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A COMPARISON OF OCEANIC PARAMETERS
DURING THE OCEANIC PERIOD OFF THE
CENTRAL COAST OF CALIFORNIA
by
Elroy Anthony Soluri
Thesi
s Advisor: S. P. Tucker
MAR 1971
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TE SCHOOL
93940
A Comparison of Oceanic Parameters During the
Oceanic Period Off the Central Coast of California
by
Elroy Anthony Soluri
Lieutenant Commander, United States Navy
E.S., New York State Maritime College, 1962
Submitted in partial fulfillment of the
requirements for the degree of
MASTER OF SCIENCE IN OCEANOGRAPHY
from the
NAVAL POSTGRADUATE SCHOOL
March 1971
scroot
ABSTRACT
A detailed examination of the coastal region between
Monterey Bay and San Francisco Bay was conducted from 1 to 6
November 1970. Measurements of temperature, salinity, sound
velocity, beam transmittance , Coulter particle size distri-
butions, chlorophyll a, phosphate, and oxygen were obtained
at 86 stations from the surface to 100 meters. The data
collected are presented in the form of contours in horizontal
and vertical sections and depth profiles which indicate:
1. a distinctive off-shore region, which exhibited high
values of oxygen, chlorophyll a, and particle count and low
values of temperature and beam transmittance was present;
2. the areas with the highest standing crop are inshore,
within five miles of the coast;
3. a peak in the size distribution of particles did not
always occur in the surface layer within the observable
range of diameters of from 1.59u to 32. Ou;
4. a plot of oxygen versus phosphate yielded a slope of
yg-at/1 P04
-2.4
ml/1 02
5. there appears to be no simple correlation in the
scatter of points plotted for chlorophyll a as a function of
oxygen ; and
6. a plot of chlorophyll a versus beam transmittance
indicates similarly that no simple relationship between these
parameters exists.
TABLE OF CONTENTS
I. INTRODUCTION 9
A. PURPOSE 9
B. MARINE CLIMATOLOGY 9
C. PREVIOUS INVESTIGATIONS 11
II. OBSERVATIONAL PROCEDURES 14
A. STATION LOCATIONS 14
B. DATA COLLECTION 14
C. INSTRUMENTATION 18
1. Sound Velocity-Temperature-
Depth Probe 18
2. Beam Transmissometer 18
3. Particle Counter 18
4. Fluorometer 19
D. DATA REDUCTION 19
III. DATA ANALYSIS 22
A. INTRODUCTION . 22
B. DESCRIPTIVE TECHNIQUES . 22
1. Horizontal Contours 22
a. Temperature 23
b. Phosphate 25
c. Oxygen 26
d. Salinity 26
e. Chlorophyll a 27
f. Beam Transmittance 29
g. Particulates 31
2. Vertical Contours 32
a. Sections A and B 32
b. Section E 34
c. Section G 35
d. Section I 35
e. Section K 36
f. Section M 37
3. Depth Profiles 37
4. Graphical Comparisons 38
IV. CONCLUSIONS 54
V. SUGGESTIONS FOR FUTURE RESEARCH 56
TABLE I - Fortran IV Computer Program 214
Table II - Station Data 223
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BIBLIOGRAPHY 360
INITIAL DISTRIBUTION LIST 362
FORM DD 1473 368
LIST OF TABLES
Table
I Fortran IV Computer Program for Data
Analysis 214
II Station Data: Location, Time, Date, Depth,
Weather, Sound Velocity, Temperature,
Transmittance , Oxygen, Phosphate and
Chlorophyll 223
III Particle Size Distribution 309
LIST OF FIGURES
Figure
1. Cruise Chart and Approximate Station
Locations 15
2. Arrangement of SV/T/D Probe and Beam
Transmissometer 16
3. U.S. Coast Guard Airborne Radiation
Thermometer Temperature Chart for
October 1970 24
4. Location of CALCOFI and NPS Stations in
Monterey Bay 28
5. Particle Size Distribution Observed at
Station E-2 at 100 m 40
6. Particle Size Distribution Observed at
Station A-6 in Monterey Bay, from
0-80 m 41
7. Particle Size Distribution Observed at
Station B-l in Monterey Bay, from
0-14 m 43
8. Particle Size Distribution Observed at
Station B-6 in Monterey Bay from
0-75 m 44
9. Particle Size Distribution Observed at
Station K-9 Off Point Montara from
0-80 m ■ 45
10. Chlorophyll a as a Function of Oxygen 46
11. Beam Transmittance as a Function of
Chlorophyll a 48
12. Oxygen as a Function of Phosphate with
Pytkowicz' Empirical Relation
Superimposed 49
13. Best Fit Curve Superimposed for Oxygen
as a Function of Phosphate 50
14. Beam Transmittance as a Function of
Total Particle Count 52
15. Beam Attenuation Coefficient (Alpha)
as a Function of Cumulative Particle
Volume 53
16-45 Horizontal Contours for 0, 10, 20, 40 and
75 m Depths for Chlorophyll a Oxygen,
Beam Transmittance , Phosphate,
Temperature, and Total Particle
Count 58
46-87 Verticle Sections Temperature Oxygen,
Phosphate, Chlorophyll a, Total Particle
Count and Beam Transmittance for
Station Groupings A, B, E, G, I, K,
and M 88
88-171 Station Profiles of Oxygen, Phosphate Density
Chlorophyll a, Cumulative Particle
Volume and LN Transmittance 130
ACKNOWLEDGEMENTS
I wish to extend my sincere gratitude to the many
people who helped put this thesis together. First, I wish
to thank Stevens P. Tucker, under whose direct supervision
I worked, who willingly gave of his time and technical
knowledge in enabling me to overcome the difficulties
confronted while writing this report. Secondly, I wish to
thank Professor Eugene Traganza for his help and understand-
ing. Sincere thanks go out to all the members of OP9 4 and
several of OP02. Without their assistance in collecting
and analyzing samples during the at-sea period it would
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schedule. I wish also to thank the officers and crew of
the USNS DE STEIGUER (T-AGOR-12) and Mr. Jerry Norton of
the Oceanography Department who offered invaluable assis-
tance both during and after the cruise. Lastly, to my
wife, Alice, profound gratitude for her endless encourage-
ment and assistance and for the cheerful manner in which
she accepted my neglect during the preparation of this
report.
I. INTRODUCTION
A. PURPOSE
The purpose of this investigation was to examine the
coastal waters off Central California during the oceanic
period and to compare the oceanographic parameters measured
with those observed previously by Baker during this period
and by Labyak and Shepard during the spring upwelling
period. In particular it was desired to obtain further
knowledge of the spatial and temporal variability of beam
transmittance and its relation to other oceanographic
parameters in the region.
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were occupied during the period 1-5 November 1970 and
2749 water samples were collected and analyzed.
B. MARINE CLIMATOLOGY
Skogsberg [5] was the first to describe the annual
thermal rhythm of the Monterey Bay area in terms of three
major seasonal features, namely, the "cold water" phase,
the "warm water" phase, and the "low thermal gradient"
phase. Bolin [4] later described these features and
labeled them as the "upwelling," the "oceanic," and the
"Davidson Current" periods.
The upwelling period is the most persistent of the
three periods. It is usually initiated in the latter part
of January by a change in the wind direction from the south
to north-northwest. This change gives rise to a transport
of water away from the coast and its subsequent replacement
by colder, subsurface layers from depths which depend on a
number of factors but do not exceed about 200 m at most.
The major properties of this period are a normal sea
surface temperature of 10 to 11°C/ the lowest of the annual
cycle, and the absence of clearly defined isotherms.
In September there is a transition period during which
the calm of the oceanic period becomes pronounced. As the
strong north-northwest wind dies out, the upwelling becomes
intermittent and breaks into irregular eddies. The cold,
dense, surface water causes the formation of a very sharp
thermocline at depths of only a few meters. During this
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observed, the highest of the year. Bolin and Abbot [3] have
described the effect of this intermittent upwelling on the
plankton volumes observed in the Central California coastal
region.
In November the upwelling ceases with the onset of
southerly winds. In the surface layers a countercurrent
called the Davidson Current is developed. This current
normally lasts until late January and serves to reinforce
the wind driven circulation. Sea surface temperatures
decrease slightly during this period, which is characterized
by a weak thermocline depressed to 50 to 100 m.
10
C. PREVIOUS INVESTIGATIONS
Skogsberg (1936) was the first to carry out an intensive
investigation of the hydrography of Monterey Bay. His five-
year study revealed that the thermal properties of this
region are remarkably consistent from year to year.
Bolin (1964) also conducted a five-year study but
localized his area of interest to that of the Monterey
Submarine Canyon. His results confirm the three-phase
annual cycle of the marine climate described by Skogsberg
and indicate the variations of parameters such as salinity,
oxygen, and plant nutrients during the annual cycle. He
found that each of the variables he studied also undergoes
an annual cyclic alteration, but that the changes during
the oceanic period were less pronounced than those of the
upwelling and Davidson periods.
From the mid-1960 's observations of the effects of
various oceanic variables on the waters of the Central
California coast have been made by the Naval Postgraduate
School.
The first of a series of studies was conducted in 1964
by Bassett and Fuminger [8] . They examined the vertical
variation of light attenuation within Monterey Bay and its
relation to phosphate content, salinity, temperature and
light scattering. They did not, however, find clear-cut
relationships between relative volume scattering coefficients,
density, and phosphate for the stations they occupied.
11
Yeske and Waer [7] in 1968 examined in some detail the
temporal variation of oceanic parameters on light attenua-
tion at two stations within Monterey Bay during a complete
lunar cycle. Their measurements indicated among other
things that approximately 96% of the suspended particles
contributing to this attenuation were less than 8.5u in
diameter.
Labyak [6] in 1969 was the first to investigate in
detail the beam transmittance of the coastal waters between
Monterey Bay and San Francisco Bay during the upwelling
period. In general he found fairly good correlation between
beam transmittance, temperature, and particle count. He
found poor or no correlation between these, however, in the
near-shore and upwelling areas. He observed that approxi-
mately 90% of the particles were less than 12y.
Baker [2] in November 1969 made further observations
of the optical properties of these coastal waters during
the oceanic period. He also found a fairly good correlation
between beam transmittance and particulate count but found
no strong relationship between beam transmittance and
temperature. He concluded that approximately 74% of all
the particulate matter observed was less than 6.2y in
diameter.
Shepard [1] in May 19 70 was the first to conduct a com-
prehensive survey of the variation of oceanic parameters
during the upwelling period. He dealt not only with the
effects of temperature and particle count on light
12
attenuation, but also considered the effects of oxygen,
phosphate, and chlorophyll a on beam transmittance. His
work contains a review of these parameters and their
observed variations along the California coast.
He concluded that upwelling during May 19 70 was taking
place on a larger scale than that observed the previous
year by Labyak. He found a fairly good relationship
between beam transmittance and particulate matter.
13
II. OBSERVATIONAL PROCEDURES
A. STATION LOCATIONS
During the period 1-6 November 1970, station data were
collected aboard the USNS DE STEIGUER (T-AGOR-12). The
study area, the coastal area between Monterey Bay and San
Francisco Bay, is depicted in Figure 1 along with the
approximate locations of the eighty-six stations occupied.
The exact position, time, and weather conditions for each
station are presented in Table II. These stations were
selected to cover approximately the same areas and stations
occupied by Shepard [1], Baker [2] and Labyak [6]. Stations
vers occupied in reverse alphabetical and n\HT©rica] ordeT*
starting with station M-6 at the entrance to San Francisco
Bay and ending with station A-l in Monterey Bay. Station
positions were determined every 15 minutes by loran A,
radar, or visual bearings.
B. DATA COLLECTION
At least two hydrographic casts were made at each sta-
tion. However, at 5 7 of the stations occupied, near bottom
samples were also obtained by means of a third cast. On
the first cast the sound velocity/temperature/depth probe
and the beam transmissometer were arranged so as to allow
the beam transmissometer to pass through undisturbed water.
Figure 2 is a sketch of this arrangement. During the lower-
ing readings of depth, temperature, sound velocity, and
14
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HYDRO- WIRE-
ELECTRICAL CABLE
SV/T/D PROBE
BEAM TRANSMISSOMETER
Figure 2
16
beam transmittance were recorded for selected depths down
to 100 m. These observed values/ along with station weather
data, are presented in Table II, which begins on page 223.
Continuous readings were recorded as the cast was returned
to the surface. Expendable or mechanical bathythermographs
were taken at many stations to provide an additional measure
of the temperature.
Graphical plots of temperature, sound velocity, and beam
transmittance as functions of depth were made, and, on the
basis of these, optimum positions for the Nansen bottles
were determined. The water samples collected were divided
into five groups: (1) 250 ml for oxygen analysis, (2) 100ml
for phosphate analysis, (3) 320 ml for salinity determina-
tion, (4) 120 ml for particulate cinalvsi^g , an^ (5) t-h<?
remainder for chlorophyll a determination. All samples
taken, with the exception of those for chlorophyll a, were
analyzed aboard the DE STEIGUER. The chlorophyll a samples
were filtered through Whatman GF/C glass filters with a
small amount of magnesium carbonate added to prevent acidity.
The filters were then folded in half, sealed in plastic
bags, and immediately frozen. These samples were kept
frozen until the analysis was carried out about four weeks
later.
The third cast was made using a bottom sampler [6] to
collect samples for phosphate, oxygen, salinity, and partic-
ulate determinations.
17
C. INSTRUMENTATION
1. Sound Velocity /Temperature/Depth Probe
A Ramsey Engineering Company MK-1 Sound Velocity/
Temperature/Depth (SV/T/D) probe was utilized at nearly all
stations curing the cruise. This instrument is similar to
the one described by Labyak [6].
2. Beam Transmissometer
A Marine Advisors model C-2 beam transmissometer
("Alpha-meter" or "C-meter") was used throughout the entire
cruise. This instrument is similar to that described by
Yeske and Waer [7] and is the one used by Labyak [6], Baker
[2] and Shepard [1] . A tungsten lamp was used as the light
source, and the optical pass-band was determined by a com-
kinaf i rS -P T-T ■ *- J — « /r"1 — > ~ ^ o ~ v ^» 4- 4- r> /-• _ 1 O -f A 1 4- /^ v o
dominant wavelength of approximately 5 3 8.8 nm.
The instrument was zeroed prior to each cast and
never lowered below 5 meters from the bottom.
3. Particle Counter
A Model T Coulter counter was used to carry out the.
analysis for particulate matter in the seawater sample. It
The total beam attenuation coefficient c = (a+b) is given by
c = - (l/l)dl/dx, where I is the radiant flux incident on a
thin layer of thickness dx normal to the beam, and dl is the
radiant flux lost to the beam due to the effects of scatter-
ing and absorption. If this equation is integrated, I (x) =
l(0)e~cx, where I (x) is the radiant flux of the beam at a
distance x in the direction of propagation from a point where
the flux has the value 1(0). Normally x is taken to be 1 m,
so that 1(1) =I(0)e~c. The transmittance_per meter, T, is
then defined as the ratio T = I(1)/I(0) = e c. Sometimes the
term "beam attenuation," A, is used. It is related to the
transmittance: T+A=l. It is to be emphasized that c is
wavelength-dependent, i.e. c = c(A).
18
is the same instrument used and described by Shepard [1] .
Electrical noise prevented the use of Channel 14 at the
small-size end of the range. With the lOOu diameter orifice
used the range of sizes detected was from 1.5u to 32. Oy.
4 . Fluorometer
A Turner Model 111 Fluorometer was utilized in the
determination of chlorophyll a. This instrument is the one
described and used by Shepard [1] .
D. DATA REDUCTION
A Fortran IV program for the Naval Postgraduate School's
IBM 360 computer, the core of which was drafted by LCDR
Miller and LT Garcia in 19 70 was modified somewhat to
calculate values of salinity, oxygen and phosphate. A
copy of the program is presented as Table I. It is capable
of processing 9 stations per run with a maximum of 40 cards
per station. Statement cards are located throughout the
program to provide an indication of what each section does.
The program contains seven subroutines, four of which are
used to calculate salinity, oxygen, phosphate and density;
a fifth one prints the station heading, and the last two
interpolate the Nansen cast data and SV/T/D - transmission
data to standard depths. SV/T/D, transmission, particle,
and chlorophyll a data are read directly into the program
and no calculations other than the interpolations are
carried out on this information. The computer output is
presented in Tables I, II, III.
19
A draw subroutine was utilized to plot depth profiles
for individual stations for the following parameters:
density, oxygen, phosphate, chlorophyll a, cumulative par-
ticle volume, and alpha = [-In (transmittance) ] . Since the
values of cumulative particle volum-3 covered a large range,
it was difficult to choose a common scaling function and
at the same time avoid the loss of detail by the crowding
of points along one axis. Therefore, a common scale was
used only for individual station lines, e.g. 1-1 to 1-9
rather than for all 86 stations.
The scales used in each case are depicted in the heading
format of the individual station depth profiles.
The amount of chlorophyll a present was determined from
a procedure ouLIineu by Holm— Hansen, et al , [14] using
f luorometeric techniques. One can also determine the amount
of phaeo-pigments present from this procedure; I did not,
2
however, make the actual calculation. In the analysis of
chlorophyll a carried out by Shepard [1] it was assumed that
no phaeo-pigments were present; I did not make this assump-
tion.
A program for a WANG Model 360 K desk calculator was used
to solve the following equation for each sample:
3 T
mg chlorophyll a/m = F — y (R ~ RA)
mg phaeophytin/m = FD -^ZJ ^tRa ~ RB^
20
where F = door factor
RB = fluormetric reading before acidification
R, = fluormetric reading after acidification
t = the ratio of R„/R,
B' A
An attempt was also made to determine chlorophyll a con-
centration by means of a continuous flow analysis at several
stations while at sea. These attempts were unsuccessful in
producing any results that compared with those obtained by
individual analysis. The presence of air bubbles in the
system was a constant problem, and this was believed to be
the cause of our inaccuracies.
In summary., the use of the computer is an ideal, quick
and efficient, method of processing large amounts of station
data. Although the equation for chlorophyll a is not
presently in the program, it could easily be added as an
additional subroutine.
21
III. DATA ANALYSIS
A. INTRODUCTION
To depict the distributions of temperature, phosphate,
oxygen, chlorophyll a, beam transmittance/ and suspended
particle matter during the oceanic period in some detail,
horizontal and vertical contours were drawn. In addition,
depth profiles of density, phosphate, chlorophyll a,
cumulative particle volume, oxygen, and beam attenuation
coefficient (alpha) were plotted to facilitate comparisons
between these parameters.
The computer outputs of station data, including weather,
pcciuicn, oimc , «ui.c, an^ c^gcivcu values arc -ic^c- in
Table II.
Table III contains a listing by oceanographic station
of the particulate count data observed for each Coulter
counter channel for each depth sampled.
Graphical comparisons were also made between various
pairs of parameters to determine what quantitative relation-
ships, if any, exist between them.
B. DESCRIPTIVE TECHNIQUES
1. Horizontal Contours
Horizontal contours at depths of 0, 10, 20, 40, and
75 m were drawn. The depths were chosen for ease of com-
parison with Shepard's analysis. These contours will be
discussed in order from the surface to 75 m, according to
22
the following list: temperature, phosphate, oxygen,
chlorophyll a, beam transmittance , and total particles.
The extreme horizontal isopleths for all parameters did
not always occur at the surface, but they were generally
within the upper 20 meters. Some predominant features were
observed at the northern end of Monterey Bay near Santa
Cruz (Station B-l) , in an area approximately 15 nmi off
Point Montara (Station K-9) , in an area approximately 10 nmi
off Point Ano Nuevo (Station G-7) , and to the west of the
entrance to San Francisco Bay.
These features generally persisted down to a depth
of nearly 40 meters.
a. Temperature
The surface temperature con •hours fFiaurp l.f>)
depict a uniform temperature structure with very weak
thermal gradients. The most dominant aspect of this figure
is the presence of a cool patch of water off Point Montara.
This pool is also shown on the U.S. Coast Guard Airborne
Radiation Thermometer chart for October 19 70 (Figure 3) .
The average sea surface temperature during this period was
13.45°C, which is in agreement with Bolin's [4] description
of the oceanic period. However, the surface was approxi-
mately 1°C colder than observed by Baker [2] for a similar
period in 1969. The CALCOFI temperature contours for the
first half of November 1970 show that the onset of the
Davidson Current period had not yet taken place. That is,
the surface water was being influenced largely by the cold
23
Figure 3
24
California Current, resulting in a lowered sea surface
temperature. There was a decrease in temperature with
increasing depth and a general increase seaward. The
strongest horizontal gradient appeared at a depth of 75 m
off the Monterey Peninsula. The nearly isothermal water
observed by Shepard in the northern, inshore portion of
Monterey Bay was also observed during this investigation.
It is interesting to note that, whereas Baker [2] observed
only 6 of 25 Bay stations with temperatures less than 14.0°C,
the warmest temperature during my investigation was 13.9°C
at Station A-l off Monterey.
b. Phosphate
The phosphate contours (Figures 21 to 25) show
exceptions to this were noted: the first was a patch of phos-
phate rich water located some 15 nmi off Point Ano Nuevo; and
the second, not indicated by the surface contours, was
located approximately 15 nmi off Point Montara at Station
K-9 within the pool of colder water previously mentioned.
Riley and Skirrow [16] observed that autumn blooms are very
unpredictable and can arise when a period of autumn winds
and cooling surface waters allow phosphates to mix into the
euphotic zone. Such mixing may be followed by sufficient
stability for rapid plant growth to recommence. The phos-
phates decrease with depth. Generally, values of phosphate
were fairly uniform throughout the region of interest and
much lower than those of the upwelling period. The highest
25
values of phosphate, 2 yg-at/1, first appeared at 75 m.
Shepard observed a high of 2.5 yg-at/1 at 40 m.
c. Oxygen
The oxygen contours (Figures 26-30) show four
distinct regions, namely the area in the vicinity of K-9
previously described, the region just offshore of Point
Ano Nuevo (Station 1-8), the Monterey Canyon (Station B-9)
and southwest of the Monterey Peninsula (Station C-3).
These regions are "anomalous" in that they are either highly
saturated (Station K-9) or under-saturated (Stations 1-8,
B-9, C-3) for a given salinity and temperature. All but
Station K-9 have a relatively high sea surface temperature.
The large concentrations of chlorophyll a and phosphate
observed at K-9 may be due to the entrapment of water ohoto-
synthetically enriched in oxygen. The best agreement between
temperature and oxygen, i.e. low temperature and low oxygen
content, was found in the regions between Pigeon Point and
Point Ano Nuevo and along the axis of the Monterey Canyon
approximately seven nautical miles from shore. The expected
decrease of oxygen with depth was generally not observed
above about 20 m. At most stations conditions remained
fairly constant above about 75 m. The only "anomalous"
increase in dissolved oxygen occurred at Station K-9 at
depths of from about 10 to 30 m.
d. Salinity
Observed salinity values were compared with the
ten year mean values of the California Cooperative Oceanic
26
Fisheries Investigations (CALCOFI) and generally good agree-
ment was noted. Using our observed salinities and corres-
ponding temperatures, the saturation percentage of oxygen
for the four distinct regions mentioned were calculated.
100% saturation of oxygen was assumed to occur at 6.1 ml/1,
which is approximately correct for the study area. The
maximum observed value of 7.5 ml/1 at Station K-9 gave a
saturation value of 117%. At station C-3 southwest of the
Monterey Peninsula the value was 69% of saturation, while
at B-9 in the Monterey Canyon it was 82%. In the area off
Point Ano Nuevo the cruise minimum of 3.72 ml/1 was
observed, which corresponds to 64% saturation.
The dissolved oxygen and phosphate values
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a concurrent, independent, CALCOFI cruise of the Hopkins
Marine Station. These values were in excellent agreement.
In Figure 4 Station 3 denotes the location of the Hopkins
CALCOFI cruise station which corresponds most nearly to the
time frame of this report. The cross marks the position of
NPS Station B-8. The corresponding values of oxygen and
phosphate are shown in the figure within parentheses.
e. Chlorophyll a
Concentration of chlorophyll a at the surface
(Figure 31) was fairly constant from Point Montara south to
Monterey Bay and somewhat variable off the entrance to San
Francisco Bay. The highest values were observed at Stations
M-3 and M-5 outside the entrance to San Francisco Bay, and
27
I22°00' I2I°55' I2I°50'
I22°00'
I2I°55'
I2I°50'
Figure 4. Location of CALCOFI and NPS Stations
in Monterey Bay.
28
at station B-l in northern Monterey Bay, just off Santa
Cruz. The maximum values of chlorophyll a were generally
confined to the upper 10 m, but there were scattered pockets
of high concentrations below this level. A patch of
unusually high values was observed near Station K-9 at a
depth of 40 m.
The high surface value observed at Station B-l
still persisted near the bottom. In both cases low light
transmission and fairly high values of total particle count
are observed. This process may best be explained by a
cessation or slackening of upwelling in these areas with
the onset of the Davidson Current Period.
Offshore numerical values agree well with
Shsr?2rd ' s ob£6rv?.tions but the inshore values ?. re rTenera!My
an order of magnitude lower.
f. Beam Transmittance
Beam Transmittance (Trans) contours from the
surface to 75 m (Figures 36-40) did not display the effects
of coastal turbidity (Trans < 50 %/m) except near the
entrance to San Francisco Bay. The northern and southern
ends of Monterey Bay were clear (Trans = 80 %/m) areas with
a patch of relatively clear water (Trans = 60 %/m) in the
vicinity of Monterey Canyon. This is contrasted with the
extremely low values of beam transmittance observed for
these regions by both Labyak and Shepard during the upwelling
period. During the November 1970 cruise the surface trans-
mittance values ranged from 50-80 %/m; these are slightly
29
higher than those observed by Baker for a similar period in
1969. The surface contours show two areas where the trans-
mission is slightly less than 50 %/m. One of these occurs
at station M-5 off the entrance to San Francisco Bay.
Station M-5 occupied at 1545 on 1 November 1970. A maximum
flood tide of 2.2 kts. occurred at 1100 on 1 November 1970;
thus, at the time this station was sampled, slack water
conditions existed. The difference existing between the low
values on the May 1970 cruise and the relatively higher
values on the November 19 70 cruise may be attributed to the
3
transport of coastal water into the Bay by the flood tide.
The second region where transmission was lower
than 50 %/m was located at Station K-9. Considering the
ri T rrll TJ^1 HOC <■% -P /"\ t^t t •t^-* v. rNVvrvr<*-«V* -^4-/> -n ft /-l r»K 1 ArnnhTrl 1 r> t.t V» "i oVx
occur in that region, one may conclude that the low values
of light transmission are the result of the relatively large
standing crop. Looking at the successive depths one finds
that this condition is confined to the upper 20 m, beneath
which the water becomes clearer. A study of the 20 and 40 m
contours reveals the effects of shallowness along the
inshore portion of the study area. Generally there was a
decrease of light transmission with depth along the entire
region from Point Montara to Santa Cruz, and even into the
northern part of Monterey Bay. The K-station line is unique
3
Further discussion of this tidal effect is to be found in
Shepard (1970) , p. 30.
30
in that high values of transmission (Trans = 90 %/m) are
found in the upper 20 m nearshore and below this level off-
shore.
g. Particulates
It was found that the November 19 70 maximum
particle counts were less than those observed by Shepard
but generally greater than those for the November 1969
cruise.
At the surface an extremely strong horizontal
gradient is evident near the entrance to San Francisco Bay
(Figure 41) .
Two additional areas of high particulate count
occurred off Santa Cruz Harbor at Station B-l and off Point
Ano Nuevo (Station G-7) . Both of these regions had cor-
responding relatively high values for dissolved oxygen and
chlorophyll a. Outside these three regions lower counts
were observed. Below the surface l£iyer an increase of total
particle count with depth was observed between Point Montara
and Pigeon Point. There was also a decrease in counts as
the distance from shore increased. This is in agreement
with the rapid decrease of beam transmittance exhibited in
this area. Monterey Bay, except as noted above, was an area
of rather low particle count down to 75 m. The 75 m contour
depicts the first pocket of high particle count on the wall
of the Monterey Bay Canyon at Station A-4. This can be
attributed perhaps to the transport of bottom sediments down
the canyon.
31
2. Vertical Contours
Vertical sections were drawn for station lines A, B,
E, G, I, K, and M (Figures 46 to 87). These station lines
were contoured in a fashion identical to that described by
Shepard. The contours were drawn to the data at each sta-
tion in a given line from the surface to 100 m, except where
interrupted by the bottom. Contour intervals were modified
in regions of strong gradients to avoid crowding the
isopleths .
a. Sections A and B
The influence of the Monterey Submarine Canyon
on these parameters is indicated by the upward bulge below
20 m in the contours over the Canyon region and the north
and southward spreading at the surface (Figures 46 to 49).
Bolin and Abbot [3] noted that the Canyon causes a funneling
of deep water into the Bay and a subsequent fanning out at
the surface. Two contrasting features are displayed at the
northern end of Monterey Bay. At Station A-l the water is
oxygen-rich, phosphate-poor with a small standing crop,
clear, and of a low particle count. At Station B-l, which
is located approximately 3 nmi west-southwest of A-l, the
water is oxygen-rich, phosphate-poor, and has a large stand-
ing crop (i.e. it has chlorophyll a contents between 0.7
and 1.7 mg/m ) and has a transmission of about 80 %/m and a
high particle count. A similar situation was observed by
Shepard for the entire northern end of the Bay.
32
Values of beam transmittance between 70 and
90 %/m and relatively low particle count (i.e. about
_3
10 x 10 /2ml) may be observed throughout most of the Bay,
and even over the Monterey Submarine Canyon, except as
noted above and within a few meters of the bottom of the
Canyon. The rapid change in particle content near the
bottom is characterized by a strong gradient in which con-
ditions deteriorate rapidly; e.g. particle counts increased
at Station A-3 from 5K particles per 2ml to 94K particles
per 2ml in a distance of but 10 m. The area at the southern
end of the Bay, where transmission is about 80 %/m, may be
seen along both the A and B station lines, and the profiles
show that this water is being transported northward and is
gradually moving toward the northern edge of the Monterey
Canyon, where the influence of the bottom on transmissivity
begins. This is very probably due to the influence of the
Davidson Current. The isotherms below approximately 12.5°C
extend across the entire Bay. This is in agreement with
both Labyak's and Shepard's observations. The water of
3
relatively large standing crop (chlorophyll a - 1.0 mg/m )
observed near the surface at Station B-l, spreads out and
sinks to a depth of 40 m at Station B-4. A possible cause
for this is the circular eddy pattern described for northern
Monterey Bay during the oceanic period in the Bay-Delta
Study prepared for the California State Water Quality Control
Board [15, Fig. VI-10] . The eddy would tend to isolate this
feature within the area.
33
b. Section E
The surface waters along the E station line
depict high values of beam transmittance and low particle
count. These conditions remain unchanged with depth sea-
ward of Station E-3. Shoreward of this station, however,
at depths below about 15 m, low values of transmittance
and high particle counts are found. Sediment disturbance
by near bottom currents apparently sharply increases the
amount of suspended particulate matter. Bolin [4] observed
that, as the Davidson Current starts its northward flow in
November, the Coriolis force causes the surface waters to
move shoreward, where they sink. The increase in turbidity
may result from this downwelling. Generally, the profiles
are fairly uniform along the E station line. A contrasting
feature is the humping of two oxygen isopleths at Station
E-3 (Figure 60) . This possibly may be the result of an
error in analysis, since no verification for its existence
can be found in the other profiles. A relatively large
standing crop (e.g. chlorophyll a) is apparent in the
inshore region from the surface to 30 m. Shepard found
this to be the region most productive in terms of chloro-
phyll a during the May 1970 cruise, whereas the levels were
fairly constant during the November cruise. There is, how-
ever, good agreement with the observations of beam trans-
mission obtained by Baker for this region during November
1969.
34
c. Section G
Station G-7 provides a striking contrast between
total particle count and beam transmittance. Extremely high
counts are observed with corresponding high values of beam
transmittance. Because the other parameters do not indicate:
upwelling or a plankton bloom, the high particle counts
could possibly be a result of ship's electrical interference
not noted during the measurements at sea. The apparent
sinking of surface water at Stations G-3, G-4, and G-5
(Figures 6 5 to 67) is a phenomenon also noted by Shepard.
Again, the inshore region appears to have a somewhat higher
standing crop in the upper 20 m. This is evidenced by a
decrease in transmissivity and increased Coulter counts
along the sloping bottom. Inshore values of transmission
agree well with those of Baker, but the offshore water was
generally "clearer" during the November 1970 cruise. There
was very little agreement in magnitude with the observations
of Shepard.
d. Section I
The profile of oxygen along the I~station line
shows an increase of dissolved oxygen content from the
coast seaward. This is similar to the profile observed by
Baker, which he suggests indicates the presence of the east-
ward edge of the southward flowing California Current. A
tongue of water having high transmittance and low particle
content may be observed (Figures 7 4 and 75) extending shore-
ward from Station 1-1 to 1-6, the axis of which is located
35
at about 55 m. The cold temperature of this "clear" water
thus gives some verification to the suggestion of Baker
that this region is influenced by the California Current.
The upward bulge below 20 m in the isopleths of oxygen,
chlorophyll a, phosphate, and particle count at Station 1-8
may indicate that some weak, localized upwelling is taking
place. The water in the inshore region has low oxygen
content, low particulate counts, a high phosphate level and
is relatively cold at the surface.
e. Section K
As was also the case during the November 1969
and May 1970 cruises, the highest values of dissolved oxygen
for the entire cruise were found off Point Montara along the
K— station line 'Ficurss 76 to 81^ . ^be h-irrVi vainpR of
oxygen, chlorophyll a, and particle count, along with low
values of transmission and phosphate, delimit the region
where the standing crop was largest for the entire cruise,
i.e. between Stations K-8 and K-9. The K-station line is
also characterized by the strongest gradients for oxygen,
chlorophyll a, total particulate count, and transmissivity .
Below the upper 10 m the beam transmittance increases rapidly
to a value of 80 %/m at 30 m (Figure 80). At Station K-9 a
pocket of water of relatively high chlorophyll a content
and high Coulter count is to be noted at a depth of 45 m.
Station K-9 was occupied at 0900 hours, and the effect could
be due to diurnal phytoplankton sinking. There is some
indication of upwelling provided by the sharp rise of the
36
various isopleths in the vicinity of Stations K-7 and
K-8.
f. Section M
The "time axis" method used by Shepard to
describe the profiles along the M-station lines will be
utilized here. Station M-6 was occupied one hour before
slack water. The tide was at a maximum ebb when Station
M-3 was occupied at 1745 on 1 November 1970. The tidal
currents in this region are directed toward the Bay for
approximately 3 hours at decreasing velocities until a
slack water condition is reached. A similar period is to
observed for the onset of the ebb tide until maximum ebb
is reached. Thus, stations M-5 and M-4 were occupied during
r~v*-i>~-ir>>£ir- of -'nr"rc:'SsiTirT ^irrs"^ ^'^l^cities
Figures 82 to 87 depict the converse of the
observations of Shepard, which were for a slack to maximum
flood time period. High values of temperature, oxygen,
chlorophyll a, and particulate counts coupled with low
transmission were observed at Stations M-3 to M-7. The
stations occupied after the maximum ebb show a complete
reversal in the levels of the above parameters, except at
the bottom, where the strong gradients of high particles
and low transmissivity were maintained.
3. Depth Profiles
Depth profiles of density, chlorophyll a, phosphate,
oxygen, cumulative particle volume, and beam attenuation
coefficient are presented in Figures 88 to 171. With few
37
exceptions an increase in cumulative particle volume is
associated with a corresponding decrease in transmittance
and vice versa. Most of the profiles depict an increase
of dissolved oxygen in the upper 20 m followed by a
decrease. Phosphate, to the contrary, decreases slightly
in the upper 20 m and then increases rapidly below this depth
4 . Graphical Comparisons
To establish numerical relationships between the
data observed on the November 1970 cruise and those of
Shepard, our data are presented in the same way his are.
Simple scatter diagrams were drawn to depict what relation-
ships, if any, exist between various pairs of parameters.
It should be noted here that, because of the disparity in
vanrfoo <~>f da^a Kofwoon -HV\ci Maw ^^d NOT'
Dtnhcr 1 O "7 fl <-,r-n-i eoc
3
(e.g. chlorophyll a ranged from 0.2 to 10 mg/m , while in
3
November 1970 it ranged from 0.1 to 1.2 mg/m ), November-
May comparisons cannot be made over the entire ranges
observed.
While working with the Coulter counter, Bader [11]
observed that many natural collections of small particles,
such as mineral and organic particles suspended in seawater
and fine sediments, have hyberbolic cumulative population
distributions of the form N = kv , where k and m are con-
stants and v is particle volume. He observed further that
if log, N is plotted as a function of log1QD, where D is
spherical particle diameter, the result is linear with
slopes of -3m, which range from 0.88 to 1.45 counts/y for
38
seawater samples from Abaco Bight, Bahamas. For a compari-
son with our November 1970 data a log differential population
plot was made for the clearest water observed on the cruise,
i.e. 92.4 %/m for Station E-2 at a depth of 100 m (Figure 5).
This plot indicates a slope of -2.52 for our data. For
purposes of comparison Bader's number distribution curve for
"wave-agitated seawater masses" [11, Fig. 4] is plotted as
a dashed line in Figure 5.
To examine the natural truncation of the large
diameter particles plots similar to those of Figure 6 were
drawn. Shepard observed a rather abrupt change and dip at
approximately 15u for Station A- 6 within Monterey Bay. This
station was again plotted to see if such a change was
present foi bhe November data. No abrupt changes for this
station or for Stations B-l, B-6 and K-9 were noted (Figures
6 to 9). A decrease in particle count with an increase in
diameter was the trend in all cases. The largest count
plotted occurs at Station K-9 at a depth of 30 m for par-
ticles with a diameter of 1.59y. Points where crossovers
occurred were compared with the vertical profiles in an
attempt to explain how this feature fits into the general
station trend. For Station A- 6 (Figure 6) this crossover
occurs at 1.5K counts/2 ml and a diameter of 7.5y for the
20, 35, 80 m curves. The depth profile for this station
shows the area to have high values of transmissivity (70 %/m
to 80 %/m) , low particle count, relatively low values of
chlorophyll a, and increasing values of phosphate. The plot
39
rrrq"
1 I TTTiT
6
i I 'ill
jj L
J.
Li
o
CN
40
""■""
u
—
0)
-P
<D
F
—
f0
•H
Q
0)
H
U
•H
4->
M
id
—
a.
10
— ^
3
B
en
CN
a)
>
4->
— —
4J
c
' " «
C3
3
3
o
O
o
u
-J
5
rH
U
•H
•r— 1
■U
_U
5-1
id
—
•— i
c^
TO
H
•H
•U
ti
d
•r-!
<u
+J
u
c
'U
a)
•I-l
(U
=5
M-l
o
•rH
u
in
i i 111 m
80o
E
u
V
a
L.
o
a.
ill
0.2
1.0
Particle Diameler in jU
41
for Station B-l (Figure 7) shows two crossovers. The first
occurs at 4K counts/2 ml and 5y; the second, at 200 counts/
2 ml and 13y. The vertical contours show this to be an area
of relatively high values of chlorophyll a and phosphate,
low transmittance , and high Coulter count. Station B-l was
occupied at 2200 hours; thus, the first point is possibly
due to the presence of phytoplankton at the surface
and the second the result of bottom sediment. Figure 8
reveals a slight peak in the surface curve at 2.52y. All
the curves from 0 to 75 m cross at approximately 200 counts/
2ml and a diameter of 6.4y. The profiles indicate that
generally the values of chlorophyll a, phosphate, and beam
transmittance increase with depth. The particle size dis-
tribution for Station K— 9 (Figure 9) depicts irreaular
curves for 0, 10, 30 m and a smoothing to 80 m. These
possibly indicate two phytoplankton populations of charac-
teristic sizes 3y and 8y. The vertical profiles reveal that
the upper 30 m of this station is an area of high particle
count and low transmissivity .
Chlorophyll a was plotted as a function of oxygen for
more than two hundred points (Figure 10). These points
consist of data from both inshore and offshore stations
and include the high and low values of oxygen previously
mentioned. No clear-cut relationship is apparent between
these two parameters. Relatively high values of chlorophyll
a can be seen for both high and low values of oxygen.
Margalef [13] suggests that high concentrations of
42
i i i i nTj jr\ (— t Mm
E
0.2
1.0
SO
•r-i
\ >
\
u
\
fd
\\
PM
X
fe
Par } ic I e Diame te
43
fe
I I I I I II
TT
^50
11
0.2
1.0
o
o
"
o
o
(0
in
I
o
g
o
O
o
u
o
iw
o
—
!•
to
" '
m
—
Q)
4J
o
1
O
•H
o
O
o
* •
-P
-P
if)
-P
0)
>
U
0)
w
O
Particle Diameler in U
44
1 HI I I I I I
L_i
.JJLi
0.2
1.0
.1 I I I I. Li
Particle Diameter in U
45
Chlorophyll (mg/in^)
o o o o
• • • •
fo 4> -ON CO
4
4
r+
1 -r
■i- 4
+
4
-$■
5--H- -fh
+ -+- -t
4*
4 4 +
44- -+- -r
■FTr^rffl 4-"r-t- -i- -rrt- t- _»- _i_ -t"
tuT4.^ -■>«- +l. 4 -I j. -ir
-1- * -+- -4-
+ +*" ' ± ..,-
+
4
4
o
4 x
^4 <
4
4
chlorophyll a associated with low oxygen may be a result of
the inactivation of chlorophyll a as phaeophytin. One
feature occurring both for the May and November 1970 data
is the absence of chlorophyll a where dissolved oxygen levels
were below 2 ml/1. This suggests that perhaps 2 ml/1 is the
lower limit of oxygen required to support the production
of chlorophyll a.
Beam transmittance as a function of chlorophyll a was
also plotted using data from the Monterey Bay area and
several of the northern stations. Figure 11 again reveals
no apparent correlation between parameters. High values of
chlorophyll a can be observed at both high and low values
of transmissivity . The indication here is that a knowledge
enough to determine the corresponding value of beam trans-
4
mittance. That is, factors besides chlorophyll are sig-
nificant in contributing to light attenuation.
Pytkowi.cz [10] recorded various slopes in oxygen vs.
phosphate plots for a period before upwelling, at the onset
of upwelling, and after it had been established. He assumed
the changes in slope to be the result of a mixing of water
masses characterized by varying amounts of phosphate and
oxygen. Figures 12 and 13 represent plots of oxygen as a
function of phosphate for the same stations plotted by
Shepard, namely, J-l, J-2, K-l (inshore) and L-l, K-10, 1-1
(offshore) . The plot reveals that fairly uniform conditions
existed at all these stations. Pytkowicz's best fit for his
47
4
4-
4
4-
4
4
4
4-
4
4
4-
4
4-
44
4'
4
4-
4
4
4-
4
4
4-
4
4
T
4
-4
4-4f- 4- -
+4-
++ ; ^+ 4 +
4j_7 . 4-
4 T 44j2 4±
J_-r -r^t: ~ 4
4-
4
-J- 4"
' -4-
4^ u-~
%
4^M
4-
4
4-
t-f
4
4-
4'
o
4
4- +
o-
4
4
to.
4-
+
4
4-
4- 4
4
4
4
4
4-
o
c
CO
•U
•U
•i-l
B
to
d
CO
H
E
CN
-r ■
4
4
4
4
4
00
o
o'
o
CSJ
o
( ui/Siu) -[lAqdoao^q^
48
o
tn
•H
fa
i
c
CM
o
CM
-£>
CO
-J-
o
(-[/qe-S ) a5t?ijdson<j
49
50
September data for Oregon coastal waters is represented by
the heavy .line. Figure 13 represents a best fit for the
November 19 70 data.
Scatter diagrams were also constructed to investigate
if a relationship between particulate count and light trans-
missivity exists.
Figure 14 is a plot of beam transmittance vs. the log,n
(total particle count per 2 ml) . All data from all the
stations in the A, B, K, L, and M station lines were plotted.
No simple, linear relationship is apparent from this figure.
However, for the narrow range of values observed and plotted,
Figure 14 is not unreasonable in that a trend toward lower
transmission with increase in counts is indicated.
Fignrp 1 5 J s a plot of the beam attenuation coefficient
2/3
(alpha) versus (cumulative particle volume) f A poor
correlation was exhibited between these two parameters. Th<5
plot shows that, in general, low values of alpha (high
transmissivity) are associated with low total particle
volumes (or projected particle area) per 2 ml sample. With
a larger range of beam transmittance and cumulative volume
it appears that a better correlation between these parameters
could be reached.
51
4-
4-
+ +
+
+
4-
4+-
4-
+
4
+
4-
.-#•
-f
+
+
+
4-
4-
4-
4+4+-? =F , +
4- +
+
+ +
4- +
4
4-
4- 4-
4-
4-
4-
4-
+
4-
4
+4-
+
4+
4-
4+
+4-
4- +
+ 4-
4-
"'T + + ±ir
44-
4-4-
4j_4-m 4-*" 4- +
4.
f +
+# ■&. 4-
4
4-
4- jt- ■ 4-
+ + *+± +
+ + ■
4-
4-
4-
4-
4-
+
-t-
4-"
4-
00
E
CM
V
a
c
3
o
U
o
Q.
O
o
0°
o
o
o
o
o
5J-
o
(N
/UJ/oM 3 iUDJJ jLUSUDJ J^ UID3£j
52
IV. CONCLUSIONS
This study represents a continuation of a series of
surveys being conducted by the Naval Postgraduate School
and others off the Central California coastal region. For
ease of comparison the analysis of data was approached in
a quasi-synoptic manner. This method provides a subjective
aid to the understanding of the processes taking place
during the oceanic period. From the data presentations it
was concluded:
1. The study area during the November 19 70 cruise indi-
cates a distinctive offshore region located approximately
15 nmi off Poirt Montara which exhibited inw surfcics
temperatures and beam transmission, and high values of
dissolved oxygen, Coulter counts, and chlorophyll a.
2. The average sea surface temperature during the
period 1-6 November 1970 was 13.45°C, approximately 1°C
lower than that for 7-14 November 1969.
3. The Monterey Bay area exhibited high values of
transmissivity (80 %/m) during the cruise period. This is
in contrast to the low values (10 %/m) observed during the
May 1969 and 1970 cruises and the slightly lower values
observed during the cruise of November 1969.
4. The areas having the highest standing crop in terms
of chlorophyll a are located within 5 nmi of the coast.
54
Offshore all the observed parameters are fairly constant
except as noted in (1) above.
5. The spread of particle diameters counted was from
1.59 to 25.4 ]i .
6. A poor correlation between cumulative particle
volume and the beam attenuation coefficient seems to exist.
7. Most of the surface waters were 100 % saturated with
respect to dissolved oxygen. The area off Pt. Montara is
supersaturated. Three regions, off Point Ano Nuevo, along
the axis of the Monterey Canyon, and southwest of the
Monterey Peninsula were undersaturated
8. The tidal currents in the vicinity of the entrance
to San Francisco Bay definitely affect the variability of
observed by Shepard.
9 . Ocean water having high values of beam transmittance
(80 %/m to 9 0 %/m) and low particle counts was observed at
the seaward ends of the station lines at depths of 40 to
65 m. It appears that these stations are influenced by the
California Current.
55
V. SUGGESTIONS FOR FUTURE RESEARCH
There is a continuing need for both raw and processed
data for the coastal region between Monterey Bay and San
Francisco Bay. The Central California coast is blessed with
many natu^il resources , including a pleasant year-round
climate and unlimited recreational facilities. These
resources encourage both tourism and rapid population growth.
The ever increasing number of people in the area makes it
urgent to improve and develop coastal waste disposal
facilities. The region includes the Sacramento River system,
the largest in the state, and the Salinas River, both of
. ,1-. -I -*V* « •«»-* d~* - -' ^ 4- ^ i-'K^. ^ ^, -, T/r ,' 4-W 4- V-> t <— tw m-»>-*/^ 4-V\/^ -Pa*I 1 /->tt *» v» rr
recommendations are made:
Coastal water investigations should be continued to
include the Davidson Current period, that is, the period
from late November through January.
Values of phaeophytin for the November 1970 cruise
should be calculated so that the pigment-to-oxygen ratios
may be explained in terms of the inactivation of chlorophyll
a as phaeophytin.
Continuous flow determinations of chlorophyll a should
be made. This will require the installation of a bubble
trap to remove the source of error we experience. These
56
determinations should be conducted to concur with airborne
spectrophotometry analyses.
The density profiles for this period should be examined
to determine the effects of advection on the water column.
These should be examined further to observe what correlations,
if any, between density, beam transmission, and particulate
maxima exist.
Finally, enough data is presently available so that an
investigation into possible relationships between multiple
parameters may be conducted. Several regression and corre-
lation programs are available for use on the IBM 360. These
are listed in the IBM Scientific Subroutine Package.
57
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4<y
- \
60
80
10C
Depth P r o f i I
e $
FIGURE 99
141
S T A T 1 O N B2
J
5.0
DEN SI IT
25.0
X
.2
CHLOROPHYLL (X)
1.0
t—
.5
PHOSPHATE (A)
2.5
0.
LU
2.0
OXYGEN (a)
10.
0
0
a
.2
- LN TRANSMITTANCE {0)
1.
0
. 80.0
PARTICLE VOLUME (CUM.)f+)
400.0
. ; .
\ 1 \
■
-.2
f <
i
c* n x
20
i
i
i
40
1
i
i
1
i
60
i
1
!
80
D e p f h P r o f i
e s
FIGURE 100
142
J
I
I—
0.
UJ
o
6.0
STATION B3
"density
25,0
.2
CHLOROPHYLL
(*)
i_Q_
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
C°)
JiLH
.2
- LN TRANSMITTANCE
(0)
.0
30.0
PA RT 1CLE VOLU M E (CU M. )(+) _150JL0_
20
40
60
80
10C
Depth Prof
e s
FIGURE 101
143
5.0
STATION B4
DENSITY
25.0
CHLOROPHYLL
m
1^0
.5
PHOSPHATE
(A)
2.5
Ui
2.0
OXYGEN
(°)
10.0
°n-
201
40
- LN TRANSMITTANCE
(0)
1.0
30.0
__*_
PARTICLE VOLUME (CUM.)f+) 150.0
_ -— hf— -
Depth Profiles
FIGURE 102
144
J
I
0.
ui
:-
5.0
STATION B5
DENSITY
25.0
.2
CHLOROPHYLL
(*)
UP
.5
PHOSPHATE
(*)
2.5
2.0
OXYGEN
(o)
10.0
.2
30.0
20
- LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM.)f+) 150.0
40*
60
80
IOC
D e p « h P r o I i I
FIGURE 103
145
FIGURE 104
146
STATION U7
5.0
.2
.5
.2
30.0"
DENSITY
CHLOROPHYLL
PHOSPHATE
25.0
(*)
1.0
(A)
2.5
OXYGEN
(°)
,10.0.
LN TRANSMITTANCE__J0] JL0.
pATTiaFToLTlME^uM^^^
80
10C
Depfh Profiles
FIGURE 105
147
STATION B8
5.0
DENSITY
.2
CHLOROPHYLL
(X)
25.0
1.0
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
(°)
10.0
o
0
10C
.2
- LN TRANSMITTANCE
(0)
30.0
Depth P r o f i I
e s
FIGURE 106
1.0
PARTICLE VOLUME (CUM.V+) 150.0
148
S T A T I O N B9
5.0
DENSITY
25.0
.2
CHLOROPHYLL
(X)
L0_
0-
UI
O
.5
2.0
.2
30.0
PHOSPHATE
(A)
OXYGEN
(°)
- LN TRANSMITTANCE
(0)
2.5
10.0
1.0
PARTICLE VOLUME (CUM.)f+) 150.0
80
Depth P r o f i I
e s
FIGURE 107
149
J
I
o.
a
40
60
80
10C
5.0
A.
.5
2.0
.2
30.0
STATION BIO
DENSITY
25.0
•i
CHLOROPHYLL
PHOSPHATE
(X)
1.0
OXYGEN
2.5
JOJL
-LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM.)f+) 150.0
[1
tl
D e
I h
f i I
e s
FIGURE 108
150
S T A T I O N B11
a.
ui
a
5.0
DENSITY
25.0
.2
CHLOROPHYLL.
(X)
^0.
.5
PHOSPHATE
(a:
2.5
2.0
OXYGEN
(°)
}££_
.2
30.0
LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM.)f+) 150.0
20
40
60
80
D e p I h P r o f i
e s
FIGURE 109
151
IT[>nRANSMiTTANi--
PARTICLE VOLUME (CUM.X+T.
80
10C
D e p I
h Profiles
FlGUR E 110
132
S T A T I O N B13
5.0
.2
DENSITY
25.0
CHLOROPHYLL
on
1.0
.5
PHOSPHATE
(A)
2,5
2.0
OXYGEN
(°)
10.0
- LN TRANSMITTANCE
(0)
.0
PARTICLE VOLUME (CUM.)^+) 150.0
60
80
10C
D e p J h Pr oli I
e s
FIGURE 111
153
S T A T I O N C1
5.0
.2
DENSITY
OjLQR.QPHY.LL
(x)
25.0
l.Q
.5
PHOSPHATE
M
Ul
2.0
9XYQEN.
(d)
,10. Q
-feM TRANSMITTANCE
(0)
_LH
PARTICIF VOLUME (CUM.) (»
Depth P r o f i I
e $
40.0
FIGURE 112
154
S T A T I O N C2
5.0
■&ENS11Y.
25. Q
.2
■CHLQRQPHYLJL
(X)
.5
PHOSPHATE
W
-XL
2*5.
2.0
QXYQEN
(o)
JQJL
.2
-LN TRANSMITTANCE
CO)
.JL
20
4Q
60
8.0
PARTI.TIF VOI I IMF (CIlM.'i (+)
40.0
80
D e p » h Prof
iles
FIGURE 113
155
S T A T I O N C3
5.0
DENSITY
25. Q
.2
CHLOROPHYLL
(X)
AJL
.5
PHOSPHATE
M
1*L
2.0
OXYGEN
(o)
10-0
.2
-!lN transmittance
CO)
-A
PARTICLE VOLUME (CUM.) (+)
40.0
20
40
60
80
Depth Pro!
lies
FIGURE 114
156
S T A T I O N D1
.2
—PENS 111
CHLOROPHYLL
(X)
25.0.,
1,0
PHOSPHATE
(*)
757
1A
2.0
OXYGEN
l&SL
.2
4.0
-LN TRANSMITTANCE
(0)
.LH
PARTICLE VOLUME (CUM.) (+) 20.0
Depth Prof
e s
FIGURE 115
157
STATION D2
5..0
DENSITY
25.0
.2
CHLOROPHYLL
(X)
1.0
.5
PHOSPHATE
(4
2.5
2.0
OXYGEN
<M
10.0
.2
-LN
TRANSMITTANCE •
(0)
1.0
4.0
. — *— — " * —
PARTICLE VOLUME (CUM.)
(+)
20.0
■ . X.
/
X.
<£
\.
\
*
/
/
'X
4
A
\ A
X
.
¥
.;--"■
S
X
N
i \
Depth P r o f i I
e s
FIGURE 116
158
S T A T I O N D3
5J0
DENSITY
2SJL
.y
CHLOROPHYLL
(X)
PHOSPHATE
w
H
.LO.
2.5
2.0
OXYGEN
10. Q
-LN TRANSMUTANCE
(0)
2JL
4.0
PARTICLE VOLUME (CUM.) (+) 20.0
X
<
rfv*
•£
D e p ! h P r o f i
e s
F I G U R E 117
159
5.0
STATION E1
DENSITY
25.0
CHLOROPHYL!
(X)
1.0
PHOSPHATE
(A)
2.5
OXYGEN
(<=>)
1Q^_
LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM,)f+) 150.0
r
80
D e p f h Prof
lies
FIGURE 118
160
STATION E2
5.0
DENSITY
25.0
.2
CHLOROPHYLL
(X)
1.0
a.
Ui
a
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
(=>)
ifiJI
.2
- LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM.)^+) 150.0
FIGURE 119
161
STATION E3
x
5.0
.2
DENSITY
chlorophyll"
(*)
25.0
1,0
.5
PHOSPHATE
(*>
2.5
2.0
OXYGEN
(°)
SLSL
.2
-LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM.)f+) 150.0
20
40
•^ a>
\
-/
./
\
'A
60
80
D e p I h P r o ! i I
e $
FIGURE 120
162
X
5.0
.2
STATION E4
DENSITY
25.0
CHLOROPHYLL
(X)
1.0
.5
PHOSPHATE
(A)
2.5
L'J
o
20
40
2.0
.2
30.0
OXYGEN
(«)
J0JL
- LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUM.)M 150.0
60
80
D e p I h Pr oli I
e $
FIGURE 121
16 3
X
Ul
a
5.0
STATION E5
DENSITY
25.0
.2
CHLOROPHYLL
(X)
1.0
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
(°)
10.0
.2
LN TRANSMITTANCE
(0)
30.0
1.0
PARTICLE VOLUME (CUM.)^) 150.0
80
10C
Depth Profile
FIGURE 122
164
40
60
80
10G
Depth Profile
FIGURE 123
165
I
►—
0-
UJ
O
5.0
S T A T I O N E7
DENSITY
25.0
.2
CHLOROPHYLI
(X)
1.0
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
C°)
!0x£_
.2
- LN TRANSMITTANCE
(0)
0
30.0
20
PARTICLE VOLUME (CUM.)(» 150.0
40
60
80
iod
Depth P r o f i I
e s
F I G U R E 124
166
5.0
STATION F1
DENSITY
25.0
.2
CHLOKUKHYLL
i*l
1.0
.5
PHOSPHATE
(*,
2.5
"77T
OXYGEN
M
10.0
!0
"2"
40.0
-LN TRANSMITTANCE (0)
_Lfl.
PARTICLE
-& v5
VOLUME (CUM.)(+) 200.0
10
)C
D e p » h P r o f i I
e s
FIGURE 125
167
I
0.
UJ
O
STATION F2
density""
25.0
.2
CHLOKOKHYLL
s*±
1.0
.5
"2TTT
PHOSPHATE
(a)
2.5
OXYGEN
(°)
0.0
zz
40.0
- LN TRANSMITTANCE (0) 1.0
PARTICLE
VOLUME (CUM.)(+) 200.0
D e p f h P r o I i
e s
F I G U R E 126
168
D e p Ih P r o f i
e $
FIGURE 127
169
STATION G2
J
5.0
DENSITY
25.0
I
.2
CHLOROPHYLL
(*)
1.0
t—
.5
PHOSPHATE
(A)
2.5
0-
L'J
2.0
OXYGEN
(&)
10.0
a
.2
-LN TRANSMITTANCE
(0)
1.0
0
• 30.0 ,
_ , rrx-i —
-K—
PARTICLE VOLUME (CUM
-J- — — — fT —X
.)(+)
150.0
i rri <_
20
40
60
80
10C
Depth Profile
FIGURE 128
170
S Y A T 1 O N G3
5.0
DENSITY
25.0
.2
CHLOROPHYLL
(*)
1.0
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
(<=>)
10.0
.2
- LN TRANSMITTANCE
(0)
1.0
. 30.0
. . ■ — (-X
PARTICLE VOLUME
. ^i- . »^4
(CUM.)M
150.0
1—
0
20
40
Depth P r o f i
e $
FIGURE 129
171
.0
STATION G4
density""
25.0
.2
CHLOROPHYLL
(*)
1,0
0-
.5
PHOSPHATE
(*>
2.5
2.0
OXYGEN
(a)
10.0
.2
- LN TRANSMITTANCE
(0
1.0
30.0
PARTICLE VOLUME (CUM.V+) 150.0
Depth P r o I i I
FIGURE 130
172
J,
X
»—
o-
o
0
5.0
STATION G5
DENSITY
25.0
.2
CHLOROPHYLL
(*)
_L0
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
M
10^0
.2
-LN TRANSMITTANCE
(0)
1.0
30.0
PARTICLE VOLUME (CUM.)M 150.0
80
10C
Depth P r o f i I
FIGURE 131
173
J
X
D-
UJ
a
5.0
.2
STATION G6
density"""
chlorophyll
(X)
25.0
1,0
.5
2.0
.2
30.0
PHOSPHATE
(A)
2.5
OXYGEN
(«)
JO^H.
- LN TRANSMITTANCE
(0)
1.0
PARTICLE VOLUME (CUMJM 150.0
Depth Profile
FIGURE 132
174
2.0
— T"
- LN TRANSMITTANCE
60.0
PARTICLE VOLUME (CUlO (+ ^____2^;_n__
Dep*h Profiles
FIGURE 133
175
STATION HI
J
X
5,0
DENSITY
2UL
.2
CHLOROPHYLL
i*L
1.0
.5
PHOSPHATE
r^)
2.5
2.0
OXYGEN
(CO)
10.0
.2
10.0
- LN TRANSMITTANCE
(0)
PARTICLE VOLUME (CUM.) (+)
V V-^
-- ■? -X! J
1.0
■m
50.0
.J-
Depth P r o f i
e s
FIGURE 134
176
5,0
.2
STATION H2
PENSJIY.
CHLOROPHYLL
M
25l>£l
1.0
.5
PHOSPHATE
(A)
2.5
2.0
OXYGEN
(a)
10.0
.2
10.0
K &
LN TRANSMITTANCE
(0)
PARTICLE VOLUME (CUM.)(+)
1.0
50.0
Depth Profile
FIGURE 135
177
STATION H3
.2
DENSITY
CHLOROPHYLL ..
PHOSPHATE
i*i
(A)
1-9.
.2
OXYGEN
(a)
- LN TRANSMITTANCE
(0)
,25^0_
1.0
2.5
10.0
1.0
lO^F" PARTICLE VOLUME (CUM.) O) 50.0
Depth Profiles
FIGURE 136
178
5.0.
.2
STATION 11
DENSITY
CHLOROPHYLL
.5
2.0
PHOSPHATE
OXYGEN
0=0
- LN TRANSMITTANCE
(0)
60.0
25.0.
1.0
2.5
10.0
1.0
PARTICLE VOLUME (COM.) (+Y J^Ll
10C
Depth P r o I i I « »
FIGURE 137
179
STATION 12
E
x
o.
LU
o
5.0
DENSITY
2ZJL
.2
CHLOROPHYLL
-Gil
1.0
.5
PH,QSPH&XE_
(A)
2.0
"72"
OXYGEN
Co;
10.0
LN TRANSMITTANCE
(0)
1.0
60.0
PARTICLE VOLUME (CUM.) (+)' 300.0
D e p f h Profit
e s
OS.
FIGURE 138
180
STATION 13
5.0
DENSITY
25tQ
.2
CHLOROPHYLL
1*1
1.0
.5
PHOSPHAIE.
(A)
2.5
2.0
OXYGEN
CO
10.0
o
0
- LN TRANSMITTANCE
(0)
1,0
• 60.0
rr-i — j>*— **— sf —
PARTICLE VOLUME (CUM.) (+)' 300.0
P
80
oc
Depth Profile
FIGURE 139
181
5.0
STATION 14
DENSITY
25_J2_
CHLOROPHYLL
£11
1.0
PHOSPHATE
(*)
2.5
2.0
OXYGEN
(o)
10.0
- LN TRANSMITTANCE
(0)
1.0
60.0
PARTICLE VOLUME (CUM.) (+) 300.0
od
Depth Profile
FIGURE 140
182
Depth Profile
FIGURE 141
183
S T A T 1 O N 16
J
5.0
DENSITY
25.0
I
.2
CHLOROPHYLL
00
1.0
>-
.5
PHOSPHATE
(A)
2.5
UJ
2.0
OXYGEN
(a)
10.0
O
.2
- LN TRANSMITTANCE
(0)
1.0
0
■ 60.0
___ y j^j ,£_ _.
PARTICLE VOLUME (GUM.)
(+)
300.0
t_.
30
oc
D e p t h P r o f i I
e s
FIGURE 142
184
STATION 17
5.0
DENSITY
25,0
CHLOROPHYLL
_<*!
1.0
.PHOSPHATE
(A)
2.5
2.0
OXYGEN
CO
10.0
-LN TRANSMITTANCE
CO)
1.0
60.0
PARTICLE VOLUME (CUM.) (+) 300.0
D e p t h Prof
lies
FIGURE 143
185
STATION 18
5.0
DENSITY
25,0
CHLOROPHYLL
£1
1.0
PHOSPHATE
(A)
2.5
2.0
OXYGEN
CO)
10.0
- LN TRANSMITTANCE
(0)
1.0
60.0
PARTICLE VOLUME. (CUM.) (+) 300.0
^1
Depth P r o I i I
e $
FIGURE 144
186
STATION 19
!
J 5.0
DENSITY
25.0
.2
CHLOROPHYLL (X)
1.0
o. *5
PHOSPHATE (»
2.5
2.0
OXYGEN (o)
10.0
2
- LN TRANSMITTANCE (0)
1.0
• 60.0
.^.*v__.
PARTICLE VOLUME (CUM.) (+)
300.0
\)
Lit
\
L .. * - ,
■',■■
20 7
\
Vd v, \
40
60
80
IOC
Depfh Profiles
FIGURE 145
187
STATION J1
5.0
DENSITY
2LJL
.2
CHLOROPHYLL
S*L
1.0
PJPSTOIL
(*)
2.5
2.0
~2™
OXYGEN
CO
10.0
- LN TRANSMITTANCE
(0)
1.0
60.0
PARTICLE VOLUME (CUM.) (+) 300.0
x-- f
'
Depth Profit
e s
FIGURE 146
188
STATION J2
5.0
DENSITY
25,9
.2
CHLOROPHYLL
1*1
1.0
PHOSPHATE
(A)
2.5
UJ
D
2.0
OXYGEN
CO)
- LN TRAN SM I TTAN C E
(0)
10.0
1.0
20
PARTICLE VOLUME (CUM.) (+) 300.0
40
60
80
10C
Depth Prof
lies
FIGURE 147
189
J
I
*-
a.
Ui
a
5.0
.2
2.0
60.0
STATION J3
DENSITY
CHLOROPHYLL
1*1
PHQSPHATE
fA)
OXYGEN
CO)
— LN TRANSMITTANCE
(0)
>-i
25rQ
1.0
2.5
10.0
1.0
PARTICLE VOLUME (CUM.) (+)' 300.0
Deplh Profiles
FIGURE 148
190
STATION J4
5.0
DENSITY
25, 0
CHLOROPHYLL
<*1
1.0
.5
P20S£HAJIL
(*)
2.5
2.0
OXYGEN
CO)
10.0
- LN TRANSMITTANCE
(0)
1.0
• 60.0
PARTICLE VOLUME (CUM.) (+) 300.0
■. y
rX
S
Depth Profiles
FIGURE 149
191
X
UJ
a
5.0
STATION K1
DENSITY
25.0
CHLOROPHYLL
(X)
1.0
PHOSPHATE
(A)
20
2.0
80.0
OXYGEN
M
- LN TRANSMITTANCE
(0)
10.0
1.0
PARTICLE VOLUME (CUM.)(+)
400.0
40
60
80
10C
Depth Profiles
FIGURE 150
192
J
X
►-
a.
UJ
a
5.0
STATION K2
DENSITY
25.0
CHLOROPHYLL
(X)
1.0
PHOSPHATE
(A)
2.5
2.0
.2
8-0.0
OXYGEN
M
- LN TRANSMITTAIICE
(0)
10.0
1.0
PARTICLE VOLUME (CUM.)(+) 400.0
80
Dep*h Profiles
FIGURE 151
193
STATION K3
J
5.0
DENSITY
25.0
I
.2
CHLOROPHYLL (X)
1.0
►-
.5
PHOSPHATE (A)
2.5
Ul
2.0
OXYGEN (a)
10.0
a
.2
- LN TRANSMITTANCE (0)
1.0
0
. 80.0
PARTICLE VOLUME (CUM.)f»
400.0
y ^ /
• - .
20
40
X
Y
y\ /
60
i
1
60
1
i
lUC
Depth Profiles
FIGURE 152
194
STATION K4
5.0
DEN SI IT
25.0
CHLOROPHYLL
(X)
1.0
.5
PHOSPHATE
(*)
2.5
2.0
.2
OXYGEN
(a)
- LN TRANSMITTANCE
(0)
10.0
1.0
VOLUME (CUM.)fr)
400.0
D e p I h Prof
e s
FIGURE 153
195
5.0
STATION K5
DENSITY
25.0
CHLOROPHYLL
(X)
1.0
PHOSPHATE
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FIGURE 154
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FIGURE 157
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FIGURE 158
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FIGURE 159
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FIGURE 160
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FIGURE 161
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FIGURE 162
204
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FIGURE 163
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FIGURE 164
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FIGURE 165
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FIGURE 166
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F i G U R E 167
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FIGURE 168
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FIGURE 170
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222
TABLE II
STATION DATA: LOCATION, TIME, DATE, DEPTH, WEATHER,
SOUND VELOCITY, TEMPERATURE, TRAMSMITTANCE ,
OXYGEN, PHOSPHATE AND CHLOROPHYLL
STATICN: Al DEPTH: 69M D4TE 6 NOV 70 TIME: 1C15
LA7: 36-39. ON LONG: 121-54. 1V\ WIND: 190 SPEED: 12
AIR TEMP(DRY): 58 BARO: 30. C9 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 190-1 SWELL: 240-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(MJ
SALINITY
(O/OO)
0
32.965
10
32.967
30
33.084
50
33.450
68
33.479
OXYGEN
(ML/L)
6.21
6.31
6.45
5.83
5.95
PHCSPHATE
(MG-ATM/L)
0.39
0.40
0.49
0.90
C.97
CHLOROPHYLL
(MG/M3)
0.140
0.169
0.173
0.371
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(MJ
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.93
1500.5
85.7
10
13.42
1500.5
63.8
18
13.30
15CC.3
84.8
28
13.08
1499.9
87.0
38
12.63
14S£.7
83.7
48
12.38
1498.2
81.5
56
12.20
1497.9
79.5
61
12.17
1497.9
79.1
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
13.93
1500.5
85.7
10
13.42
1500.5
83.8
20
13.26
1500.2
85.2
30
12.99
1499.7
86.3
50
12.33
1498.1
81.0
32.965 6.21 0.39 C.140 24.65
32.967 6.31 0.40 0.169 24.76
33.025 6.38 0.45 0.171 24.83
33.C64 6.45 0.49 0.173 24.93
33.450 5.83 0.90 0.371 25.34
o o "}
STATION: A2 DEPTH: 76M DATE: 1 NOV 70 TIME: 0920
LAT: 36-40. 7N LONG: 121-54. 2W HIND: 190 SPEED: 12
AIR TEMP(DRY): 58 BARO: 30.09 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 190-1 SWELL: 240-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
32.992
18
32.997
35
33.135
57
33.469
75
33.539
OXYGEN
(ML/L)
5.62
6.26
5.27
5.23
5.52
PHOSPHATE
(MG-ATM/L)
0.39
0.40
0.50
0.97
1.22
CHLOROPHYLL
(MG/M3)
0.361
0.595
0.008
0.418
0.536
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.48
1500.5
84.9
10
13*47
15CC.6
84.0
21
13.39
15CC.5
83.0
28
13.19
1500.2
85.0
38
12.57
1496.5
84.5
47
12.42
1498.4
81.2
57
12.19
14 9 7.7
80.3
67
11.84
1496.8
82.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.48
1500.5
84.9
10
13.47
1500.6
84.0
20
13.40
1500.5
83.1
30
13.07
1499.9
84.9
50
12.35
1498.2
80.9
75
32.992 5.62 0.39 0.361 24.76
32.994 5.98 0.39 0.491 24.77
33.C13 6.14 0.41 C.526 24. 8C
33.094 5.56 0.47 C.181 24.93
33.363 5.25 0.82 0.288 25.27
33.539 5.52 1.22 0.536
224
STATION: A3 DEPTH: 78M DATE: 6 NOV 70 TIME: 0835
LAT: 36-42. IN LONG: 121-54.,21-i WIND: 135 SPEED: 10
AIR TEMP(DRY): 54 BARO: 30. C4 CLOUD AMT: 8
HEIGHT(FT): 1500 SEA: 135-1/2 SWELL: 230-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHvLL
(MG/M3)
0
33.000
5.65
0.43
0.174
15
32.995
6.34
0.2C0
35
33.064
5.7C
0.46
0.142
50
33.226
5.26
0.59
0.266
65
33.434
5.99
0.89
0.442
77
33.635
4.40
1.83
OBSERVED VALUES ( SV/T/D-TRANSMISSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO., VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
1 3 ■ 4 5
1 5 0 C . 4
80. t>
8
13.45
15C0.6
80.2
24
13.40
1 5 G C . 7
81.3
38
13.09
15CC.1
84.9
48
12.71
1499.1
86. 1
58
12.18
1497.6
84.6
67
11.61
1495.6
82.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHCS CHLOR SIG-T
0
13.45
1500.4
80.5
10
13.44
1500.6
80.3
20
13.41
1500.7
81.0
30
13.27
1500.4
82.8
50
12.60
1498.8
85.8
75
33.000 5.65 0.43 0.174 24.78
32.997 6.11 0.191 24.77
33.C12 6.18 0.185 24.79
33.C47 5.86 0.156 24.85
33.226 5.26 0.59 0.266 25.12
33.6C1 4.66 1.67 0.C74
225
STATION: A4 DEPTH: 87M DATE: 6 NOV 70 TIME: 3745
LAT: 36-43. 7N LONG: 121-54. 5W WIND: 135 SPEED: 10
AIR TEMP(DRY): 54 8AR0: 30.04 CLOUD AMT: 8
HEIGHT(FT): 1500 SEA: 135-1/2 SWELL: 230-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLCPCPHYLL
(MG/M3)
0
32.984
6.00
0.42
0.176
15
32.979
5.92
0.42
0.197
35
32.036
6.00
0.43
0.205
55
33.285
5.61
0.68
0.198
70
33.531
5.19
1.08
0.734
86
33.719
4.21
1.92
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCt.
(0/0)
0
13.60
15CC.2
76.8
10
13.35
1500.3
79.0
24
13.32
150C.4
79.5
38
13.18
15CC.3
85.0
47
12.72
1499.2
87.7
56
12.15
1497.4
87.4
65
11.96
1497.2
80.3
69
11.52
1495.7
60.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.60
1500.2
78.8
10
13.35
1500.3
79.0
20
13.33
1500.4
79.4
30
13.26
1500.4
81.9
50
12.53
1498.6
87.6
75
32.984 6.00 0.42 0.176 24.73
32.981 5.95 0.42 0.190 24.78
32.993 5.94 0.42 0.199 24.80
33.021 5.98 0.43 0.203 24.83
33.223 5.71 0.62 0.200 25.13
33.59C 4.89 1.34 0.505
226
STATION: A5 DEPTH: 82M DATE: 6 NOV 70 TIME: 0632
LAT: 36-45. 5N LONG: 121-54. 4h WIND: 130 SPEED: 1C
AIR TEMP(DRY): 53 BARO: 30.01 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 130-1 SWELL:27C-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.008
20
33.019
40
33.102
65
33.320
81
33.785
OXYGEN
(ML/L)
0.0
6.24
6.44
6.26
5.07
PHGSPHATE
(MG-ATM/L)
0.42
0.43
0.4 7
0.76
1.98
CHLOROPHYLL
(MG/M3)
0.173
0.249
0.244
0.293
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.27
1499.9
77.2
7
13.27
15C0.C
77.4
19
13.24
15C0.1
77.1
29
13.26
1500.3
78.2
38
13. C9
15CC.1
79.2
47
12.81
1499.4
79.1
62
11.95
1496.9
80.7
71
11.86
1497. C
69.5
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.27
1499.9
77.2
10
13.26
1500.0
77.3
20
13.24
1500.1
77.2
30
13.24
1500.3
78.3
50
12.64
1498.9
79.4
75
33.008 0.0 0.42 0.173 24.82
33.014 3.12 0.42 0.211 24.82
33.019 6.24 0.43 0.249 24.83
33.C6C 6.34 0.45 C.246 24.86
33.189 6.37 0.59 C.264 25.08
33.611 5.52 1.52 C.11C
227
STATION: A6 DEPTH: 450M DATE: 6 NOV 70 TIKE: 0450
LAT: 36-46. 6N LONG: 121-54.'^ WIND: LIGHT AIRS
AIR TEMP(DRY): 54 BARO: 30.05 CLOUD AMT: 2
HEIGHT(FT): 1500 SEA: CALM SWELL: 27C-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.084
20
33.131
35
33.300
60
33.533
80
33.692
105
33.871
OXYGEN
(ML/L)
6.47
6.42
6.56
5.37
3.73
2.86
PHOSPHATE
(MG-ATM/L)
0.45
0.50
0.56
1.20
1.75
2.12
CHLOROPHYLL
(MG/M3I
0,
,213
0,
,369
0,
,651
0,
,461
0,
,161
0,
.077
OBSERVED VALUES { SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO., VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.28
i c;rn n
*70 O
9
13.30
1500.2
78.6
18
13.28
15CC.3
77.1
31
13.06
1499.9
73.4
46
12.69
1499.2
76.6
55
11.03
14 94.8
80. 6
74
10.33
1491.9
52.7
84
9.89
14S0.6
59.2
100
9.15
1488.2
68.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
13.28
1500.0
79.8
10
13.30
1500.2
78.4
20
13.25
1500.2
76.5
30
13. C8
1499.9
73.7
50
11.95
1497.2
78.4
75
10.29
1491.8
53.3
00
9.15
1488.2
68.7
33.084 6.47 0.45 0.213 24.88
33.108 6.44 0.48 0.291 24.89
33.131 6.42 0.50 0.369 24.92
33.243 6.52 0.54 0.557 25.04
33.439 5.85 0.94 0.537 25.41
33.652 4.14 1.61 0.236 25.87
33.835 3.03 2.04 0.094 26.20
228
STATION: A7 DEPTH: I46M DATE: 6 NOV 70 TIME: 0315
LAT: 36-49. 6N LONG: 121-54. 2k WIND: LIGHT AIRS
AIR TEMP(DRY): 54 BARO: 30-06 CLOUD AMT: 2
HEIGHT(FT): 1500 SEA: CALM SWELL: 27C-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PFCSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.284
6.19
0.53
0.353
10
33.288
6.45
0.52
0.118
25
33.386
6.26
0.63
0.6C5
50
33.457
5.44
1.07
0.327
60
33.571
4.68
1.40
0.286
85
33.663
3.95
1.71
0.229
100
33.873
3.19
2.19
0.075
OBSERVED VALUES ( SV/T/D-TR ANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.95
1499.1
70.9
10
12.84
1499.0
81.1
20
12.59
1498.4
75.1
48
11.53
1495.2
82.8
58
11.06
1494. C
82.1
77
10.64
1493.0
57.7
87
10.23
1491.6
50.0
107
9.03
1488.0
54.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
12.95
1499.1
70.9
10
12. 84
1499.0
81.1
20
12.59
1498.4
75.1
30
12.21
1497.3
77.8
50
11.44
1495.0
82.7
75
10.68
1493. 1
60.3
100
9.45
1489.3
52.8
33.284 6.19 0.53 0.353 25.10
33.288 6.45 0.52 0.118 25.12
33.353 6.33 0.60 0.443 25.22
33.400 6.10 0.72 C.549 25.33
33.457 5.44 1.07 0.327 25.52
33.626 4.24 1.59 0.252 25.78
33.873 3.19 2.19 C.075 26.18
229
STATION: A8 DEPTH: 73M DATE: 6 NOV 70 TIME: C230
LAT: 36-49. 7N LONG: 121-54. 3W WIND: LIGHT AIRS
AIR TEMP(DRY): 54 BARO: 30.06 CLOUD AMT: 2
HEIGHT(FT): 1500 SEA: CALM SWELL: 270-2
. OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.231
6.56
0.51
0.697
5
33.308
6.51
0.54
0.666
25
33.389
6.24
0.69
0.691
45
33.408
5.22
1.07
0.292
65
33.523
4.89
1.31
0.234
72
33.564
4.74
•
1.47
OBSERVED VALUES ( SV/T/D- TRANSMI S SOMETE R CAST)
CEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
1 ?.8A
1498.8
77.8
4
12.84
1496.9
76.9
15
12.48
1496.0
73.8
30
12.23
1497.5
76.1
50
11.31
1494.6
86. C
69
11.13
1494.5
52.9
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLCR SIG-T
0 12.84 1498.8
10 12.64 1498.4
20 12. 4C 1497.8
30 12.23 1497.5
50 11.31 1494.6
77.8 33.231 6.56 0.51 0.697 25.08
75.2 33.32£ 6.44 0.58 0.672 25.19
74.6 33.369 6.30 0.65 C.685 25.27
76.1 33.394 5.98 0.79 0.591 25.32
86.0 33.437 5.14 1.13 0.277 25.52
230
STATION: A9 DEPTH: 59M DATE: 6 NOV 70 TIKE: C130
LAT: 36-51. 2N LONG: 121-54. 3W KIND: LIGHT AIRS
AIR TEMP(DRY): 54 BARO: 30. C6 CLOUD AMT: 2
HEIGHT(FT): 1500 SEA: CALM SWELL: 27C-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PhCSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.150
6.28
0.51
0.234
10
33.175
6.35
0.49
0.4C5
20
33.331
6.24
0.64
0.493
30
33.352
6.15
0.74
0.456
40
33.358
5.83
0.93
0.530
50
33.474
5.43
1.14
0.473
58
5.50
1.25
0.591
OBSERVED VALUES ( SV/T/D- fRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.18
1499.8
77.5
4
13.13
1499.8
77.9
10
12.96
1499.3
77.5
20
12. 64
1498.5
81.0
30
12.34
1497.5
80. 1
4C
11.56
1495.1
86.9
43
11.67
1495.5
50.5
49
11.96
1496. C
33.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.18 1499.8
10 12.96 1499.3
20 12.64 1498.5
30 12.34 1497.5
50
77.5 33.150 6.28 0.51 0.234 24.95
77.5 33.175 6.35 0.49 0.405 25.01
81.0 33.331 6.24 0.64 C.493 25.19
80.1 33.352 6.15 0.74 0.456 25.27
33.474 5.43 1.14 0.473
231
STATION: AlO DEPTH: 36M DATE: 6 NOV 70 TIME: 0040
LAT: 36-52. 7N LONG: 121-54. 3W WIND: CALM
AIR TEMP(DRY): 54 BARO: 30.10 CLOUD AMT: 10
TYPE: FOG SEA: CALM SWELL: 270-3
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLCROPHYLL
(MG/M3)
0
5
10
20
30
35
33.134
33.130
33.136
33.323
33.397
33.401
6.32
6.33
6.43
6.37
6.14
6.20
0.51
0.49
0.52
0.60
0.7C
0.79
0.450
0.318
0.334
0.372
0.654
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(C/0)
n
5
9
14
20
30
13, 14
13.14
13.12
12.70
12.45
12.40
1499.6
14 99.7
1499.7
1499.7
1497.9
1497.9
80.3
78.9
78.4
81.0
82.8
64.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.14 1499.6
10 13.04 1499.7
20 12.45 1497.9
30 12. 4C 1497.9
80.3 33.134 6.32 0.51 C.450 24.94
78.9 33.136 6.43 0.52 0.334 24.96
82.8 33.323 6.37 0.60 C.372 25.22
64.2 33.397 6.14 0.70 0.654 25.29
232
STATION: All DEPTH: 22M DATE: 6 NOV 70 TIME: 0005
LAT: 36-54. 2N LONG: 121-54. 3W WIND:CALM
AIR TEMP(DRY): 54 BARO: 30. iC CLOUD AMT: 10
TYPE: FOG SEA: CALM SWELL: 270-3
DEPTH
<M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
10
18
21
33.242
33.303
33.326
6.68
6.60
6.52
6.49
0.52
0.56
0.61
0.65
0.259
0.539
0.467
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
<C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
5 •
in
17
13.07
12.89
1 2.82
12.74
1499.5
1499.0
1498.9
1498.8
84.1
77.7
73.6
55.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13. C7 1499.5 84.1 33.242 6.68 0.52 0.259 25.04
10 12.82 1498.9 73.6 33.303 6.60 0.56 0.539 25.14
20 6.50 0.64 0.156
233
STATION: A12 DEPTH: 17M DATE: 5 NOV 70 TIME: 2320
LAT: 36-55. 7N LONG: 121-54. 4W WIND: CALM
AIR TEMP(DRY): 54 BARO: 30.10 CLOUD AMT: 10
TYPE: FOG SEA: CALM SWELL: 27C-3
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
6
12
15
32.243
33.259
33.268
32.273
6.41
6.53
6.49
6.45
0.55
0.53
0.56
0.63
0.282
0.265
0.401
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.95
1499. 1
78.0
3
12.95
1499.2
78.8
6
12.93
1499.2
77.8
C
12.92
1499.1
74.9
12
12.91
1499.2
70.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.95 1499.1
10 12.93 1499.2
78.0 33.243 6.41 0.55 0.282 25.06
77.7 33.265 6.50 0.55 0.356 25.08
234
STATION: Bl DEPTH: 15M DATE: 5 NOV 70 TIME: 2214
LAT: 36-56. 3N LONG: 121-59. Ik WIND: CALM
AIR TEMP(DRY): 54 BARO: 30.10 CLOUD AMT: 10
TYPE". FOG SEA: CALM SWELL: 270-2
OBSERVED VALUES (NANSEN CAST)
EPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
( MG/M3)
0
33.168
6.29
1.17
1.032
3
33.188
6.21
1.18
1.188
6
33.177
6.07
1.12
0.790
8
33.246
6.13
0.84
0.7C5
10
33.337
6.34
1.05
1.059
14
33.412
6.11
1.17
1.685
OBSERVED VALUES ( SV/T/D-T RANSMISSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
n
13.17
149 9.6
63.0
3
13.17
1499.7
68.0
6
13.14
1499,9
79. C
9
12.99
1499.5
45.0
12
12.70
12.70
149 8.7
25.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. GXY PHOS CHLOR SIG-T
0 13.17 1499.6
10 12.89 1499.2
68.0 33.168 6.29 1.17 1.032 24.96
38.4 33.337 6.34 1.05 1.C59 25.15
235
STATION: B2 DEPTH: 29M DATE: 5 NOV 70 TIME: 2115
LAT: 36-54. 8N LONG: 121-59. lvJ WIND: CALM
AIR TEMP(DRY): 54 BARC: 30. C7 CLOUC AMT: 10
TYPE: FOG SEA: CALM SWELL: 27C-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.372
5
33.372
10
33.375
20
33.435
25
33.450
OXYGEN
(ML/L)
6.66
6.71
6.7C
6.39
6.10
PHOSPHATE
(MG-ATM/L)
0.48
0.50
0.48
0.70
0.86
CHLOROPHYLL
(MG/M3)
0.697
0.694
0.839
0.965
1.029
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.84
1496.9
62.8
c;
L 2 e 8 1
14 9 8.9
61.3
10
12.80
1498.9
61.3
14
12.77
1499.0
65.3
19
12.47
149 7.4
45.8
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.84 1498.9 62.8 33.372 6.66 0.48 0.697 25.19
10 12.80 1498.9 61.3 33.375 6.70 0.48 0.839 25.19
20 33.435 6.39 0.70 0.965
236
STATION: B3 DEPTH: 36M DATE: 5 NOV 70 TIKE: 2005
LAT: 36-53. 4N LONG: 121-59. IV. WIND: CALM
AIR TEKP(DRY): 54 BARO: 30. C7 CLOUD AMT: 10
TYPE: FOG SEA: CALM SWELL: 270-2
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
5
10
15
25
35
33.370
33.360
33.364
33.355
33.457
33.480
6.65
6.44
6.52
6.45
6.33
5.79
0.47
0.47
0.56
0.57
0.67
0.97
0.488
0.531
0.475
0.521
0.999
OBSERVED VALUES ( S V/T/D- TRANSMIS SOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
Q
5
9
14
19
24
29
12,9^
12.89
12.71
12.46
12.47
12.44
12.34
1499-1
1499.0
1498.5
1498.2
1498.0
1498.0
1497.9
75.0
77.7
81.2
81.1
64.9
55.5
39.5
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.93 1499.1
10 12.66 1498.4
20 12.46 1498.0
30
75.0 33.370 6.65 0.47 0.488 25.17
81.2 33.364 6.52 0.56 0.475 25.21
63.0 33.406 6.39 0.62 0.760 25.28
33.466 6.06 0.82 0.499
237
STATION: 84 DEPTH: 68M DATE: 5 NOV 70 TIME: 1847
LAT: 36-51. 6N LONG: 121-59. 4W WIND: LIGHT AIRS
AIR TEMP(DRY): 54 BARO: 30.05 CLOUD AMT: 7
HEIGHT(FT): 5000 SEA: RIPPLES SWELL: 215-3
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/LI
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3J
0
15
25
40
60
66
33.257
33.361
33.449
33.516
33.490
6.51
6.63
5.91
5.86
5.66
5.66
0.48
0.54
C.87
0.96
1.06
0.347
0.521
1.278
1.277
0.641
1.022
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
4
9
14
19
28
38
48
58
12.84
12.83
12.78
12.77
12.77
12.22
12.07
12.09
12.10
1498.8
1498.8
1498.8
1498.9
1499.0
1497.4
1497.1
1497.4
1497.6
80.0
76.8
73.5
65.2
62.5
80.1
64.7
47.8
31.9
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0 12.84 1498.8
10 12.78 1498.8
20 12.71 1498.8
30 12.19 1497.3
50 12.09 1497.4
80.0 33.257 6.51 0.48 0.347 25.10
71.8 33.326 6.59 0.52 0.463 25.16
64.5 33.405 6.27 0.70 0.899 25.24
77.0 33.471 5.90 0.90 1.278 25.39
44.6 33.503 5.76 1.01 0.959 25.43
238
STATION: B5 DEPTH: 86M DATE: 5 NOV 70 TIME: 1710
LAT: 36-50. 5N LONG: 121-59. 1W WIND: LIGHT AIRS
AIR TEMP(DRY): 54 BARO: 30. C5 CLOUD AMT: 7
HEIGHT(FT): 5000 SEA: RIPPLES SWELL: 215-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.213
6.34
0.55
0.441
5
33.242
6.53
0.55
0.425
10
33.272
6.44
0.55
0.649
15
33.285
6.15
0.53
0.821
20
33.316
6.51
0.55
0.849
30
33.407
6.32
0.67
0.551
50
33.490
5.52
1.08
0.376
70
33.577
4.62
1.51
0.296
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TPMP
(C)
<: n . \/ r- 1
(M/SECT
TRAN^MTTTAMPF
(0/0)
0
13.32
15CC.2
60.1
7
13.28
15C0.2
59.5
10
13.25
15CC.C
58.7
19
12.77
1498.9
61.9
27
12.56
1498.5
65.8
48
11.84
1496.2
77.8
69
11.06
1494.6
52.1
73
11.04
1494.2
55.4
DEPTH
INTERPOLATED VALUES
TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.32 1500.2
10 13.25 1500. C
20 12.74 1498.8
30 12.46 1498.2
50 11.77 1496.0
60.1 33.213 6.34 0.55 0.441 24.97
58.7 33.272 6.44 0.55 0.649 25.03
62.4 33.316 6.51 0.55 0.649 25.16
67.5 33.407 6.32 0.67 0.551 25.29
75.4 33.490 5.52 1.08 0.376 25.48
239
STATION: B6 DEPTH: 549M DATE: 5 NOV 70 TIME: 1545
LAT: 36-48. 9N LONG: 122-59. 1W WIND: LIGHT AIRS
AIR TEMP(DRY): 66 BARO: 30. C5 CLOUD AMT: 7
HEIGHT(FT): 3000 SEA: RIPPLES SWELL: 180-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(K)
SALINITY
(0/00)
0
33.042
15
33.075
35
33.388
45
33.431
75
33.613
100
33.669
OXYGEN
(ML/L)
6.22
6.16
6.38
6.11
4.02
3.62
PHOSPHATE
(MG-ATM/L)
0.44
0.47
0.53
0.66
1.61
1.75
CHLOROPHYLL
(MG/M3)
0.233
0.251
0.757
1.0C9
0.210
0.262
OBSERVED VALUES ( SV/T/D- TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
Q
1 ?r3]
1 5CC.1
75.6
10
13.28
1500.1
74.9
25
13.08
1499.9
69.2
40
12.64
1498.9
72.1
48
12.25
1497.8
70.9
59
11.52
1496.3
77.7
78
10.75
1493.3
88.4
98
10.38
1492.5
66.1
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-1
0
13.31
1500.1
75.6
10
13.28
1500.1
74.9
20
13.15
1500.0
71.1
30
12.93
1499.6
7C.2
50
12. 12
1497.5
72.1
75
10.87
1493.8
86.7
100
33.042 6.22 0.44 0.233 24.84
33.064 6.18 0.46 0.245 24.86
33.153 6.22 0.48 0.377 24.96
33.310 6.33 0.52 0.630 25.12
33.462 5.76 0.82 0.876 25.39
33.613 4.02 1.61 0.210 25.74
33.669 3.62 1.75 0.262
240
STATION: B7 DEPTH: M DATE: 5 NOV 70 TIME: 1515
LAT: 36-47. 2N LONG: 121-58. f.W WIND: 270 SPEED: 6
AIR TEMP(DRY): 66 BARO: 30.06 CLOUD AMT: 7
HEIGHT(FT): 3000 SEA: RIPPLES SWELL: 180-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.012
6.14
0.47
0.186
10
33.016
6.31
0.46
0.181
25
32.083
6.28
0.47
0.345
50
33.410
6.C8
0.69
1.099
75
33.505
4.84
1.27
0.5C9
100
33.638
3.81
1.64
0.244
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO., VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.42
15CC.5
76.2
10
13.29
150C.2
73.0
25
13.18
1500.1
71.9
49
12.29
1498.0
67.5
59
11.88
1496.6
78.0
78
10.82
1493.6
84.2
97
10.47
1492.7
50.8
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
33.012 6.14 0.47 0.186 24.79
33.016 6.31 0.46 C.181 24.82
33.061 6.29 0.47 C.290 24.87
33.149 6.24 0.51 0.496 24.98
33.41C 6.08 0.69 1.C99 25.33
33.5C5 4.84 1.27 C.509 25.63
33.638 3.81 1.64 0.244
0
13.42
1500.5
76.2
10
13.29
1500.2
73.0
20
13.22
1500.1
72.3
30
12.99
1499.7
71.0
50
12.25
1497.9
68.5
75
10.99
1494.1
83.2
100
241
STATION: B8 DEPTH: 805M DATE: 5 NOV 70 TIME: 1245
LAT: 36-45. 9N LONG: 121-59. 1W WIND: 230 SPEED: 12
AIR TEMP(DRY): 56 BARO: 30.08 CLOUD AMT: 10
HEIGHT(FT): 100C SEA: 200-2 SWELL: 180-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.016
6.14
0.46
0.222
15
33.011
6.39
0.48
0.175
37
33.166
6.32
0.51
0.461
57
33.448
5.99
0.78
0.570
85
33.592
4.26
1.49
0.076
110
33.686
3.57
1.78
0.153
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
C
13-^5
1 5 0 C - 3
77.3
14
13.27
1500.1
76.6
28
13.17
1500.1
78.5
38
12.78
1499.2
77.1
58
12.00
1497.1
79.1
85
10.74
1493.5
91.4
104
10.43
1492.8
63.1
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
33.016 6.14 0.46 0.222 24.79
33.013 6.30 0.47 0.191 24.61
33.047 6.37 0.49 0.240 24.86
33.117 6.34 0.50 C.370 24.94
33.35C 6.10 0.68 C.532 25.27
33.541 4.88 1.24 0.252 25.62
33.649 3.85 1.67 0.122 25.83
0
13.45
1500.3
77.3
10
33.32
1500.2
76.8
20
13.23
1500.1
77.4
30
13.09
1499.9
78.2
50
12.31
1497.9
78.3
75
11.21
1494.8
86.8
ICO
10.50
1492.9
69.1
242
STATION: B9 DEPTH: 622M DATE: 5 NOV 70 TIME: 1117
LAT: 36-44. 2N LONG: 122-59. 2W WIND: 230 SPEED: 12
AIR TEMP(DRY): 56 BARO: 30.08 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 200-2 SWELL: 180-3
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALU-ES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
10
25
50
75
100
32.981
32.982
32.985
33.259
33.484
33.603
4.71
4.60
6.32
7.34
4.93
4.20
C.48
0.45
0.45
0.59
1.30
1.56
0.187
0.191
0.241
0.228
0.136
0.169
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M>
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
c
8
28
48
57
77
96
1 3,33
13.31
13.26
13.16
11.48
10.90
10.75
1 500. C
15CC.1
1500.3
15CC.5
1495.3
1493.8
1493.7
78
78
79
82
88
87
89.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.33
1500.0
78.0
10
13.30
1500.1
78.4
20
13.28
1500.2
79.0
30
13.25
1500.3
79.8
50
12.79
1499.3
84.3
75
10.96
1493.9
88.6
100
32.981 4.71 0.48 0.187 24.79
32.982 4.60 0.45 0.191 24.79
32.984 5.75 0.45 0.224 24.80
33.04C 6.53 0.48 0.238 24.85
33.259 7.34 0.59 C.228 25.11
33.484 4.93 1.30 0.136 25.62
33.6C3 4.20 1.56 C. 169
243
STATION: BIO DEPTH: 247M DATE: 5 NOV 70 TIME: 10C0
LAT: 36-42. 8N LONG: 122-59. Ik WIND: 180 SPEED: 22
AIR TEMP(DRY): 57 BARO: 30. C5 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 180-3 SWELL: 180-3
DEPTH
(Ml
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(NG-ATM/L)
CHLCROPHY.L
(MG/M3 )
0
15
40
55
70
100
32.968
32.973
33.009
33.282
33.202
33.659
6.24
6.51
6.31
6.42
5.42
4.06
0.45
C.45
0.46
0.58
0.86
1.64
0.169
0.107
0.187
0.194
0.179
0.135
OBSERVED VALUES ( SV/T/D- T RANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
9
14
20
3 9
57
76
99
13.30
13.29
13.29
13.29
13.30
12.90
10.95
10.57
1499.9
1500.0
1500.2
150C.2
15CC.7
1499.8
1494.0
1494.9
77.4
77.4
77.4
77.4
79.2
82.5
85.5
77.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.30
1499.9
77.4
10
13.29
1500.0
77.4
20
13.29
1500.2
77.4
30
13.30
1500.5
78.3
50
13.06
1500.1
81.2
75
11.05
1494.3
85.3
100
32.968 6.24 0.45 0.169 24.78
32.971 6.42 0.45 C.128 24.79
32.980 6.47 0.45 0.123 24.79
32.995 6.39 0.46 0.155 24.80
33.191 6.39 0.54 C.192 25.00
33.278 5.19 0.99 0.172 25.45
33.659 4.C6 1.64 0.135
244
STATION: Bll DEPTH: 109M DATE: 5 NOV 70 TIME: 0855
LAT: 36-41. 3N LONG: 122-59. 1W WIND: 190 SPEED: 20
AIR TEMP(DRY): 58 BARO: 30. CO CLGUD AMT: 10
HEIGHT(FT): 1000 SEA: 190-3 SWELL: 180-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.980
6.22
0.44
0.154
25
32.972
6.23
0.44
0.2C9
60
33.229
0.64
0.225
75
33.330
5.71
0.92
0.228
95
33.543
5.14
1.28
0.355
108
33.701
3.7C
2.15
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.43
15CC.3
79.6
20
13.42
15C0.7
79.5
50
13.33
15CC.9
81.3
59
12.86
1498.8
84.9
74
11.71
1496.0
87.7
99
11.12
1494.9
84.0
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.43
1500.3
79.6
10
13.42
1500.5
79.5
20
13.42
1500.7
79.5
30
13.39
1500.8
80.1
50
13.33
150C.9
81.3
75
11.69
1496. C
87.6
100
32.980 6.22 0.44 0.154 24.76
32.977 6.23 0.44 0.176 24.76
32.974 6.23 0.44 C.198 24.76
33.C09 5.34 0.47 C.211 24.80
33.156 1.78 0.58 C.220 24.92
33.33C 5.71 0.92 0.228 25.37
33.604 4.59 1.61 0.218
245
STATION: B12 DEPTH: 99M DATE: 5 NOV 70 TIME: 0750
LAT: 36-39. 8N LONG: 122-59. 2W WIND: 190 SPEED: 20
AIR TEMP(DRY): 58 BARO: 30.00 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 190-3 SWELL: 18C-5
. OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.971
6.22
0.43
0.197
20
32.982
5.78
0.43
0. 169
45
33.105
4.18
0.54
0.175
60
33.414
2.27
0.96
0.332
80
33.499
4.55
1. 11
0.446
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0 •
13.46
150C.5
77.9
2 I
I 3 - 4 5
15CC.8
78.5
46
13.13
1500.4
83.2
55
12.52
1498.6
80.8
70
12.05
1497.5
79.4
88
11.50
1496.1
82.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-1
0
13.46
1500.5
77.9
10
13.46
1500.6
78.2
20
13.45
1500.8
78.5
30
13.33
1500.7
8C.2
50
12.86
1499.6
82.1
75
11.90
1497. 1
80.2
32.971 6.22 0.43 0.197 24.75
32.977 6.00 0.43 0.183 24.76
32.962 5.78 0.43 0.169 24.76
33.032 5.14 0.47 0.171 24.82
33.208 3.54 0.68 0.227 25.05
33.478 3.98 1.07 0.417 25.45
246
STATION: B13 DEPTH: 82M DATE: 5 NOV 70 TIME: 0655
LAT: 36-38. 8N LONG: 121-58. 7W WIND: 160 SPEED: 30
AIR TEMP(DRY): 50 BARO: 29.95 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-5 SWELL: 170-12
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLORCPHYLL
(MG/M3)
0
20
50
60
81
32.961
32.961
33.163
33.382
33.533
6.23
6.37
6.16
5.81
5.35
0.49
0.51
0.64
0.89
0.167
0.199
0.160
0.358
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
9
18
27
35
44
53
63
67
13.36
13.35
13.32
13.34
13.30
13.18
12.57
12.23
11.82
150C.2
150C.3
1500.4
1500.6
15CC.7
150C.4
149 8.7
1497.9
1496.8
81.3
81.6
80.8
80.2
80.2
81.9
78.8
80.0
77.8
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.36
1500.2
81.3
10
13.35
1500.3
81.5
20
13.32
1500.4
80.7
30
13.32
1500.6
8C.2
50
12.77
1499.3
79.8
75
32.961 6.23 0.49 0.167 24.76
32.961 6.30 0.50 0.183 24.77
32.961 6.37 0.51 0.199 24.77
33.C29 6.30 0.55 0.186 24.82
33.163 6.16 0.64 C.160 25.04
33.490 5.48 0.25 0.102
247
STATION: CI DEPTH: 444M DATE: 5 NOV 70 TIME: 0545
LAT: 36-36. 2N LONG: 122-01. 7W WIND: 160 SPEED: 30
AIR TEMP(DRY): 50 BARO: 29.95 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-5 SWELL: 170-12
t
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY OXYGEN
(0/00) (ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.965
6.
,26
0,
,44
0.149
20
32.965
6,
,29
0,
.48
0.275
50
33.367
6.
,10
C,
.79
0.459
70
33.490
5.
,91
1.
,00
0.839
80
33.494
5.
,85
1,
.02
0.725
100
33.602
4,
,65
1,
,31
0.443
OBSERVED VALUES
(SV/T/D-TRANSMISSOMETER
CAST)
DEPTH TEMP
(M) (C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(C/0)
0 13.30
1499.9
82. C
13 13.30
15C0.2
82.1
23 13.30
1500.4
82.1
38 12.99
1499.8
80.7
46 12.73
1499.3
77.5
69 11.95
1497.1
71.2
93 10.65
1492.7
79.3
102 9.97
1491.1
85.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.30
1499.9
82.0
10
13.30
1500.1
82.1
20
13.30
1500.3
82.1
30
13.16
1500.1
81.4
50
12.59
1498.9
76.4
75
11.62
1496.0
73.2
100
10.12
1491. 5
84.2
32.965 6.26 0.44 0.149 24.78
32.965 6.29 0.48 0.275 24.78
32.965 6.29 0.48 0.275 24.78
33.367 6.10 0.79 C.459 25.12
33.367 6.10 0.79 C.459 25.23
33.4<;2 5.88 1.01 0.782 25.51
33.602 4.65 1.31 0.443 25.86
248
STATION: CI DEPTH: 444M DATE: 5 NOV 70 TIME: 0545
LAT: 36-36. 2N LONG: 122-01. 7W WIND: 160 SPEED: 30
AIR TEMP(DRY): 50 BARO: 29.95 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-5 SWELL: 170-12
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.965
6.26
0.44
0.149
20
32.965
6.29
0.48
0.275
50
33.367
6.10
C.79
0.459
70
33.490
5.91
1.00
0.839
80
33.494
5.85
1.02
0.725
100
33.602
4.65
1.31
0.443
OBSERVED VALUES ( SV/T/D-T RANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SG. VEL
(M/SEC)
TRANSMITTANCE
(C/0)
0
1 ^.30
1499.9
82. C
13
13.30
15C0.2
82.1
23
13.30
1500.4
82.1
38
12.99
1499.8
80.7
46
12.73
1499.3
77.5
69
11.95
1497.1
71.2
93
10.65
1492.7
79.3
102
9.97
1491.1
85.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.30
1499.9
82.0
10
13.30
1500.1
82.1
20
13.30
1500.3
82.1
30
13.16
1500.1
81.4
50
12.59
1498.9
76.4
75
11.62
1496.0
73.2
100
10.12
1491.5
84.2
32.965 6.26 0.44 0.149 24.78
32.965 6.29 0.48 0.275 24.78
32.965 6.29 0.48 0.275 24.78
33.367 6.10 0.79 C.459 25.12
33.367 6.10 0.79 C.459 25.23
33.4S2 5.88 1.01 0.782 25.51
33.602 4.65 1.31 0.443 25.86
248
STATION: C2 DEPTH: 823M DATE: 5 NOV 70 TIME: 0437
LAT: 36-34. IN LONG: 122-04. 1W WIND: 160 SPEED: 35
AIR TEMP(DRY): 50 BARO: 29.90 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-6 SWELL: 170-12
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY OXYGEN
(0/00) (ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.927
4,
,65
0,
,42
0.227
20
32.936
4,
,67
0,
,42
0.245
50
32.961
4,
,70
0,
.43
0.2C0
65
33.280
5,
,93
0.
.71
0.296
80
33.578
3.
,70
1,
.42
0.267
100
33.604
2,
.95
1.
.57
0.106
OBSERVED VALUES
(SV/T/D-7RANSMISS0METER
CAST)
DEPTH TEMP
( M ) ( C )
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0 13-44
15CG.4
77.7
4 13.45
150C.5
78.8
14 13.43
15C0.6
78.4
23 13.44
15 CO. 8
78.4
37 13.41
15C1.0
77.9
54 13.19
1 5 0 C . 7
81.8
64 12.17
1493.7
80.5
79 10.84
1493.7
83.1
94 9.85
1490.2
89.0
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
32.927 4.65 0.42 0.227 24.72
32.936 4.67 0.42 0.245 24.73
32.936 4.67 0.42 0.245 24.73
32.961 4.70 0.43 0.200 24.75
32.961 4.70 0.43 0.200 24.79
33.478 4.44 1.19 0.277 25.58
33.604 2.95 1.57 0.106
0
13.44
1500.4
77.7
10
13.44
1500.6
78.6
20
13.44
1500.7
78.4
30
13.42
1500.9
78.1
50
13.24
1500.8
80.9
75
11.19
1493.7
82.4
100
249
STATION: C3 DEPTH: 1280M DATE: 5 NOV 70 TIME: 0305
LAT: 36-31. 5N LONG: 122-07. 4W WIND: 160 SPEED: 35
AIR TEMP(DRY): 50 BARO: 29.90 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-6 SWELL: 170-12
. OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.831
3.95
0.41
0.1C7
10
32.864
4.94
0.41
0.175
25
32.872
5.20
0.41
0.156
40
33.315
4.80
0.68
0.195
60
33.403
4.18
0.98
0.189
70
33.155
4.22
•
1.01
0.C71
90
33.477
4.03
1.43
0.031
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.56
1500.7
78.8
9
13.55
15CC.9
79.2
28
13.49
1501.0
79.9
38
13.27
150C.2
80.6
58
11.66
1496.0
88.8
67
9.47
1487. S
91.4
85
9.37
1486.3
91.7
96
8.69
1486.2
92.4
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.56
1500.7
78.8
10
13.55
1500.9
79.2
20
13.52
1501. C
79.6
30
13.45
1500.8
80.0
50
12.30
1497.7
85.5
75
9.43
1488. 1
91.5
32.831 3.95 0.41 0.107 24.62
32.864 4.94 0.41 0.175 24.65
32.86<5 5.11 0.41 C.162 24.66
33.C2C 5.07 0.50 0.169 24.79
33.359 4.49 0.83 0.192 25.28
33.236 4.18 1.12 0.C61 25.69
250
STATION: Dl DEPTH: 1737M DATE: 5 NGV 7C TIME: OlOO
LATr. 36-35. 5N LONG: 122-10. 8W WIND: 160 SPEED: 35
AIR TENP(DRY): 55 BARC: 29.95 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-6 SWELL: 170-1C
OBSERVED VALUES (KANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHCSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.920
5.92
0.47
0.193
10
32.916
5.42
0.48
0.157
25
32.909
5.33
0.50
0.142
40
33.126
5.26
0.52
0.151
60
33.372
4.95
0.68
0.215
70
33.431
A. 35
0.99
0.154
90
33.415
4.08
0.C29
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.16
1499.4
78.5
10
13.15
1499.5
79.0
19
13. 04
1499.4
79.9
27
13.03
1499.5
81. 1
37
13.23
15C1.4
85.2
57
12.23
1497.8
89.2
77
10.26
1491.5
90.3
96
9.37
1488.7
91.2
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13. 16
1499.4
78.5
10
13.15
1499.5
79.0
20
13.04
1499.4
8C.0
30
13.09
1500.1
82.3
50
12.58
1499.1
87.8
75
10.46
1492. 1
90.2
32.920 5.92 0.47 0.193 24.77
32.916 5.42 0.48 0.157 24.77
32.911 5.36 0.49 0.147 24.79
32.981 5.31 0.51 C.145 24.83
33.249 5.11 0.60 0.183 25.14
33.427 4.28 0.74 0.123 25.67
251
STATION: D2 DEPTH: 1370M DATE: 4 NOV 70 TIME: 2300
LAT: 36-39. 2N LONG: 122-14. 6W WIND: 160 SPEED: 30
AIR TEMP(DRY): 53 BARO: 29.97 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-4 SWELL: 170-9
OBSERVED VALUES (NANSEN CAST)
DEPTH
(MJ
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.230
6.38
0.55
0.177
10
33.231
6.51
0.53
0.122
30
33.231
6.45
0.52
0.249
40
33.224
3.58
0.55
0.175
55
33.170
6.24
0.57
0.089
70
33.109
5.84
0.79
0.088
90
33.483
4.72
1.37
0.215
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO., VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.50
1501.0
76.8
1C
13.45
1 5 C C . 9
77.6
20
13.41
1 5 C 1 . C
78.1
28
13.27
1500.6
78. 1
39
13.03
1499.9
80. A
58
10.60
1491.5
88.7
76
10.42
1492.0
90.0
89
9. 41
1488.5
91.9
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
13.50
1501.0
76.8
10
13.45
1500.9
77.6
20
13.41
1501.0
78.1
30
13.23
1500.5
78.5
50
11.62
1495. C
85.2
75
10.43
1492. C
89.9
33.230 6.38 0.55 0.177 24.94
33.231 6.51 0.53 0.122 24.95
33.231 6.45 0.52 0.249 24.96
33.231 6.45 0.52 0.249 25.00
33.188 5.36 0.56 C.118 25.27
33.2C3 5.56 0.94 0.120 25.50
252
STATION: 03 DEPTH: 1262M DATE: 4 NOV 70 TIME: 2100
LAT: 36-43. ON LONG: 122-18. 5W WIND: 210 SPEED: 25
AIR TEMP(DRY): 55 BARO: 29.93 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 200-7 SWELL: 190-9
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (KANSEN CAST)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
15
30
40
60
32.243
32.243
33.251
33.341
33.397
6.41
6.16
6.42
5.70
4.99
0.52
0.46
0.52
0.93
1.24
0.142
0.171
0.167
0.179
0.059
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
o
18
27
46
64
76
82
13.77
12.77
13.74
13.68
11.53
10.02
9.74
9.71
1501.8
15C2.1
15C2.1
1502.1
1495.4
1490.4
149C.0
1489.7
77
77
77
77
85
89
90.0
90.0
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.77 1501.8
10 13.77 1502.1
20 13.73 1502.1
30 13.34 1501.0
50 11.19 1494.3
77.2 33.243 6.41 0.52 0.142 24.90
77.2 33.243 6.25 0.48 C.161 24.90
77.3 33.251 6.42 0.52 0.167 24.91
78.8 33.251 6.42 0.52 0.167 24.99
86.5 33.369 5.34 1.08 0.119 25.49
253
STATION: El DEPTH: 841M DATE: 4 NOV 70 TIME: 1853
LAT: 36-47. 4N LONG: 122-14. 5b WIND: 170 SPEED: 25
AIR TEMP(DRY): 55 BARO: 29.93 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 170-7 SWELL: 17C-1C
DEPTH
(M)
SALINITY
(0/00)
OBSERVED VALUES (NANSEN CAST)
OXYGEN
(ML/L)
PhQSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
30
50
70
80
33.084
33.085
33.116
33.058
33.278
6.18
6.27
6.21
4.50
4.42
0.48
0.48
C.50
0.69
1.16
0.160
0.134
0.177
0el56
0.058
OBSERVED VALUES ( SV/T/D-T RANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
9
26
44
59
66
77
13.07
13.06
13.11
11.83
11.41
10.30
9.97
1499.4
149Q r <s
15CC.C
1495.9
1495.1
1491. C
1490.3
77.8
78.8
78.1
85.3
88.5
90.7
90.7
INTERPOLATED VALUES
DEPTH TEMP' SO. VEL TRANS. SAL. GXY PHOS CHLOR SIG-T
0
13.07
1499.4
77.8
10
13.06
1499.5
78.8
20
13.09
1499.8
78.3
30
12.83
1499. 1
79.7
50
11.66
1495.6
86.6
75
10. C3
1490.4
9C.7
33.084 6.18 0.48 0.160 24.92
33.084 6.21 0.48 0.151 24.92
33.C65 6.24 0.48 0.143 24.91
33.C85 6.27 0.48 0.134 24.97
33.116 6.21 0.50 0.177 25.21
33.168 4.46 0.92 0.107 25.54
254
STATION: E2 DEPTH: 192M DATE: 4 NOV 70 TIME: 1000
LAT: 36-50. 7N LONG: 122-10. 6W WIND: 170 SPEED: 25
AIR TEMP(DRY): 54 BARO: 29.98 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 170-2 SWELL: 180-5
OBSERVED VALUES (KANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.049
6.29
0.46
0.163
5
33.061
6.45
0.43
0. 178
10
33.061
6.27
0.43
0.135
20
33.068
6.37
0.45
0.162
30
33.256
6.24
0.62
0.221
50
33.348
5.60
1.06
0.137
75
33.629
3.82
1.68
0.047
100
33.777
3.55
1.84
0.044
OBSERVED VALUES ( S V/T/D-TRANSMI S SOMET ER CAST)
EPTH
(M)
T CM D
icT
cnt \/ci
(m/secT
TRAN^MITTAMf.F
(0/0)
0
13.38
15C0.3
79.7
4
13.37
15CC.3
79.2
9
13.38
1500.4
78.5
19
13.31
1 5 C C • C
79.8
30
12.91
1499.5
83.2
49
11.04
1493.6
91.5
74
10.10
1490. 8
93.7
98
9.21
1488.3
94. 1
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.38
1500.3
79.7
10
13.37
1500.4
78.6
20
13.27
1500. C
80.1
30
12.91
14 99.5
83.2
50
11 .CO
1493.5
91.6
75
10.06
1490.7
93.7
100
33.C49 6.29 0.46 0.163 24.83
33.061 6.27 0c43 0.135 24.84
33.068 6.37 0.45 0.162 24.86
33.256 6.24 0.62 0.221 25.08
33.348 5.60 1.06 0.137 25.51
33.629 3.82 1.68 0.C47 25.89
33.777 3.55 1.84 0.044
255
STATION: E3 DEPTH: 109M DATE: 4 NOV 70 TIME: 1055
LAT: 36-51. 9N LONG: 122-09. oh WIND: 170 SPEED: 25
AIR TEMP(DRY): 54 8ARO: 29.98 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 170-2 SWELL: 180-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(Ml
SALINITY
(0/00)
0
33.014
10
33.014
20
33.096
50
33.380
70
33.567
OXYGEN
(ML/L)
5.69
6.12
5.11
5.10
4.05
PHOSPHATE
(MG-ATM/L)
0.46
0.46
0.51
1.04
1.47
CHLOROPHYLL
(MG/M3)
0.180
0.226
0.215
0.182
0.091
OBSERVED VALUES ( SV/T/D- TRANSMI S SCMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0 •
13.21
1499.6
77.2
in
1 3. ?l
u;9^
77. 3
19
13.12
1499.7
77.2
39
12.27
14 97.5
86.8
49
11.19
1493.8
89.3
68
9.88
1490.5
90.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0 13.21 1499.6
10 13.21 1499.9
20 13.08 1499.6
30 12.65 1498.5
50 11.12 1493.6
77.2 33.014 5.69 0.46 0.180 24.83
77.3 33.014 6.12 0.46 0.226 24.83
77.7 33.096 5.11 0.51 0.215 24.92
82.5 33.190 5.11 0.69 0.204 25.08
89.3 33.3EC 5.10 1.04 0.182 25.51
256
STATION: E4 DEPTH: 89M DATE: 4 NOV 70 TIME: 1155
LAT: 36-53. 2N LONG: 122-08. 5W WIND: 170 SPEED: 12
AIR TEMP(DRY): 55 BARO: 29.98 CLOUD AMT: 10
HEIGHT(FT): 100C SEA: 170-2 SWELL: 170-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.073
6.30
0.45
0.223
5
33.053
6.36
0.47
0.278
10
32.053
6.16
0.4 8
0.274
20
33.115
6.29
0.50
0.276
30
33.371
6.23
0.7 8
0.379
50
33.506
4.83
1.35
0o312
75
33.680
3.45
1.87
0.132
86
33.706
3.34
OBSERVED VALUES ( SV/T/D-T RANSMI SSOMETE R CAST)
n c p t u
"(Mi"
TCMD
(cV
en \/pi
(M/SEC)
TR AN9M JTTANCF
(0/0)
0
13.28
1499.9
74.2
5
13.26
1500.0
74.5
10
13.26
1 5 C C . C
74.1
19
13.16
1520.0
74.9
28
12.53
1498.2
77.8
48
11.49
1495.2
75.0
57
10.72
1492.8
86.5
73.
10.08
149C.4
82.1
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-1
0
13.28
1499.9
74.2
10
13.26
1500.0
74.1
20
13.09
1499.8
75.2
30
12.43
1497.9
77.5
50
11.32
14 94. 7
77.6
75
33.073 6.30 0.45 0.223 24.87
33.053 6.16 0.48 0.274 24.85
33.115 6.29 0.50 0.276 24.94
33.371 6.23 0.78 0.379 25.26
33.5C6 4.83 1.35 0.312 25.58
33.68C 3.45 1.87 C.132
257
STATION: E5 DEPTH: 65M DATE: 4 NOV 70 TIKE: 1245
LAT: 36-54. 2N LONG: 122-06. E-W WIND: 170 SPEED: 12
AIR TEMP(DRY): 55 BARO: 29.98 CLOUC AMT: 10
HEIGHT(FT): 1000 SEA: 170-2 SWELL: 170-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(MJ
SALINITY
tO/00)
0
33.069
10
33.107
25
33.372
45
33.534
55
33.572
63
33.610
OXYGEN
(ML/L)
PHGSPHATE
(MG-ATM/L)
6.24
0.48
6.46
0.50
6.24
0.70
4.57
1.48
4.15
1.66
3.89
CHLOROPHYLL
(MG/M3)
0.3C5
0.357
0.717
0.510
0.349
OBSERVED VALUES { SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC, VEL
(M/SEC)
TRANSMITTANCE
(C/0)
0
13,30
1500.0
7 6. 6
10
13.24
150C.C
75.9
29
12.33
1497.7
63.3
39
11.66
1495.7
29.8
49
11.20
1494.3
32.2
53
10.94
1493.4
40.3
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
13.30
1500.0
76.6
10
13.24
15C0.C
75.9
20
12.76
1498.8
69.3
30
limit
1497.5
59.9
50
11.13
1494.1
34.2
33.069 6.24 0.48 0.305 24.86
33.1C7 6.46 0.50 0.357 24.90
33.264 6.31 0.64 0.597 25.13
33.412 5.82 0.90 0.665 25.33
33.553 4.36 1.57 0.429 25.65
258
STATION: E6 DEPTH: 45M DATE: 4 NOV 70 TIME: 1330
LAT: 36-55. 5N LONG: 122-05. 9W WIND: 170 SPEED: 12
AIR TEMP(DRY): 56 BARO: 29.95 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 170-2 SWELL: 17G-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(Ml
SALINITY
(0/00)
0
33.106
15
33.144
25
33.347
35
33.471
43
OXYGEN
(ML/L)
6.34
6.46
6.27
5.44
4.7C
PHOSPHATE
(MG-ATM/L)
0.52
0.52
0.73
1. 15
CHLOROPHYLL
(MG/M3)
0.281
0.361
0.658
0.451
OBSERVED VALUES ( SV/T/D-TRAN SMI SSOMETE R CAST)
DEPTH
( M )
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
1^
27
32
36
13.23
1 2 : 79
12.11
12.05
11.54
1499.9
1498.9
1496.9
1496.9
1495.3
76.2
68.7
34.7
41.4
35.5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.23 1499.9
10 12.92 1499.2
20 12.48 1498.0
30 12.07 1496.9
76.2 33.1C6 6.34 0.52 C.281 24.90
70. 8 33.131 6.42 0.52 0.334 24.98
53.0 33.246 6.37 0.62 0.509 25.16
38.7 33.4C9 5.86 0.94 0.554 25.36
259
STATION: E7 DEPTH: 35M DATE: 4 NOV 70 TIME: 1355
LAT: 36-56. 4N LONG: 122-05. OW WIND: 170 SPEED: 12
AIR TEMP(DRY): 56 BARC: 29.95 CLOUD AMT: 10
HEIGHT(FT): 100C SEA: 170-2 SWELL: 170-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(Ml
SALINITY
(0/00)
0
33.121
5
33.121
12
33.144
25
33.425
33
33.472
OXYGEN
(ML/L)
6.37
6. 08
5.50
5.16
4.97
PHOSPHATE
(MG-ATM/L)
0.55
0.53
0.58
1.02
CHLOROPHYLL
(MG/M3)
0.510
0.782
0.5C8
0.479
OBSERVED VALUES ( SV/T/D-TRANSMI SSQMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.13
149 9.6
74.3
4
13.08
14 9 9.6
73.7
13
12.98
1499.4
70.2
23
12.41
14 9 8.0
38.3
27
12.02
1496.8
28.5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.13 1499.6
10 13.01 1499.5
20 12.58 1498.4
30
74.3 33.121 6.37 0.55 0.510 24.93
71.4 33.137 5.67 0.57 0.586 24.97
47.9 33.316 5.29 0.86 0.490 25.19
33.454 5.04 0.36 C.180
260
STATION: Fl DEPTH: 49M DATE: 4 NOV 70 TIME: C839
LAT: 36-57. 8N LONG: 122-10. lb WIND: 180 SPEED: 15
AIR TEMP(DRY): 54 BARO: 29.96 CLOUD AMT: 10
HEIGHT(FT): 700 SEA: 165-2 SWELL: 180-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.216
10
33.220
20
33.276
25
33.430
35
33.528
47
OXYGEN
(ML/L)
4.30
5.98
5.83
5.35
4.67
3.90
PHOSPHATE
(NG-ATM/L)
0.54
0.54
0.55
0.74
1.31
1.76
CHLOROPHYLL
(MG/M3)
0.343
0.442
0.679
0.381
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
C
12.97
1499. i
75,9
6
12.96
1499.2
76.1
11
12.95
1499.2
76.1
15
12.93
1499.2
75.6
20
12.72
1 4 <; 8 . 7
70.9
25
12.12
1496.9
63.9
29
11.71
1495.5
48.5
39
11.30
14 94.5
37.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.97 1499.1
10 12.95 1499.2
20 12.72 149 8.7
30 11.67 1495.4
75.9 33.216 4.30 0.54 0.343 25.04
76.1 33.22C 5.98 0.54 0.442 25.05
7C.9 33.276 5.83 0.55 0.679 25.13
47.4 33.479 5.01 1.03 25.49
261
STATION: F2 DEPTH: 36M DATE: 4 NOV 70 TIME: 0725
LAT: 37-01. ON LONG: 122-14. 8W WIND: 180 SPEEC: 15
AIR TEMP(DRY): 54 BARO: 29.96 CLOUD AMT: 10
HEIGHT(FT): 700 SEA: 165-2 SWELL: 180-5
OBSERVED VALUcS (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.322
5
3 3.324
15
33.367
25
33.522
OXYGEN
(ML/L)
6.36
6.50
6.60
5.19
PHOSPHATE
(MG-ATM/L)
0.59
0.59
0.63
1.27
CHLCPOPHYLL
(MG/M3)
0.477
0.615
G.990
0.533
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
:epth
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0 •
12.78
1496.6
75.1
5
1 2 . 77
1^96-7
71 .?
9
12.66
1498.5
71.2
14
12.33
1497.4
60. C
19
11.83
1497.4
46.6
24
11.61
1496.1
41.6
30
11.21
1495.3
32.5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR S IG-T
0 12.78 1498.6
10 12.59 1498.3
20 11.79 1497.1
30 11.21 1495.3
75.1 33.322 6.36 0.59 0.477 25.16
69.0 33.34fc 6.55 0.61 0.802 25.21
45.6 33.445 5.89 0.95 0.761 25.44
32.5 14.849 2.31 0.55 C.237 11.17
262
STATION: F3 DEPTH: 63M DATE: 4 NOV 70 TINE: C630
LAT: 37-043N LONG: 122-17. 5W WIND: 165 SPEED: 10
AIR TEMP(DRY): 55 BARO: 29.92 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 165-1 SWELL: 180-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLCROPHY..L
(MG/M3)
0
33.360
6.42
0.59
0.455
5
33.357
6.39
0.58
0.445
12
33.360
6.46
0.59
0.549
22
33.361
6.38
0.62
0.5C3
27
33.389
6.31
0.73
0.665
34
33.399
5.84
0.94
OBSERVED VALUES ( SV/T/D-7RANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
1^- 31
lA'JR-6
80.6
4
12.70
14 9 8.7
80.8
10
12.60
1498.4
79.3
15
12.36
1497.7
68.8
19
12.27
14 9 7.6
66. C
24
12.27
1497.6
63.3
29
12.27
1497.7
49.5
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. CXY PHOS CHLOR S1G-T
0 13.31 1498.6
10 12.60 1498.4
20 12.27 1497.6
30
80.6 33.360 6.42 0.59 0.455 25.06
79.3 33.359 6.44 0.58 0.519 25.22
65.5 33.361 6.40 C.62 0.512 25.29
33.393 6.11 0.82 0.380
26 3
STATION: Gl DEPTH: 56M DATF: 4 NOV 70 TIKE: 053G
LAT: 37-C3.0N LONG: 122-19. Ok WIND: 165 SPEEC: 10
AIR TEMP(DRY): 55 BARO: 29.92 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 165-1 SWELL: 180-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.365
6.35
0.56
0.362
5
33.365
6.40
0.57
0.329
10
33.367
6.30
0.98
0.3C0
20
33.469
5.68
1.25
1.069
30
33.525
4.97
1.45
0.691
40
33.547
4.94
1.38
0.546
54
33.596
4.22
OBSERVED VALUES ( SV/T/D-T RANSMI SSOMETER CAST)
DEPTH
(Ml
TEMP
(C)
SOc VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.03
1498.6
82.0
4
12.78
1498.6
81.5
10
12.78
1498.7
81.6
18
12.30
1497.5
74.6
28
11.52
1494.9
56.8
37
11.27
1494.3
58.9
11.21
1494.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0 13.03 1498.6
10 12.78 1498.7
20 12.14 1497.0
30 11.46 1494.8
50
82.0 33.365 6.35 0.56 C.362 25.14
81.6 33.367 6.30 0.98 0.300 25.19
71.0 33.469 5.68 1.25 1.C69 25.39
57.3 33.525 4.97 1.45 0.691 25.56
33.562 4.43
264
STATION: G2 DEPTH: 75M DATE: 4 NOV 70 TIME: 0425
LAT: 37-02. 2N LONG: 122-20. 5W WIND: 180 SPEED: 6
AIR TEMP(DRY): 54 BARO: 29.87 CLOUD AMT: 0
HEIGHT(FT): CLEAR SEA: 180-1 SWELL: 180-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(NG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.345
6.34
0.56
0.320
5
33.345
6.34
0.57
0.4 27
10
33.346
6.37
0.58
0.385
20
33.373
6.33
0.63
0.357
40
33.580
4.36
1.64
0.278
60
33.629
4.03
1.79
0.294
73
33.637
3.93
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH-
(MJ
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
73.8
73.8
74.0
80.1
88.5
37.0
33.0
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
10
20
30
50
73.8 33.345 6.34 0.56 C.320
33.346 6.37 0.58 0.385
33.373 6.33 0.63 0.357
33.476 5.34 1.14 0.317
33.604 4.19 1.72 0.286
265
STATION: G3 DEPTH: 97M DATE: 4 NOV 70 TIME: 0305
LAT: 37-01. 5N LONG: 122-21. 7W WIND: 180 SPEED: 6
AIR TEMP(DRY): 54 BARO: 29.87 CLOUD AMT: 0
HEIGHT(FT): CLEAR SEA: 180-1 SWELL: 180-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.353
6.36
0.59
0.392
5
33.356
6.47
0.60
0.364
20
33.421
6.15
0.78
0.347
40
33.508
5.06
1.21
0.576
50
33.520
4.90
1.28
0.391
65
33.653
4. 10
1.59
0.207
75
33.725
3.38
0.215
95
33.729
3.52
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M>
T F M P
(C)
sn. vfi
(M/SEC)
TRANSMITTANCE
(0/0)
62.0
72.1
78.6
81.6
86.1
88.2
48.0
46.9
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
62.0 33.353 6.36 0.59 0.392
33.377 6.36 0.66 C.358
33.421 6.15 0.78 0.347
33.464 5.61 1.00 0.461
33.52C 4.90 1.28 0.391
33.725 3.38 0.215
266
STATION: G4 DEPTH: 155M DATE: 4 NOV 70 TIME: 0200
LAT: 37-00. 5N LONG: 122-23. 1W WIND: 180 SPEED: 6
AIR TEMP(DRY): 54 BARO: 29.88 CLOUD AMT: 3
HEIGHT(FT): 150C SEA: 180-1 SWELL: 18C-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLCROPHYLL
(MG/M3)
0
33.355
6.32
0.63
0.404
10
33.353
6.34
0.69
0.456
30
33.396
5.73
1.04
0.435
40
33.448
5.54
1.06
0.414
60
33.7C0
3.37
1.67
0.727
80
33.770
3.46
1.81
0.097
100
33.806
3.22
1.89
0.076
153
33.827
3.16
OBSERVED VALUES ( S V/T/D-T RANSMI SSOMETER CAST)
HEPTH
(M)
TCMP
(C)
(M/SEC)
TR ANSM r TTANf.F
(0/0)
74.3
74.8
82.7
86.1
91.6
89.4
80.7
74.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
100
150
74.3 33.355 6.32 0.63 0.404
33.353 6.34 0.69 C.456
33.374 6.04 0.87 0.445
33.396 5.73 1.04 C.435
33.574 4.7C 1.37 0.57C
33.752 3.57 1.77 0.254
33..1C6 3.22 1.89 0.076
33.825 3.16 O.C04
267
STATION: G5 DEPTH: 155M DATE: 4 NOV 70 TIME: C045
LAT: 36-59. 5N LONG: 122-24. 5W WIND: 160 SPEED: 30
AIR TEMP(DRY): 51 BARO: 29,87 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 160-8 SWELL: CCNFUSED-10
OBSERVED VALUES (NANSEN CAST)
DEPTH
(MJ
SALINITY
(0/00)
0
33.411
10
33.407
20
33.487
35
33.524
55
33.638
75
33.863
95
33.862
OXYGEN
(ML/L)
6.40
6.31
5.92
4.95
4.05
3.07
2.99
PHOSPHATE
(MG-ATM/L)
0.67
0.66
C.92
1.28
1.59
1.92
1.96
CHLOROPHYLL
(MG/M3)
0.267
0.374
0.377
0.221
0.0 64
0.077
0.094
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETE R CAST)
DEPTH-
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
72.4
72.2
74.2
82.2
88.8
90.0
83.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
72.4 33.411 6.40 0.67 0.287
33.4C7 6.31 0.66 0.374
33.487 5.92 0.92 0.377
33.512 5.27 1.16 C.273
33.61C 4.27 1.51 C.103
33.863 3.07 1.92 0.077
268
STATION: G6 DEPTH: 733M DATE: 3 NOV 70 TIKE: 2312
LAT: 36-56. 3N LONG: 122-32. 8h WIND: 150 SPEED: 30
AIR TEMP(DRY): 51 BARO: 29.33 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 150-8 SWELL: CCNFUSED-12
OBSERVED VALUES (NAMSEN CAST)
DEPTH
(Ml
SALINITY
(0/00)
OXYGEN
(ML/LI
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.457
6.31
0.69
0.496
10
33.454
6.42
0.71
0.559
20
33.484
5.94
0.85
0.542
35
33.317
5.13
1. 16
0.137
55
33.571
4.34
1.48
0.172
75
33.529
4.71
1.42
0.114
95
33.688
4.38
1.57
0.041
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(Ml
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
72.7
73.0
82.5
89.0
88.7
90.2
90.6
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. CXY PHCS CHLOR SIG-T
0
10
20
30
50
75
72.7 33.457 6.31 0.69 C.496
33.454 6.42 0.71 0.559
33.4C4 5.94 0.85 0.542
33.373 5.4C 1.06 C.272
33.5C7 4.54 1.40 C.163
33.529 4.71 1.42 C.114
269
STATION: G7 DEPTH: 1370M DATE: 3 NOV 70 TIKE: 2204
LAT: 36-53. 3N LONG: 122-32. 8h WIND: 150 SPEED: 30
AIR TEMP(DRY): 51 BARO: 29.83 CLOUD AMT: 10
HEIGHT(FT): 1000 SEA: 150-8 SWELL: CONFUSED-12
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.386
6.51
1.13
0.348
5
33.384
6.46
0.79
0.283
10
33.337
6.22
1.12
0.411
20
33.395
6.33
0.92
0.475
30
33.401
5.21
0,67
0.215
50
3 3.49 8
4.46
1.45
0.189
75
33.515
4.84
1.76
0.094
100
33.679
4.79
1.49
0.051
OBSERVED VALUES (SV/T/D- RANSMISSOME ER CAST)
IEPTH
(M)
TEMP
(C)
en mci
(M/SEC)
TP AM CM TTT A M£ P
' (6/0) '
71.9
74.2
74.2
82.2
92.0
92.2
DEPTH TEMP
0
10
20
30
50
75
100
INTERPOLATED VALUES
SO. VEL TRANS. SAL. GXY PHCS CHLOR SIG-T
71.9 33.326 6.51 1.13 0.348
33.3E7 6.22 1.12 C.411
33.395 6.33 0.92 0.475
33.401 5.21 0.67 C.215
33.49c 4.46 1.45 0.189
33.515 4.84 1.76 C.C94
33.679 4.79 1.49 0.C51
270
STATION: HI DEPTH: 825M DATE: 3 NOV 70 TIME: 180C
LAT: 36-58. 3N LONG: 122-41. CW WIND: 140 SPEED: 25
AIR TEMP(DRY): 53 BARO: 29. 8C CLOUD AMT: 10
HEICHT(FT): 1000 SEA: 140-5 SWELL: CCNFUSED-7
. OBSERVED VALUES (NANS EN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/LJ
CHLOROPHYLL
(MG/M3)
0
33.299
6.45
0.56
0.438
10
33.310
6.47
0.54
0.349
25
33.327
6.35
0.57
0.414
35
33.434
6.09
0.77
0.452
50
33.510
5.68
1.02
0.441
75
33.567
4.63
*
1.43
0.295
100
33.750
3.7C
1.86
0. 102
OBSERVED VALUES ( S V/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.94
1499.2
68.4
5
12.94
14 99.3
68. 1
13
12.90
1499.4
67.3
23
12.71
1499.4
68.1
39
11.67
1497.2
74.6
48
11.67
1495.8
74. 5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
10
20
30
50
75
100
12.94 1499.2 68.4
12.91 1499.4 67.6
12.77 1499.4 67.9
12.25 1498.4 7C.9
33.299 6.45 0.56 0.438 25.11
33.310 6.47 0.54 C.349 25.12
33.321 6.39 0.56 C.392 25.16
33.380 6.22 0.67 0.433 25.30
33e51C 5.68 1.02 0.441
33.567 4.63 1.43 0.295
33.75C 3.70 1.86 C.102
271
STATION: H2 DEPTH:llOOM DATE: 3 NOV 70 TIME: 1430
LAT: 37-02. 7N LONG: 122-48. 5W WIND: 140 SPEED: 25
AIR TEMP(DRY): 55 BARO: 29.84 CLOUD AMT: 10
HEIGHT(FT): 50C SEA: 140-3 SWELL: 300-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
32.938
10
32.939
30
33.005
70
33.290
105
33.724
OXYGEN
(ML/L)
6.16
6.22
6.37
5.56
3.41
PHOSPHATE
(MG-ATM/L)
0.35
0.34
0.38
0.96
1.72
CHLOROPHYLL
(MG/M3)
0.151
0.157
0.158
0.067
0.051
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
CEPTH
(M)
TEMP
(C)
SC, VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.99
1502.1
78.0
9
13 *98
1502.3
79.5
28
12.23
1496.9
88.2
37
11.94
1496.3
89.2
69
10.46
1491.9
92.9
83
10.73
1493.4
93.0
97
10.33
1492.2
90.0
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.99
1502.1
78.0
10
13.89
1502.0
80.0
20
12.97
1499.2
84.5
30
12.17
1496. 8
88.4
50
11.34
1494.5
90.7
75
10.58
1492.5
92,9
100
32.938 6.16 0.35 0.151 24.62
32.939 6.22 0.34 0.157 24.64
33.0C5 6.37 0.38 C.158 24.88
33.0C5 6.37 0.38 0.158 25.03
33.147 5.96 0.67 C.122 25.29
33.352 5.25 1.07 0.C82 25.59
33.662 3.71 1.61 0.056
272
STATION: H3 DEPTH: 629M DATE: 3 NOV 70 TIME: 1250
LAT: 37-07. 2N LONG: 122-56. 6W WIND: 140 SPEED: 20
AIR TEMP(DRY): 55 BARC: 29.94 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: 140-2 SWELL: 30C-5
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
32.914
20
32.940
60
33.235
85
33.646
105
33.748
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
5.06
0.35
5.37
0.36
5.59
0.94
3.71
1.57
3.60
1.77
CHLOROPHYLL
(MG/M3)
0.1C0
0.178
0.068
0.052
0.065
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
14.15
15C2.6
85.0
1 /. IT
1 5 C 2 . 8
83.7
35
12.64
1498.5
85.1
48
11.58
1495. C
92.6
69
10.25
1491.2
92.4
86
10.05
1491.0
90.2
98
10.02
1491.2
84.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
14.15
1502.6
85.0
10
14. 12
1502.8
83.7
20
14.12
1502.8
83.7
30
13. 13
1499.9
84.6
50
11.45
1494.6
92.6
75
10.18
1491.1
91.6
100
32.914 5.06 0.35 0.100 24.57
32.940 5.37 0.36 C.178 24.59
32.940 5.37 0.36 0.178 24.59
33.014 5.43 0.51 0.150 24.85
33.161 5.53 0.79 0.C95 25.28
33.481 4,46 1.31 C.C58 25.76
33.723 3.62 1.72 0.062
273
STATION: II DEPTH: 120M DATE: 3 NOV 70 TIKE: 1020
LAT: 37-11. ON LONG: 122-46. CW WIND: 140 SPEED: 15
AIR TEMP(DRY): 55 BARO: 29.94 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: 140-2 SWELL: 3CC-4
. OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLGBOPHYLL
CM6/M3I
0
32.978
6.20
0.37
0.139
5
32.979
6.32
0.39
0.145
10
32.986
6.23
0.39
0.148
20
33.045
6.38
0.43
0.169
30
33.147
6.20
0.63
0.113
50
33.146
5.81
0.89
0.055
75
33.639
4.04
1.59
0.056
100
33.795
3.31
1.87
0.070
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
r, f p t h
( M )
TFMP
(C)
<; r r \/ p i
(M/SEC)
tram<;mttta n C (;
(6/o)
0
13.96
1502.1
80.5
4
13.94
1502. C
81.3
9
13.93
1502.1
79.3
20
13.68
1501.6
79.3
28
13.00
1499.4
80.4
47
10.96
1492.9
90.5
77
9.92
149C.4
89.2
97
9.57
1489.7
82.8
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
32.978 6.20 0.37 0.139 24.56
32.936 6.23 0.39 C.148 24.67
33.C45 6.38 0.43 0.169 24.76
33.147 6.20 0.63 0.113 25.02
33.146 5.81 0.89 0.C55 25.3 8
33.639 4.04 1.59 C.C56 25.91
33.795 3.31 1.87 0.07C
0
13.96
1502.1
80.5
10
13.91
1502.1
79.3
20
13.68
1501.6
79.3
30
12.79
1498.7
81.5
50
10.8 6
1492.6
90.4
75
9.99
1490.6
89.3
100
274
STATION: 12 DEPTH: 120M DATE: 3 NOV 70 TIME: C950
LAT: 37-11. 2N LONG: 122-42. 8W WIND: 140 SPEED: 15
AIR TEMP(DRY): 55 BARO: 29.94 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: 140-2 SWELL: 300-4
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN PHCSPHATE
(ML/L) (HG-ATM/L)
CHLGPOPHYLL
(MG/M3)
0
32.913
6.30 0,
,37
0.132
5
32.911
6.21 0,
,37
0.154
10
32.911
6.34 0,
.38
0.141
20
32.976
6.41 0,
,41
0.155
30
33.123
6.15 0,
,68
0.112
50
33.595
4.08 1,
.48
0.076
75
33.701
3.57 1
.71
0.050
100
33.756
3.35 1,
.84
0.068
118
33.820
3.18
HDCCDWCn \J i
UU ^U in**-*-/ V r
\ L U E S { S V / T / D— T P. A N S M !
rCCOMPTf-R fA<;TI
DEPTH
(M)
TEMP SC. VEL
(C) (M/SEC)
TRANSMITTANCE
(0/0)
75.0
75.0
75.0
80.0
82.2
89.4
90.4
86.3
86.4
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
100
75.0 32.913 6.30 0.37 0.132
32.911 6.34 0.38 0.141
32.976 6.41 0.41 0.155
33.123 6.15 0.68 0.112
33.595 4.C8 1.48 0.C76
33. 7C1 3.57 1.71 C.C5C
33.756 3.35 1.84 C.C68
STATION: 13 DEPTH: 100M DATE: 3 NOV 70 TIME: 0735
LAT: 37-11. ON LONG: 122-38. CW WIND: 140 SPEED: 15
AIR TEMP(DRY): 52 BARO: 29.<=4 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: 140-2 SWELL: 240-5
OBSERVED VALUES (N'ANSEN CAST)
DEPTH
(M>
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.902
6.33
0.40
0.114
10
32.909
6.30
0.40
0.133
30
33.060
6.37
0.58
0.178
60
33.279
5.38
1.10
0.065
75
33.465
-
0.041
90
33.680
3.62
0.061
98
33.760
3.37
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO., VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.76
1501.3
81.8
10
13.75
15CC.5
81.5
25
13.45
1496.0
86.4
49
12.02
1494.2
91.4
60
1492.5
92.6
87
1490.8
88.9
93
,
149C.2
78.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
32.902 6.33 0.40 0.114 24.64
32.909 6.30 0.40 0.133 24.65
32.985 6.33 0.49 0.155 24.74
33.060 6.37 0.58 C.178 24.88
33.2C6 5.71 0.92 0.103 25.41
33.465 0.041
0
13.76
1501.3
81.8
10
13.75
1500.5
81.5
20
13.55
1497. 5
84.8
30
13. 15
1495.6
87.4
50
10.93
1494.0
91.5
75
1491.6
90.5
276
STATION: 14 DEPTH: 95M DATE: 3 NOV 7C TIME: 0615
LAT: 37*11. ON LONG: 122-34. 6k WIND: 150 SPEED: 12
AIR TEMP(DRY): 51 BARO: 29.95 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: 150-1 SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.943
6.23
0
0.38
0. 146
10
32.948
6.28
0.39
0.158
35
33.210
6.01
0.75
0. 158
50
33.250
5.54
1.00
0.C98
75
33.625
3.86
1.61
0.055
93
33.746
3.35
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH
1 M )
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
o
13. 69
] 501. 1
80. 2
10
13.41
15CC.4
81.3
29
11.98
1496.2
85.2
48
10.44
1491.2
92.2
78
10.20
1491.3
81
10.19
1491.2
83.4
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. €XY PHOS CHLOR SIG-T
0
13.69
1501.1
80.2
10
13.41
1500.4
81.3
20
12.66
1498.2
83.4
30
11.90
1495.9
85.6
50
10.42
1491.2
86.1
75
10.22
1491.3
9.2
32.943 6.23 0.38 C.146 24.68
32.948 6.28 0.39 0.158 24.74
33.053 6.17 0.53 0.158 24.97
33.158 6.06 0.68 0.158 25.20
33.250 5.54 1.00 C.098 25.54
33.625 3.86 1.61 0.055 25.86
277
STATION: 15 DEPTH: 93M DATE: 3 NOV 70 TIME: 0445
LAT: 37-10. 6N LONG: 122-33. GW WIND: LIGHT AIRS
AIR TEMP(DRY): 50 BARO: 29.94 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
32.962
10
32.965
25
33.144
45
33.480
70
33.714
80
33.720
91
33.722
OXYGEN
(ML/L)
5.67
5.38
6.42
5.11
3.50
3.46
3.33
PHOSPHATE
(MG-ATM/L)
0.39
0.40
0.48
1.20
1.21
1.93
1.91
CHLOROPHYLL
(MG/M3)
0.
, 186
0,
,172
0.
,185
0.
,095
0.
,068
0,
,116
OBSERVED VALUES ( SV/T/D- TR ANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
*
TRANSMITTANCE
(0/0)
76.9
76.6
78.1
90.5
72. C
55.4
49.4
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
76.9 32.962 5.67 0.39 0.186
32.965 5.38 0.40 0.172
33.084 6.07 0.45 0.181
33.228 6.09 0.66 0.162
33.527 4.79 1.20 0.C94
33.717 3.48 1.57 C.102
278
STATION: 16 DEPTH: 8AM DATE: 3 NOV 70 TIME: 0350
LAT: 37-10. 8N LONG: 122-30. 8H WIND: LIGHT AIRS
AIR TEMP(DRY): 50 BARO: 29.54 CLOUD AMT: 10
HEIGHT(FT): 500 SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHCSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.958
4.08
0.39
0.214
10
33.024
4.04
0.41
0.238
25
33.360
5.72
0.59
0.495
45
33.417
4.61
0.95
0.226
60
33.603
3.54
1.54
0.C80
82
33.700
3.29
1.99
OBSERVED VALUES ( SV/T/D-TR ANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
n
U
13.57
1 5 C C t 8
76.1
9
13.20
15 00.1
65.8
29
12.40
1498.0
74.4
50
11.55
1495.4
91.4
60
10.71
1452.7
100.0
78
10.16
14 91.3
82.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
32.958 4.08 0.39 0.214 24.72
33.C24 4.04 0.41 0.238 24.85
33.248 5.16 0.53 C.409 25.10
33.374 5.44 0.68 0.428 25.28
33.475 4.25 1.14 0.177 25.51
33.669 3.37 1.85 0.C25 25.85
0
13.57
1500.8
76.1
10
13. 16
1500. C
66.2
20
12.76
149 8.9
7C.5
30
12.36
1497.9
75.2
50
11. 55
1495.4
91.4
75
10.25
1491.5
85.5
279
STATION: 17 DEPTH: 77M DATE: 3 NOV 70 TIME: 0300
LAT: 37-10. 7N LONG: 122-29. CW WIND: LIGHT AIRS
AIR TEMP(DRY): 49 BARO: 30. CO CLCUC AMT: 10
HEIGHT(FT): 500 SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.158
5.26
0.44
0.448
10
33.339
6.41
0.53
0.521
20
33.411
5.76
0.66
0.343
40
33.508
5.37
1.04
0.339
60
33.632
3.66
1.72
0.266
65
33.651
3.62
1.82
0.254
75
33.671
3.45
2.18
OBSERVED VALUES ( SV/T/D-TPANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO.. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.35
150C.5
68.8
10
13.12
1500.3
67.9
20
12.83
1499.1
71.6
40
11.84
1496.3
78.1
50
11.15
14 94.1
56.0
61
10.60
1492.5
59.2
7C
10.28
1491.6
34.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
33.15E 5.26 0.44 0.448 24.92
33.339 6.41 0.53 0.521 25.10
33.411 5.76 0.66 C.343 25.22
33.459 5.57 0.85 0.341 25.35
33.570 4.51 1.38 C.312 25.66
33.671 3.45 2.18
0
13.35
1500.5
68.8
10
13. 12
1500.3
67.9
20
12.83
1499. 1
71.6
30
12.33
1497.7
74.8
50
11.15
1494.1
56.0
75
280
STATION: 18 DEPTH: 60M DATE: 3 NOV 70 TIME: 0200
LAT: 37-10. 4N LONG: 122-27. Ch WIND: LIGHT AIRS
AIR TEMP(DRY): 49 BARO: 30. CO CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.388
3.72
0.56
0.673
5
33.440
4.74
0.66
0.792
20
33.579
4.60
1.43
0.361
25
33.594
3.28
1.50
0.457
35
33.614
3.52
1.59
0.293
50
33.637
3.21
1.73
0.336
59
33.654
3.83
2.00
OBSERVED VALUES ( SV/T/D- IRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.05
1499.5
68.1
5
12.94
1499.3
66.0
20
11.81
1495.7
66.6
25
11.45
1494.7
61.0
30
11.25
1494.2
56.4
50
10.73
1492.7
43.5
56
10.70
1492.7
41.2
DEPTH TEMP SO,
INTERPOLATED VALUES
VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.05 1499.5
10 12.56 1498.1
20 11.81 1495.7
30 11.25 1494.2
50 10.73 1492.7
68.1 33.388 3.72 0.56 C.673 25.16
66.2 33.486 4.69 0.92 0.655 25.33
66.6 33.579 4.60 1.43 0.381 25.54
56.4 33.6C4 3.40 1.55 0.375 25.66
43.5 33.637 3.21 1.73 0.336 25.78
281
STATION: 19 DEPTH: 55M DATE: 3 NOV 70 TIME: 0100
LAT: 37-10. 5N LONG: 122-25. 6W WINO: LIGHT AIRS
AIR TEMP(DRY): 49 BARO: 30. CC CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
CM)
SALINITY
(0/00)
0
33.455
5
33.455
10
33.483
20
33.534
30
33.556
45
3 3.5 64
54
33.612
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
4.13
0.85
3.79
0.84
4.94
C.92
4.60
1.24
4.07
1.43
3.63
1.56
3.98
2.06
CHLOROPHYLL
(MG/M3)
0.551
0.616
0.371
0.354
0.4C5
0.477
OBSERVED VALUES ( SV/T/D-YRANSMl SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
S0„ VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0 ]
.2.61
1498.2
59.5
5 ]
12.25
14 9 7.2
57.2
10 ]
L2.12
1496.7
61.3
15 J
LI. 81
1495.8
52.5
19 ]
LI. 61
149 5.3
54.1
25 ]
LI. 47
1495.0
47.2
34 ]
LI. 37
14 94.8
44.4
45 ]
LI. 13
1494.1
13.8
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.61 1498.2
10 12.12 1496.7
20 11.59 1495.2
30 11.41 1494.9
50
59.5 33.455 4.13 0.85 0.551 25.29
61.3 33.483 4.94 0.92 C.371 25.41
52.9 33.534 4.60 1.24 0.354 25.55
45.6 33.556 4.07 1.43 0.405 25.60
33.599 3.83 1.84 0.212
282
STATION: Jl DEPTH: 35M DATE: 2 NOV 70 TIME: 2315
LAI: 37-16. 2N LONG: 122-27. 4W WIND: LIGHT AIRS
AIR TEMP(DRY): 50 6AR0: 30.02 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.319
6.29
0.52
0.596
5
33.355
6.45
0.54
0.691
10
33.397
6.48
0.58
0.597
15
33.399
6.51
0.59
0.865
20
33.418
6.49
0.63
0.633
25
33.461
6.18
0.78
0.361
34
33.576
4.59
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.09
1499.6
63.9
3
13.09
14 9 9.7
63.0
7
13. 09
149 9.7
63. C
10
12.98
1499.5
65.6
16
12.87
1499.3
67.6
20
12.80
1499.1
68.6
25
12.49
1498.1
64.7
30
12.15
1497.5
37.5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.09 1499.6
10 12.98 1499.5
20 12. 8C 1499.1
30 12.15 1497.5
63.9 33.319 6.29 0.52 0.596 25.09
65.6 33.397 6.48 0.58 0.597 25.18
68.6 33.416 6.49 0.63 0.633 25.23
37.5 33.525 5.29 0.35 C.160 25.44
283
STATION: J2 DEPTH: 40M DATE: 2 NOV 70 TIME: 2145
LAT: 37-21. 5N LONG: 122-29. 5W WIND: LIGHT AIRS
AIR FEMP(DRY): 50 BARO: 30.02 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.434
6.48
0.53
0.5C9
5
33.430
6.48
0.55
0.728
10
33.481
6.30
0.71
0.413
20
33.540
5.63
1.02
0.369
30
33.555
5.20
1.18
0.295
35
33.593
4.57
1.44
0.397
39
33.635
4.07
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETE R CAST)
DEPTH-
(MJ
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.04
1499.5
70.9
5
12.98
1499.5
66.9
9
12.61
1496.7
72.3
14
12.37
1497.6
76.2
19
12.16
1496.9
78.0
26
11.81
1495. 9
78.2
30
11.65
1495.4
75.3
35
11.57
1495.3
60.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.04 1499.5
10 1.2.56 1498.5
20 12.11 1496.8
30 11.65 1495.4
70.9 33.434 6.48 0.53 0.509 25.19
73.1 33.481 6.30 0.71 0.413 25.32
78.0 33.540 5.63 1.02 0.369 25.46
75.3 33.555 5.20 1.18 0.295 25.55
284
STATION: J3 DEPTH: 40M DATE: 2 NOV 70 TIME: 2045
LAT: 37-26. 6N LONG: 122-31. 4W WIND: LIGHT AIRS
AIR TEMP(DRY): 49 BARO: 29.99 CLOUD AMT: 1C
TYPE: FOG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.310
6.49
0.60
0.289
5
33.310
6.46
0.56
0.276
10
33.373
6.34
0.58
0.170
20
33.517
6.02
0.87
0.175
25
33.533
5.40
1.14
0.146
39
33.607
3.87
OBSERVEO VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
1? w 14
i 4^ .<;
70.9
5
13.02
1499.4
79.9
10
12.95
1499.4
79.7
15
12.82
1499.0
86.5
20
12.48
1498. 1
83.7
24
12.30
64.8
30
11.82
1496.2
71.3
35
11.57
1495.4
67.1
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.14 1499.9
10 12.95 1499.4
20 12.48 1498.1
30 11.82 1496.2
70. 9 33.310 6.49 0.60 0.289 25.08
79.7 33.373 6.34 0.58 C.170 25.16
83.7 33.517 6.02 0.87 0.175 25.37
71.3 33.559 4.85 0.73 0.C94 25.53
285
STATION: J4 DEPTH: 45M DATE: 2 NOV 70 TIME: 1830
LAT: 37-31. 9N LONG: 122-33. 5W WIND: LIGHT AIRS
AIR TEMP(DRY): 49 BARO: 29.99 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.339
6.60
0.68
0.234
5
33.336
6.39
0.55
0.176
10
33.339
6.30
0.58
0.238
20
33.438
6.16
0.72
0.127
30
33.561
4.75
1.54
0.127
43
32.583
4.15
OBSERVED VALUES ( SV/T/D-TRANSM I SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
13
n /,
W»CQvA
1499.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. CXY PHOS CHLOR SIG-T
0
10
20
30
13.06 1499.6
33.339 6.60 0.68 0.234 25.12
33.339 6.30 0.58 0.238
33.438 6.16 0.72 C. 127
33.561 4.75 1.54 0.127
286
STATION: Kl DEPTH: 45M DATE: 2 NOV 70 TIKE: 1745
LAT: 37-31. 8N LONG: 122-35. OW WIND: LIGHT AIRS
AIR TEMP(DRY): 52 BARO: 29,99 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(KG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.329
6.51
0.52
0.565
7
33.334
6.39
0.52
0.645
14
33.394
6.16
0.61
0.354
25
33.473
5.95
0.79
0.649
35
33.561
4.64
1.42
0.431
44
33.608
3.89
■
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
1 3 « ° °
1499,4
75. *>
6
13.02
1499.4
78.0
13
12.97
1499.4
79.3
19
12.45
1497.9
99.4
31
12.16
1497.2
100.0
41
11.02
1493.5
24.9
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.02 1499.4
10 12.99 1499.4
20 12.43 1497.8
30 12.18 1497.3
75.5 33.329 6.51 0.52 0.565 25.12
78.7 33.360 6.29 0.56 C.520 25.15
99.4 33.437 6.04 0.71 0.515 25.32
99.9 33.517 5.29 1.11 C.540 25.42
287
STATION: K2 DEPTH: 49M DATE: 2 NOV 70 TIME: 1640
LAT: 37-31. 4N LONG: 122-37. C)W WIND: LIGHT AIRS
AIR TEMP(DRY): 55 BARO: 30.00 CLOUD AMT : 10
TYPE: FCG SEA: RIPPLES SWELL: 240-3
RAMSEY MECHANISM INOPERATIVE
OBSERVED VALUE
S (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.301
4.35
0.52
0.731
5
33.303
3.31
0.49
0.721
15
33.377
3.96
0.82
0.287
25
33.533
3.99
1.06
0.192
40
33.621
2.20
1.81
0.289
45
33.640
1.84
2.09
OBSERVED VALUES ( SV/T/D-TRANSMl SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
65 r 3
68.6
71.0
82.0
100.0
100.0
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
65.3 33.301 4.35 0.52 0.731
33.340 3.63 0.66 C.504
33.455 3.97 0.94 0.239
33.562 3.39 1.31 0.224
288
STATION: K3 DEPTH: 53M DATE: 2 NOV 70 TIME: 1550
LAT: 37-32. ON LONG: 122-r38.9h HIND: LIGHT AIRS
AIR TEMP(DRY): 55 BARO: 30.00 CLOUD AMT: 10
TYPE: FOG SEA: RIPPLES SWELL: 240-3
RAMSEY MECHANISM INOPERATIVE
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.246
6.62
0.48
0.393
5
33.282
6.55
0.49
0.6C7
10
33.317
6.53
0.57
0.633
25
33.411
5.67
0.97
0.329
45
33.611
3.98
1.64
0.170
52
33.650
2.79
2.07
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
54.1
54.3
56.5
73.8
84.2
91.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
54.1 33.246 6.62 0.48 0.393
33.317 6.53 0.57 0.633
33.380 5.96 0.84 0.430
33.461 5.25 1.14 0.289
33.639 3.13 1.94 C.049
289
STATION: K4 DEPTH: 55M DATE: 2 NOV 70 TIKE: 1505
LAT: 37-31. 7N LONG: 122-41. OW WIND: LIGHT AIRS
AIR rEMP(DRY): 55 BARO: 30.00 CLOUD AMT: 10
TYPE: FOG SEA: RIPPLES SWELL: 240-3
RAMSEY MECHANISM INOPERATIVE
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.154
10
33.281
20
33.330
30
33.408
45
33.561
OXYGEN
(ML/L)
6.58
6.63
6.34
5.73
4.53
PHOSPHATE
(MG-ATM/L)
0.47
0.49
0.68
1.04
1.46
CHLOROPHYLL
(MG/M3)
0.429
0.868
0.560
0.216
0.089
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
66.8
59 e 1
54.9
57.0
74.5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
66.8 33.154 6.58 0.47 0.429
33.281 6.63 0.49 0.868
33.330 6.34 0.68 C.580
33.408 5.73 1.04 0.216
290
STATION: K5 DEPTH: 60M DATE: 2 NOV 70 TIME: 1420
LAT: 37-32. ON LONG: 122-42. 7W WIND: LIGHT AIRS
AIR TEMP(DRY): 55 BARO: 30. C2 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-2
RAMSEY MECHANISM INOPERATIVE
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.162
6.44
0.41
0.436
10
33.296
6.51
0.62
0.754
20
3 3.2 84
6.18
0.72
0.447
30
33.226
5.50
0.99
0.139
50
33.592
3.89
1.66
0.143
58
33.651
3.54
OBSERVED VALUES ( SV/T/D^"f RANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO- VEL
(M/SEC)
TRANSMITTANCE
(0/0)
67.1
64.2
59.4
73.6
88.8
90.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
67.1 33.162 6.44 0.41 0.436
0.0 33.296 6.51 0.62 0.754
0.0 33.284 6.18 0.72 0.447
0.0 33.226 5.50 0.99 0.139
0.0 33.5S2 3.89 1.66 0.143
291
STATION: K6 DEPTH: 73M DATE: 2 NOV 70 TIME: 1310
LATE: 37-32. ON LCNG : 122-45 . 7W WIND: LIGHT AIRS
AIR TEMP(DRY): 58 BARO: 30.04 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240^2
RAMSEY MECHANISM INOPERATIVE
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLCROPHYLL
(MG/M3)
0
33. 146
6.44
0.42
0.433
10
33.371
6.23
0.73
0.555
20
33.212
5.49
1.04
0.127
30
33.413
4.92
1.30
0.094
55
33.695
3.7C
1.87
0.218
73
33.699
3.29
OBSERVED VALUES ( SV/T/D-1 RANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
69.6
65.2
68.9
85.3
89.8
91.2
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
69.6 33.146 6.44 0.42 0.433
33.371 6.23 0.73 0.555
33.212 5.49 1.04 0.127
33.413 4.92 1.30 0.C94
33.639 3.94 1.76 0.193
292
STATION: K7 DEPTH 91M DATE: 2 NOV 70 TIME: 1110
LAT: 37-31. 7N LONG: 122-50. AW WIND: LIGHT AIRS
AIR rEMP(DRY): 58 BARO: 30. C4 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-2
RAMSEY MECHANISM INOPERATIVE
. OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOPOPHYi.L
(MG/M3)
0
33.262
6.86
0.45
0.656
5
33.286
6.90
0.45
0.980
10
33.386
6.81
0.5 8
0.955
15
33.460
5.82
0.92
0.549
20
33.449
5.31
1.12
0.253
35
33.407
0.0
*
1.34
0.069
50
33.724
3.39
1.86
0.229
90
2.77
2.02
OBSERVED VALUES ( S V/T/D-TRANSMI S SOMETE R CAST)
ng DTM
TFMP
(C)
<;n, vfi
(M/SEC)
TR ANSMITTANCE
(0/0)
51,
► 2
53,
,3
65,
.0
81,
.8
85,
.4
86,
.5
56,
,6
68,
.9
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
51.2 33.262 6.86 0.45 0.656
33.386 6.81 0.58 0.955
33.449 5.31 1.12 0.253
33.421 1.77 1.27 0.130
33.724 3.39 1.86 C.229
3.01 1.96 0.C86
293
STATION: K8 DEPTH: 101M DATE: 2 NOV 70 TIME: 0945
LAT: 37-32. ON LONG: 122-54. 3 V> WIND: LIGHT AIRS
AIR TEMP(DRY): 60 BARO: 30.03 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 240-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.392
7
33.391
25
33.488
35
33.531
60
33.762
85
33.836
95
33.861
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
4.31
0.47
6.7C
0.69
5.77
0.9C
3.91
1.16
3.48
1.84
2.14
1.97
2.24
2.01
CHLOROPHYLL
(MG/M3)
0.
,633
0.
,766
0,
.679
0,
,249
0,
.698
0,
.101
OBSERVED VALUES ( SV/T/D-TRANSM I SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO, VEL
(M/SEC)
TRANSMITTANCE
(0/0)
C
12.94
1499.3
40.0
9
12.64
1498.6
45.4
28
11.00
1493.2
85.2
39
10.47
1491.6
81.5
60
9.56
1489.0
86.4
81
9.37
1498.7
83.0
94
9.24
1488.5
74.9
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
12.94
1499.3
40.0
10
12.55
1498.3
47.5
20
11.69
1495.5
68.4
30
10. 9C
1492.9
84.5
50
9.99
1490.2
84.1
75
9.42
1488.8
84.0
33.392 4.31 0.47 0.633 25.18
33.407 6.54 0.72 0.751 25.27
33.461 6.03 0.84 0.703 25.47
33.51C 4.84 1.03 0.464 25.65
33.670 3.65 1.57 0.518 25.94
33.8C6 2.67 1.92 0.340 26.14
294
STATION: K9 DEPTH: 210M DATE: 2 NOV 70 TIKE: 0845
LAT: 37-32. ON LONG: 122-58.11* WIND: LIGHT AIRS
AIR TEMP(DRY): 51 BARO: 30.02 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 280-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLCROPHYLL
(MG/M3)
0
32.293
6.85
0.49
0.829
10
33.271
7.50
0.47
0.794
30
33.307
6.48
0.56
0.7C5
40
33.470
5.06
1.03
1.170
60
33.610
4.40
1.54
0.289
80
33.743
3.26
1.77
0.127
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
1
to no
1499,3
54.0
14
12.69
1498,5
58.8
26
12.44
1496.5
72.2
40
11.33
1494.5
80.7
50
10.89
1493.3
84.2
61
10.53
1492.3
84.2
102
9.23
1488.6
90.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHCS CHLOR SIG-T
0
10
12.76
149 8.7
57.3
20
12.56
1497.5
65.5
30
12.12
1495.9
74.6
50
10.89
1493.3
84.2
75
10.09
1491.0
86.3
32.293 6.85 0.49 0.829
33.271 7.50 0.47 0.794
33.289 6.99 0.52 0.749
33.3C7 6.48 0.56 0.705
33.54C 4.73 1.28 0.729
33.71C 3.54 1.71 0.167
295
STATION: KIO DEPTH: 600M DATE: 2 NOV 70 TIME: 0723
LAT: 37-32. ON LONG: 123-03. 6W WIND: LIGHT AIRS
AIR TEMP(DRY): 51 BARQ: 30.02 CLOUD AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 280-2
■ OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33. 195
6.32
0.44
0.219
10
33.212
6.43
0.46
0.430
20
33.218
6.43
0.47
0.296
37
33.367
6.46
0.68
0.951
50
33.429
5.42
1.08
0.405
60
33.564
4.77
'
1.39
0.442
100
33.7C9
3.38
1.81
0.288
OBSERVED VALUES ( S V/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.54
15C1.8
75.8
10
13.52
15C1.6
76.2
20
13.17
15C1.0
86.4
40
11.97
1496.9
62.1
50
11.17
1494.3
82.5
60
11.18
1494.6
82.7
80
10.27
1491.9
82.9
99
9.99
1491.1
79.8
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.54
1501.8
75.8
10
13.52
1501.6
76.2
20
13.17
1501.0
86.4
30
12.57
1498.9
84.2
50
11.17
1494.3
82.5
75
10.50
1492.6
82.8
100
33.195 6.32 0.44 0.219 24.91
33.212 6.43 0.46 C.430 24.93
33.216 6.43 0.47 C.296 25. CO
33.3C6 6.45 0.59 0.681 25.19
33.429 5.42 1.08 C.405 25.54
33.619 4.25 1.55 C.384 25.81
33.7C9 3.38 1.81 C.288
296
STATION: Kll DEPTH: 680M DATE: 2 NOV 70 TIME: 0610
LAT: 3Y-32.CN LONG: 123-07. 7Vv WIND: LIGHT AIRS
AIR TEMP(DRY): 51 BARO: 29.^9 CLOUC AMT: 10
TYPE: FCG SEA: RIPPLES SWELL: 280-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(MJ
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHY.L
(MG/M3)
0
33.028
5.38
0.37
0. 159
5
33.030
6.29
0.36
0.149
10
33.023
6.33
0.36
0.139
15
33.045
6.32
0.39
0.176
40
33.330
5.79
0.89
0.143
57
33.628
3.90
1.56
0.057
80
33.755
3.22
1.81
0.080
100
33.830
2.97
1.89
0.062
OBSERVED VALUES ( SV/T/D-T RANSMI SSCMETER CAST)
r< c r» tu
i > i_ i iii
(MJ
T CM D
(C)
SO. \/ p i
Tm/secT
TR ANI^MTTTANf.F
(0/0)
13.83
1503.6
74.9
13.83
1503.7
75.3
13.69
1503.4
80.6
13.34
1502.8
82.2
11.32
1496.0
88.8
10.15
1491.8
88.7
9.89
1491. C
82.0
9.49
1489.9
86.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
100
13.83 1503.6
74.9 33.028 5.38 0.37 0.159
33.023 6.33 0.36 0.139
33.102 6.22 0.49 0.169
33.216 6.01 0.69 0.156
33.506 A. 68 1.28 0.C92
33.728 3.37 1.76 0.075
33.830 2.97 1.89 0.062
24.7 2
297
STATION: LI DEPTH: 110M DATE: 2 NOV 70 TIME: C342
LAT: 37-37. 5N LONG: 123-15. 9W WIND: LIGHT AIRS
AIR TEMP(DRY): 51 BARO: 30.00 CLOUD AMT: 0
HEIGHT(FT): CLEAR SEA: RIPPLES SWELL: 280-2
RAMSEY MECHANISM INOPERATIVE
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.015
6.12
0.43
0.122
5
33.014
6.16
0.41
0.131
15
33.087
6.32
0.45
0.154
25
33.146
6.08
0.62
0.227
50
33.283
5.48
1.01
0.078
75
33.659
4.04
1.56
0.079
100
33.792
3.27
1.84
0.047
OBSERVED VALUES ( S V/T/D-TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
76.7
10
76.3
25
78.4
40
64.8
60
88.3
75
86.3
100
85.6
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
10
20
30
50
75
76.7 33.015 6.12 0.43 0.122
76.3 33.05C 6.24 0.43 0.142
77.7 33.116 6.20 0.53 0.19C
80.5 33.263 5.48 1.01 0.078
86.5 33.659 4.04 1.56 0.079
86.3 33.792 3.27 1.84 0.047
298
STATION: L2 DEPTH: 113M DATE: 2 NOV 70 TIME: 0100
LAT: 37-42. 4N LONG: 123-07. 7W WIND: LIGHT AIRS
AIR TEMP(DRY): 51 BARO: 30.00 CLOUD AMT: 0
HEIGHT(FT): CLEAR SEA: RIPPLES SWELL: 280-2
- OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/U
CHLCROPHY'.L
(MG/M3)
0
33.119
6.16
0.46
0.155
10
33.154
6.14
0.41
0.216
25
33.333
6.05
0.67
0.282
40
33.435
5.01
1.23
0.642
60
33.650
3.46
1.80
0.285
87
33.722
3.11
1.98
0.204
100
3 3.79 8
3.05
2.10
0.175
OBSERVED VALUES ( SV/T/D-TRANSMI SSOMETER CAST)
DEPTH-
CM)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
13.57
1501.1
76.4
8
13.56
1501.2
76.9
13
13.31
15CC.6
80.1
27
12.59
1498.4
81.1
47
11.22
1494.3
78.2
67
10.11
1491.1
87.1
86
9.64
1489.7
66.6
100
9.21
1488.5
68.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.57
1501. 1
76.4
10
13.46
1501.0
78.2
20
12.95
1499.5
80.6
30
12.38
1497.8
80.7
50
11.05
1493.8
79.5
75
9.91
1490.5
78.5
100
9.21
1488. 5
68.7
33.119 6.16 0.46 0.155 24.84
33.154 6.14 0.41 0.216 24.89
33.274 6.08 0.58 0.260 25.09
33.367 5.71 0.86 0.402 25.27
33.542 4.24 1.51 0.463 25.65
33.69C 3.27 1.90 C.240 25.97
33.796 3. 05 2.10 0.175 26.16
299
STATION: L3 DEPTH: 71M DATE: 1 NOV 70 TIME: 2308
LAT: 37-47. 6N LONG: 123-00. 4W WIND: 320 SPEED: 8
AIR TEMP(DRY): 53 BARO: 30.05 CLOUD AMT: 2
HEIGHT(FT): 1000 SEA: 320-1 SWELL: 280-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.224
2.26
0.46
0.916
10
33.222
2.38
0.49
1.114
20
33.246
2.62
0.65
0.892
30
33.457
1.86
1.10
0.697
43
33.483
2.56
1.18
1.241
50
33.642
2.13
1.63
0.7C7
60
33.676
1.71
1.82
0.797
65
33.696
1.51
1.97
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
QCDTU
(M)"
TCMD
(C)
en, \/fi
Tm/secT
TR AM<;.M I TTAMfF
(C/0)
0
13.20
1499.9
64.4
10
12.90
1498.8
69. 1
19
12.56
149 8.2
74.5
30
11.87
1496.1
70.9
40
11.20
14 94. C,
74.9
48
10.47
1492.0
80.1
59
10.03
149C5
71.3
63
9.97
1490.4
54.0
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.20 1499.9
10 12.90 1498.8
20 11.87 1496.1
30 11.87 1496.1
50 10.39 1491.7
64.4 33.224 2.26 0.46 C.916 25.00
69.1 33.222 2.38 0.49 1.114 25.06
70.9 33.246 2.62 0.65 0.892 25.27
7C.9 33.457 1.86 1.10 0.697 25.44
78.5 33.642 2.13 1.63 0.707 25.85
300
STATION: L4 DEPTH: 54M DATE: 1 NOV 70 TINE: 2125
LAT: 37-53. 9N LONG: 122-53. 2W WIND: 320 SPEED: 8
AIR TEMP(DRY): 54 BARO: 30. C4 CLOUD AMT: 3
HEIGHT(FT): 1000 SEA: 320-1 SWELL 280-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(Ml
SALINITY
(0/00)
OXYGEN
(ML/L)
PHCSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
32.588
6.73
1.27
0.6C2
5
32.588
6.65
1.26
0.627
15
33.257
4.62
0.85
0.9C8
25
33.416
6.03
C.90
0.524
35
33.623
4.54
1.54
0.784
41
33.683
3.61
1.84
0.569
45
33.718
2.08
2.25
0.6 59
50
33.727
2.61
2.23
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETE R CAST)
DEPTH
(M)
T CM p
(C)
SO. V E L
(M/SEC)
TR AKKM TTTANf. F
(0/0)
0
13.09
14 9 8.8
56.0
5
13.09
1 4 <; 8 . 9
55.4
8
12.75
14 9 8.6
67.9
14
12.59
1498.3
74.5
23
11.79
1496.0
78.6
32
10.82
1492.6
82.1
42
10.20
1491.0
60.5
47
10. OC
1490.4
43.2
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.09 1498.8
10 12.70 1498.5
20 12.06 1496.8
30 11.04 1493.4
50
56.0 32.588 6.73 1.27 0.602 24.53
70. 1 32.922 5.64 1.05 0.767 24.87
77.2 33.336 5.33 0.87 C.716 25.31
81.3 33.519 5.28 1.22 0.654 25.64
33.727 2.61 2.23
301
STATION: Ml DEPTH: 44M DATE: 1 NOV 70 TIME: 2020
LAT: 37-52. 6N LONG: 122-48. 5W WIND: 320 SPEED: 8
AIR TEMP(DRY): 54 BARO: 30.04 CLOUD AMT: 8
HEIGHT(FT): 1000 SEA: 320-1 SHELL: 280-2
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.266
5.21
0.75
0.509
5
33.261
4.33
0.77
0.554
12
33.293
4.71
0.74
0.757
15
33.337
6.13
0.75
1.029
25
33.523
3.80
2.16
1.468
35
33.633
2.88
1.51
0.515
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12*86
1 A C fi O
70 . 9
3
12.84
1498.9
70.9
8
12.44
14 9 8.2
71.5
13
12.44
1498. C
74.8
17
11.89
1497.0
80.6
22
10.86
1496.2
80.6
27
1494.5
81.8
32
1492.5
49.0
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.86 1498.9
10 12.44 1498.1
20 11.27 1496.5
30 1493.3
70.9 33.266 5.21 0.75 0.509 25.10
72.8 33.284 4.60 0.75 C.699 25.19
80.6 33.430 4.96 1.46 1.248 25.53
62.1 33.578 3.34 1.84 0.991
302
STATION: M2 DEPTH: 47M DATE: 1 NOV 70 TIME: 1911
LAT: 37-49. 5N LONG: 122-48. 6W WIND: 280 SPEED: 5
AIR TEMP(DRY): 54 BARO: 30.02 CLOUD AMT: 8
HEIGHT(FT): 100C SEA: 290-1 SWELL: 250-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHCSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.271
6.29
0.72
0.781
5
33.255
6.82
0.75
0.883
10
33.274
4.92
C.65
0.739
15
33.311
6.31
0.69
1.390
20
33.363
6.49
0.76
0.989
25
33.517
5.70
1.61
1.106
32
33.624
4.34
0.3C3
OBSERVED VALUES ( SV/T/D-TRAN SMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.94
1499.2
68.2
5
12.91
1499.1
63.4
10
12.91
1499. 1
61.3
16
12.51
1498.0
69.2
20
12.44
1497.8
74« 1
25
11.79
1496.1
79.0
29
10.99
1494.6
79.0
33
1493.5
83.3
37
1491.2
52.5
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHGS CHLOR SIG-T
0
12.94
1499.2
68.2
10
12.91
1499. 1
61.3
20
12.44
1497.8
74.1
30
8.24
1494.3
8C.1
33.271 6.29 0.72 0.781 25.09
33.274 4.92 0.65 0.739 25.10
33.363 6.49 0.76 0.989 25.26
33.594 4.73 0.46 0.532 26.16
303
STATION: M3 DEPTH: 42M DATE: 1 NOV 70 TIME: 1745
LAT: 37-46. ON LONG: 123-46. 5W WIND: 280 SPEED: 5
AIR TEMP(DRY): 54 BARO: 30.02 CLOUD AMT: 8
HEIGHT(FT): 1000 SEA: 290-1 SWELL: 250-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
0
33.082
5
33.138
12
33.373
15
33.396
17
33.464
25
33.594
30
33.606
OXYGEN
(ML/L)
PHCSPHATE
(MG-ATM/L)
6.62
0.89
6.74
0.89
6.19
0.90
5.76
0.94
4.87
1.08
2.88
1.57
2.87
1.64
CHLCROPHYLL
(MG/M3)
1,
.005
1.
.185
1,
.182
0,
.689
0,
.630
0,
,4C5
OBSERVED VALUES ( SV/T/D- TRANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SC. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.82
1498.6
51.6
5
12.72
1498.2
63.7
8
12.13
1497.7
70.7
12
12.13
1496.7
77.6
18
11.29
1494.1
68.7
23
10.88
1492.9
67.2
27
10.55
1492.0
37.1
32
1492.0
33.2
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.82 1498.6
10 12.13 1497.2
20 11.13 1493.6
30 4.22 1492.0
51.6 33.082 6.62 0.89 1.005 24.96
74.1 33.306 6.35 0.90 1.183 25.27
68.1 33.513 4.13 1.26 0.546 25.62
34.8 33.6C6 2.87 1.64 26.68
304
STATION: M4 DEPTH: 40M DATE: 1 NOV 70 TIME: 1635
LAT: 37-43. 5N LONG: 122-44. 5W WIND: 260 SPEED: 6
AIR TEMP(DRY): 58 BARO: 30.03 CLOUD AMT: 9
HEIGHT(FT): 1000 SEA: 260-1 SWELL: 250-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
( M )
SALINITY
(0/00)
0
32.736
4
32.919
10
33.310
15
33.398
22
33.560
30
33.618
OXYGEN
(ML/L)
6.49
5.82
5.96
5.47
4.46
3.45
PhCSPHATE
(MG-ATM/L)
1.32
1.14
0.84
1.01
1.27
1.75
CHLOROPHYLL
(MG/M3)
0.
,718
1,
,076
1.
,566
1,
,515
0.
,612
0,
.550
OBSERVED VALUES ( SV/T/D-TRANSM I SSOMETE R CAST)
DEPTH
( M )
TEMP
<C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
I 3 . no
4 5*2
5
12.91
8
12.73
1497.9
55.4
14
12.31
1497.4
65.8
19
11.50
1496.2
68c8
23
11.04
1495.2
72.1
28
1493.6
60.0
34
1493.2
46.7
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0
13.09
10
12.59
1497.7
20
11.38
1495.9
30
1493*5
45.2 32.736 6.49 1.32 0.718 24.64
58.9 33.31C 5.96 0.84 1.566 25.19
69.6 33.514 4.75 1.20 0.870 25.57
55.6 33.618 3.45 1.75 C.55C
305
STATION: M5 DEPTH: 39M DATE: 1 NGV 70 TIME: 1545
LAT: 37-40. 3N LONG: 122-42. CW WIND: 260 SPEED: 6
AIR TEMP(DRY): 58 BARO: 30.03 CLOUD AMT: 9
HEIGHT(FT): 1000 SEA: 260-1 SWELL: 250-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(Ml
SAL INITY
(0/00)
0
33.445
8
33.457
15
33.498
20
33.557
25
33.605
30
33.592
OXYGEN
(ML/L)
6.51
6.44
5.93
4.94
1.87
2.14
PHOSPHATE
(MG-ATM/L)
C.66
0.71
C.92
1.29
1.74
1.87
CHLOROPHYLL
(MG/M3)
0.
,878
1.
,459
1.
,008
0.
,798
0.
,721
0,
,822
OBSERVED VALUES ( SV/T/D-TRANSMI S SOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
transmittance:
(0/0)
n
1 ^ o^
14Q9c 7
60-4
4
12.47
1498.6
61.6
9
11.92
1498.0
66.1
14
11.09
1496.2
70.5
18
1C.93
1493.6
39.6
24
10.78
1492.2
33.4
29
1492.8
37.6
32
1492.5
31. 1
DEPTH TEMP
INTERPOLATED VALUES
SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 13.03 1499.7
10 11.75 1497.6
20 10.88 1493.5
30 1492.7
6C.4 33.445 6.51 0.66 C.878 25.20
67.0 33*466 6.29 0.77 1.330 25.47
37.5 33.557 4.94 1.29 0.798 25.69
35.4 33.592 2.14 1.87 0.822
306
STATION: M6 DEPTH: 40M DATE: 1 NOV 7C TIME: 1225
LAT: 37-37. 5N LONG: 122-40. 2W WIND: 090 SPEED: 6
AIR TEMP(DRY): 66 BARO: 30.06 CLOUD AMT: 6
HEIGHT(FT): 1000 SEA: 090-1 SWELL: 25C-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.430
6.31
0.63
0.631
4
33.416
6.49
0.72
0.597
11
33.450
6.40
0.72
0.933
16
33.469
6.34
0.75
0.641
23
33.539
5.78
1.03
0.652
35
33.598
4.04
1.73
0.6C8
OBSERVED VALUES < SV/T/D-TRANSMI SSOMETER CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
n
12*81
1498:9
62, ?
3
12.83
1498.9
61.6
5
12.62
1499. 1
62.1
10
12.53
1498.6
61.2
15
11.87
1498.2
65.9
20
10.89
1497.3
73.3
25
1495.2
75.2
30
14 93.9
71.9
33
1493.0
32.5
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLOR SIG-T
0 12.81 1498.9
10 12.53 1498.6
20 10.89 1497.3
30 1493.9
62.2 33.430 6.31 0.63 0.631 25.24
61.2 33.445 6.41 0.72 0.885 25.30
73.3 33.509 6.02 0.91 0.647 25.66
71.9 33.573 4.77 1.44 0.626
307
STATION: M7 DEPTH: 31M DATE: 1 NOV 70 TIME: 1342
LAT: 37-37. 5N LONG: 122-36. 5W WIND: LIGHT AIR
AIR TEMP(DRY): 58 BARO: 30. C4 CLOUD AMT: 6
HEIGHT(FT): 1000 SEA: 090-1 SWELL: 250-3
OBSERVED VALUES (NANSEN CAST)
DEPTH
(M)
SALINITY
(0/00)
OXYGEN
(ML/L)
PHOSPHATE
(MG-ATM/L)
CHLOROPHYLL
(MG/M3)
0
33.474
6.57
0.72
0.734
3
33.482
4.37
0.71
0.795
10
33.492
6.47
1.05
0.938
15
33.499
6.43
0.78
1.011
20
33.526
6.55
0.93
0.966
25
33.604
4.37
1.71
1.007
OBSERVED VALUES ( S V/T/D-l RANSMI SSOMETE R CAST)
DEPTH
(M)
TEMP
(C)
SO. VEL
(M/SEC)
TRANSMITTANCE
(0/0)
0
12.-97
1499.7
59c 2
5
12.76
1498. 2
58.2
10
12.50
1498.1
57.6
15
12.49
1498.1
57.6
18
12.44
1498. C
63.0
23
11.85
1496.2
34.3
INTERPOLATED VALUES
DEPTH TEMP SO. VEL TRANS. SAL. OXY PHOS CHLCR SIG-T
0 12.97 1499.7 59.2 33.474 6.57 0.72 0.734 25.24
10 12.50 1498.1 57.6 33.492 6.47 1.05 C.938 25.34
20 12. 2C 1497.3 51.5 33.526 6.55 0.93 C.986 25.43
308
TABLE XEX
PARTICLE SIZE DISTRIBUTIONS
Equivalent spherical diaj:eters in micron;
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1
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Channel
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6
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Channel
10
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Channel
11
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Channel
12
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Channel
13
- 109
309
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359
BIBLIOGRAPHY
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361
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14. Department of Oceanography
U.S. Coast Guard Academy
New London, Connecticut 06320
15. Commander (OMS)
Eastern Area, U.S. Coast Guard
Governors Island
New York, New York 10004
1 6 . Commande r ( OMS )
Western Area, U.S. Coast Guard
630 Sansome Street
San Francisco, California 3412G
17. Naval Oceanographic Office
Attn: Library
Washington, D. C. 20390
18. National Oceanographic Data Center
Washington, D. C. 20390
19. Director, Maury Center of Ocean Sciences
Naval Research Laboratory
Washington, D. C. 20390
20. Mr. Roswell W. Austin
Visibility Laboratory
Scripps Institution of Oceanography
La Jolla, California 92037
21. Mr. Thomas E. Bailey
Central Coastal Regional Water Quality
Control Board
1108 Garden Street
San Luis Obispo, California 93401
22. Captain S. I. Bobczynski
Pacific Support Group
Naval Oceanographic Office
San Diego, California 92152
363
23. Dr. Wayne V. Burt
Department of Oceanography
Oregon State University
Corvallis, Oregon 97331
24. Dr. Peyton Cunningham
Department of Physics
Naval Postgraduate School
Monterey, California 9 3940
25. Mr. Fred H. Dierke
Regional Water Quality Control Board
364 Fourteenth Street
Oakland, California 94612
26. Dr. Siebert Q. Duntley
Visibility Laboratory
Scripps Institution of Oceanography
La Jolla, California 92037
27. Mr. George Eck
Naval Air Development Center
Johnsville, Warminster, Pennsylvania 18974
28. Mr. Gary Gilbert
Stanford Research Institute
Menlo Park, California 94025
29. Dr. Eugene C. Haderlie
Department of Oceanography
Naval Postgraduate School
Monterey, California 93940
30. Dr. R. C. Honey
Stanford Research Institute
Menlo Park, California 94025
31. Professor Alexandre Ivanoff
Laboratoire d' Oceanographie .Physique
de la Faculte des Sciences de Paris
9, Quai Saint-Bernard
Paris (V°) , France
32. Dr. N. G. Jerlov
Institute for Physical Oceanography
Solvgade 83K
Copenhagen, K, Denmark
33. Mr. Kenneth V. Mackenzie
Ocean Sciences Department - Code D50 3
Naval Undersea Research & Development Center
San Diego Division
San Diego, California 92152
364
34. Dr. Robert E. Morrison
AE1
Office of Environmental Systems
NOAA
6 010 Executive Blvd.
Rockville, Maryland 20852
35. Mr. Jerry Norton
Oceanography Department
Naval Postgraduate School
Monterey, California 93940
36. Mr. Larry Ott
Naval Air Development Center
Johnsville, Warminster, Pennsylvania 18974
37. Mr. Robert Owen
U.S. Bureau of Commercial Fisheries
La Jolla, California 92038
38. Dr. John H. Phillips
Hopkins Marine Station
Pacific Grove, California 93950
39. Mr. James Reese
Ocean Sciences Department - Code D503
Naval Undersea Research & Development Center
San Diego Division
San Diego, California 92152
40. Mr. Thomas J. Shoppie
Naval Air Development Center
Johnsville, Warminster, Pennsylvania 18974
41. Dr. E. B. Thornton
Department of Oceanography
Naval Postgraduate School
Monterey, California 93940
42. Mr. S. P. Tucker
Department of Oceanography
Naval Postgraduate School
Monterey, California 93940
43. Mr. B. L. Kolitz
Department of Oceanography
Naval Postgraduate School
Monterey, California 93940
44. Mr. John E. Tyler
Visibility Laboratory
Scripps Institution of Oceanography
La Jolla, California 92037
365
45. Mr. Lowell Van Billiard
Naval Ships Engineering Center
Prince Georges Center
Hyattsville, Maryland 20782
46. Mr. Raymond Walsh
San Francisco Bay Delta Water Quality
Control Program
Resources Building, Room 144
1416 Ninth Street
Sacramento, California 95 814
47. Dr. Hasong Pak
Department of Oceanography
Oregon State University
Corvallis, Oregon 97931
48. Mr. John Arvesen
Mail Stop 234-1
Ames Research Center
Moffett Field, California 94035
49. Mr. Alan Baldridge , Librarian
Hopkins Marine Station
Pacific Grove, California 93950
50. Mi'. Ted Petzoid
Visibility Laboratory
Scripps Institution of Oceanography
La Jolla, California 92037
51. Dr. Gary Griggs
Division of Natural Sciences - II
University of California, Santa Cruz
Santa Cruz, California 95080
52. Director
Moss Landing Marine Laboratories
Moss Landing, California 95039
53. Mrs. Elsie F. DuPre
Oceanography Branch, Optical Sciences Division
Naval Research Laboratory
Washington, D. C.
54. Dr. Rudolph W. Preisendorf er
Department of Mathematics
Naval Postgraduate School
Monterey, California 93940
55. Mr. W. J. Stachnik
Optical Systems
U.S. Navy Underwater Sound Laboratory
Fort Trumbull
New London, Connecticut 0632C
36 6
56. Mr. Raymond N. Vranicar 2
Code AIR-370D
Naval Air Systems Command
Washington, D. C. 20360
57. Mr. Irvin H. Gatzke 2
Code AIR-370
Naval Air Systems Command
Washington, D. C. 20360
58. Dr. H. R. Gordon 1
Institute of Marine Sciences
University of Miami
10 Rickenbacher Causeway
Miami, Florida 33149
59. Dr. Robert W. Holmes 1
Marine Sciences Institute
University of California
Santa Barbara, California 9 3106*
60. Dr. Robert Andrews 1
Department of Oceanography
Naval Postgraduate School
Monterey,- California 93940
61. Coastal Engineering Branch 1
Planning Division
U.S. Army Engineering Division, South Pacific
630 Sansome Street
San Francisco, California 94111
62. Professor Glenn H. Jung 1
Department of Oceanography
Naval Postgraduate School
Monterey, California 93940
63. LCDR Arthur B. Shepard 1
USCGC Burton Island WAGB-283
P.O. Box 20820
Long Beach, California 90801
64. LCDR Elroy A. Soluri 3
USS Beatty (DD-756)
Fleet Post Office :
New York, New York 09 501
65. Professor Eugene Traganza 3
Department of Oceanography
Naval Postgraduate School
Monterey, California 93940 i
66. Department of Oceanography 1
New York State Maritime College
Bronx, New York '
367
UNCLASSIFIED
Security Classification
DOCUMENT CONTROL DATA -R&D
{Security classification of title, body of abstract and indexing annotation muff be entrred when the nvr^t! tmpoti i -. titBttfiti
ORIGINATING ACTIVITY (Corporate author)
Naval Postgraduate School
Monterey, California 93940
2a. REPORT SECURITY Classification
Unclassified
2b. CROUP
3 REPOR T TITLE
A COMPARISON OF OCEANIC PARAMETERS DURING THE OCEANIC PERIOD
OFF THE CENTRAL COAST OF CALIFORNIA
4. DESCRIPTIVE NOTES (Type o/ report and.inclusive dates)
Master's Thesis; March 1971
S AUTHORiSI (First name, middle initial, last name)
Elroy Anthony Soluri, Lieutenant Commander, United States Navy
« REPOR T DATE
March 1971
7/1. TOTAL NO. OF PACES
369
7b. NO. OF REFS
16
l«. CONTRACT OR GRANT NO.
6. PROJEC T NO
9a. ORIGINATOR'S REPORT NUMBERO)
9b. OTHER REPORT NO (SI (Any other numbers that may bo . turned
this report)
10 DISTRIBUTION STATEMENT
Approved for public release; distribution unlimited,
11. SUPPLEMENTARY NOTES
12. SPONSORING MILITARY ACTIVITY
Naval Postgraduate School
Monterey, California 93940
13. ABSTRACT
A detailed examination of the co£istal region between Monterey
Bay and San Francisco Bay was conducted from 1 to 6 November 19 70.
Measurements of temperature, salinity, sound velocity, beam transn
tance, Coulter particle size distributions, chlorophyll a, phosphate,
and oxygen were obtained at 86 stations from the surface to IOC r:
The data collected are presented in the form of contours in horizontal
and vertical sections and depth profiles which indicate:
1. a distinctive off-shore region, which exhibited high values
oxygen, chlorophyll a, and particle count and low values of temperatufj
and beam transmittance v/as present;
2. the areas with the highest standing crop are inshore, within rive
miles of the coast; . ,
3. a peak in the size distribution of particles did not always occur
in the surface layers within the observable range of diameters of rrom
1.59y to 32. Oy;
4. a plot of oxygen versus phosphate yielded a slope or
-2.4
yg-at/1 P04
ml/1 0.
5. there appears to be no simple correlation in the scatter of point
plotted for chlorophyll a as a function of oxygen; and _ ,
6. a Dlot of chlorophyll a versus beam transmittance indicates si
larly that no simple relationship between these parameters exists.
DD,FN0oRvVi473 <PAGE,)
S/N 0101 -807-681 1
UNCLASSIFIED
Security Classification
A-Sl
UNCLASSIFIED
Security Classifirttion
key wo ROS
BEAM TRANSMISSION
CENTRAL CALIFORNIA COAST
CHLOROPHYLL A
COULTER COUNTER
LIGHT TRANSMISSIVITY
LIGHT ATTENUATION
MONTEREY BAY, CALIFORNIA
OCEANOGRAPFIC SURVEY
OXYGEN IN SEA WATER
PARTICULATE MATTER
PARTICLE SIZE DISTRIBUTION
PHOSPHATE
SOUND VELOCITY
SUSPENDED MATERIAL
TEMPERATURE
TURBIDITY
OCEANIC PERIOD
SALINITY
FORTRAN IV OCEANOGRAPHIC DATA
PROCESSING
OCEANOGRAPHIC DATA PLOTTING
DD ,F.T..1473 <back.
UNCLASSIFIED
S/N 0101-807-6621
369
Security Classification
»-Ji
I
The
S66!
c.l
hesi s
S6654 Soluri
28160
Thesi s
S6654
c.l
A comparison of
oceanic parameters
during the oceanic
I period off thfi fc<?n$i%l
coast of Cal i fornla'.o
128160
Soluri
A comparison of
oceanic parameters
during the oceanic
period off the central
coast of California.
m
^.'■•■"■■>.' :t.,.,' -i 'i"'/) 7P:rTv
SllSIBi&SB"
EfiSjSS
thesS6654
A comparison of oceanic parameters durin
3 2768 002 01676 8
DUDLEY KNOX LIBRARY