D 5 i ([<

TP 76-15
Effects of Dredging and Disposal on Some
Benthos at Monterey Bay, California

by
John S. Oliver and Peter N. Slattery

TECHNICAL PAPER NO. 76-15
OCTOBER 1976

DOCUMENT |
COLLE:7 eon]

Prepared for

U.S. ARMY, CORPS OF ENGINEERS

COASTAL ENGINEERING
Ge RESEARCH CENTER

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of J Fort Belvoir, Va. 22060
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The findings in this report are not to be construed as an official
Department of the Army position unless so designated by other
authorized documents.

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1. REPORT NUMBER 3. RECIPIENT’S CATALOG NUMBER
TP 76-15

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Technical Paper

6. PERFORMING ORG. REPORT NUMBER

8. CONTRACT OR GRANT NUMBER(S)

EFFECTS OF DREDGING AND DISPOSAL ON SOME BENTHOS
AT MONTEREY BAY, CALIFORNIA

7. AUTHOR(S)

John S. Oliver
Peter N. Slattery

DACW72-73-C-0010

10. PROGRAM ELEMENT, PROJECT, TASK
AREA & WORK UNIT NUMBERS

9. PERFORMING ORGANIZATION NAME AND ADDRESS

Moss Landing Marine Laboratories
Moss Landing, California 95039
CONTROLLING OFFICE NAME AND ADDRESS

Department of the Army
Coastal Engineering Research Center (CERRE-EC)

Kingman Building, Fort Belvoir, Virginia 22060
14. MONITORING AGENCY NAME & ADDRESS(if different from Controlling Office)

G31266

12. REPORT DATE

October 1976

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Q
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Mt.

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. SUPPLEMENTARY NOTES

- KEY WORDS (Continue on reverse side if necessary and identify by block number)

Benthos (Faunal) recovery rates
Dredging effects Monterey Bay, California
Ecological systems Recolonization rates
Environmental effects
. ABSTRACT (Continue on reverse side if necesaary and identify by block number)
The specific objectives of this study were to document; (a) Natural tem-
poral variations in benthic assemblages and changes related to substrate
Stability, (b) the initial effects of dredging and subsequent recolonization,
(c) the effects of disposal of dredged material on the benthos and subsequent
recovery of the fauna, and (d) the role of faunal distribution and reproduc-
tive abilities upon recovery or recolonization of disturbed areas.

DD , ees 1473 EDITION OF 1 NOV 65 1S OBSOLETE

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The natural benthic assemblages differed with changes in the amount of
sediment movement or substrate stability. Many animals characterized the
relatively stable submarine ridges but few inhabited the unstable terrace
slopes of the submarine canyon in Monterey Bay, California (Monterey Canyon) ;
even fewer animals were found in channeled areas.

Dredging in the channel areas removed 60 percent of the original popula-
tion of bottom animals. After 1.5 years, the number of individuals was low
but the species diversity and evenness indexes were higher than before dredg-
ing.

Disposal of dredged material near the Monterey Canyon head at Moss
Landing, California, removed 60 percent of the individuals. After 1.5 years,
the number of individuals remained low but the species diversity and evenness
indexes were higher than before disposal. Organisms adapted to unstable
bottom conditions survive burial better than others.

The ultimate recovery of a disturbed area depends upon the timing of the
action in relation to the reproductive cycles and distributive abilities of
the benthic organisms in the area. In Monterey Bay, spring and fall are
the most active spawning seasons for many benthic animals; dredging or dump-
ing should be avoided during these seasons.

Underwater disposal of dredged material should be made in unstable bottom
areas if possible.

2
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PREFACE

This report is published to assist coastal engineers in evaluating
the possible effects of dredging and disposal of dredged material upon
benthic organisms. The work was carried out under the coastal ecology
research program of the U.S. Army Coastal Engineering Research Center
(CERC) .

the report was prepared by John S. Oliver and Peter N. Slattery of
the Moss Landing Marine Laboratories, Moss Landing, California, under
CERC Contract No. DACW72-73-C-0010, and was revised for publication by
R.M. Yancey, CERC.

Mr. R.M. Yancey, Chief, Ecology Branch, was the CERC contract monitor
for the report, under the general supervision of Mr. R.P. Savage, Chief,
Research Division.

Comments on this publication are invited.

Approved for publication in accordance with Public Law 166, 79th
Congress, approved 31 July 1945, as supplemented by Public Law 172, 88th
Congress, approved 7 November 1963.

JOHN H. COUSINS
Colonel, Corps of Engineers
Commander and Director

CONTENTS

CONVERSION FACTORS, U.S. CUSTOMARY TO METRIC (SI)

I INTRODUCTION.
II SEDIMENT MOVEMENT AT THE MONTEREY CANYON HEAD .
Summary.
IILI FAUNAL DISTRIBUTION AND SEDIMENT MOVEMENT .
IV REPRODUCTIVE ACTIVITY OF SELECTED INVERTEBRATES .
V EFFECT OF DISPOSAL OF DREDGED MATERIAL ON THE BENTHIC
FAUNA .

1. The Control Area. Sh EAU AES cesta oe ue
2. Experimental Burial of the Benthic Fauna.
3. The Effect of Disposal on the Benthos .

VI THE EFFECT OF DREDGING ON THE BENTHOS .
Introduction.

Ik oer an eee nse neces g
2. The Control and Harbor Stations before Dredging .
5 Sidr, sik Seen

Recovery of the Benthic Fauna .
VII SUMMARY AND CONCLUSIONS .

LITERATURE CITED.

BIBLIOGRAPHY.
APPENDIX
A DEVELOPMENT OF A QUANTITATIVE SAMPLING PLAN .
B SPEGIES sii Sik:

TABLES

Ridge stations of equal depths in order of increasing sediment

stability.

Comparison of fauna at control stations in stable areas with

fauna at canyon stations .
Species at the 20-meter control station .
Species at the 20-meter disposal station.
Species at the harbor station .

Reproductive activity of selected benthic invertebrates

Page

76

16

16
18
tS
25

27

ND ww fF WwW NY Fe

10

11

12

13

14

tS

CONTENTS
TABLES-Continued
Average sedimentological parameters at the three control
stations

Average number of species per sampling period and individuals
per core at the control stations

Effect of experimental burial on benthic fauna.

Effect of experimental burial on benthic fauna.
FIGURES

Moss Landing study area .

Southern branch of the Monterey Canyon head .

Profile of the southern branch along M-3 to N-3 transect.
Profile of the south canyon wall along the P-transect
Settling jar occurrence during study period .

Settling jar occurrence during study period .

Number of species of worm fauna and number of individuals of
worm fauna .

Seasonal peaks of reproductive females and juveniles by
percentages of total population for three amphipod species

Seasonal changes in chlorophyll a at several shallow-water
stations in Monterey Bay, and the mean surface water
temperatures from stations in the central bay and the
range of station means .

Species diversity and evenness for the worm fauna and the
total fauna at the control station

Number of species of total fauna and number of individuals
of total fauna at the 10-meter control station .

Number of individuals of the total fauna and dominant species
at the 20-meter station before and after dumping .

Species diversity and evenness of the total fauna and number
of species of the total fauna.

Species diversity and evenness of the total fauna and number
of species of total fauna.

Mean per core of juvenile bivalves and number of individuals
of the total fauna .

Page

24

28

30

47

48

CONVERSION FACTORS, U.S. CUSTOMARY TO METRIC (SI)
UNITS OF MEASUREMENT

U.S. customary units of measurement used in this report can be converted to metric (SI)

units as follows:

Multiply by To obtain
inches 25.4 millimeters
2.54 centimeters
square inches 6.452 square centimeters
cubic inches 16.39 cubic centimeters
feet 30.48 centimeters
0.3048 meters
square feet 0.0929 square meters
cubic feet 0.0283 cubic meters
yards 0.9144. meters
square yards 0.836 square meters
cubic yards 0.7646 cubic meters
miles 1.6093 kilometers
square miles 259.0 hectares
acres 0.4047 hectares
foot-pounds 1.3558 newton meters
ounces 28.35 grams
pounds 453.6 grams
0.4536 kilograms
ton, long 1.0160 metric tons
ton, short 0.9072 metric tons
degrees (angle) 0.1745 radians
Fahrenheit degrees 5/9 Celsius degrees or Kelvins*

1To obtain Celsius (C) temperature readings from Fahrenheit (F) readings, use formula: C = (5/9) (F — 32).
To obtain Kelvin (K) readings, use forumla: K = (5/9) (F — 32) + 273.15.

EFFECTS OF DREDGING AND DISPOSAL ON SOME BENTHOS
AT MONTEREY BAY, CALIFORNIA

by
John §. Oltver and Peter N. Slattery

I. INTRODUCTION

There have been a number of large-scale surveys of the effects of
dredging and dredged material disposal on benthic communities. Most per-
tinent to this study were parts of multidisciplinary field studies on the
gross physical and biological effects of disposal of dredged material in
the Chesapeake Bay (Virginia Institute of Marine Science, 1967;
Pfitzenmeyer, 1970) and the Rhode Island Sound (Sailia, Pratt, and Polgar,
1972). Additional reviews were presented by Sherk (1971), O'Neal and
Sceva (1971), and Thompson (1973). Sherk and Cronin (1970) published an
annotated bibliography of selected references on the same subject.

Because of the shortcomings of some surveys, the practical problems
encountered, and the limitations of the local situation, a number of spec-
ific objectives and designed sampling procedures were established to
produce detailed answers. A minimum of laboratory work was planned so
that maximum effort could be devoted to field sampling and experimenta-
tion. The development of a quantitative sampling plan (App. A) and
exploration of sampling techniques preceded the study.

The objectives of the study were to:

(a) Document changes in benthic assemblages related to
sediment movement or substrate stability;

(b) document natural temporal variations within a benthic
assemblage and investigate the biological and physical proc-
esses that might explain these variations;

(c) document the initial effects of dredged material
disposal and subsequent recovery of the benthic fauna;

(d) document the sequence of recolonization of a benthic
assemblage within a dredged bottom area;

(e) study the mechanisms controlling benthic recovery and
recolonization, especially faunal distributions and reproduc-
tive abilities;

(f) compare the effect of mass accumulation of sediment
on benthic assemblages adapted to different levels of substrate
stability; and

(g) provide additional information relevant to the planning
of local dredging operations.

For clarification, the events at the dredged harbor station were
separated from those at the station receiving dredged material. Since
disposal did not destroy the whole assemblage, it was referred to as
dredged material disturbance with subsequent recovery. Dredging at the
harbor station removed all the fauna; however, the area was recolonized.

Maintenance dredging of the Moss Landing Harbor was done during
August 1971. A bucket dredge was used to load dredged material aboard
barges that were towed to the disposal area at the Monterey Canyon head
(Fig. 1). About 91,400 cubic meters of material were disposed of in
water depths of 10 to 60 meters. Coarse sand from between harbor jetties
was dredged first; finer sediments were dredged later as dredging pro-
gressed into the inner harbor. From November 1971 to April 1972, "'clean-
up'' dredging operations were performed by the Moss Landing Harbor District,
using a small pipeline dredge. Material was periodically piped to the
end of the Moss Landing Pier and dumped in 10 meters of water. Cleanup
involved less than 9,100 cubic meters of material.

Permanent biological stations were established in the canyon head, on
an adjacent flat bottom, and in the harbor (Fig. 1). Sampling began
before dredging in June 1971 and continued after dredging from September
NOW TeO: ores NOVS-

II. SEDIMENT MOVEMENT AT THE MONTEREY CANYON HEAD

Monterey Canyon is the largest submarine canyon on the west coast of
the United States. Sediment movement at the canyon head, which involves
the dynamics of sediment transport to greater depths, was reported by
Shepard (1948), Charlock (1970), and Arnal (1971). This study was ini-
tiated in 1971 in response to the need for recommendations on optimal
disposal techniques and periods required for a better understanding of
sediment movement in the canyon.

The canyon head is fed by three main branches: (a) The jetty branch,
(b) the main branch, and (c) the southern branch which has several
smaller tributaries. The axis of the southern branch is flanked on the
east by a large submarine ridge with a fairly flat top, located in approx-
imately 15.2 meters of water (Fig. 2). North of this ridge is the main
branch of the canyon head (Shepard, 1948). The main branch is bounded on
the south by a smaller submarine ridge that begins in 18.3 meters of water
and slopes steeply to about 30.5 meters. The primary disposal station for
biological studies (P-3) is located at a depth of 18.3 meters on the shore-
ward edge of this ridge (Figs. 2, 3, and 4). A smaller southern tributary
runs parallel to the main axis to the south, then joins it in about 30.5
meters of water (Figs. 2 and 3). The main branch leads directly to the
head of the Moss Landing Pier. A number of shallow channels or tributarie:
with heads at the shoreward end of the north ridge (Fig. 2), traverse the
north canyon wall of the main axis. The bottom slopes gently to 4.6 or
6.1 meters near the end of the Moss Landing Pier, then dips abruptly to
12.2 meters. A shallow-water terrace up to 6.1 meters high borders most
of the southern branch at these depths (Fig. 2). Its slope ranges from

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Depth Contours in Meters

Scale in Meters

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121°48'

Moss Landing study area.

with circles.

121°47'

Benthic sample stations are marked

Scale in Meters

Bents 13,12, 1|
25 2015 10 5 0 25

Contour Intervals =3m

Bents 19,18

23m
Station

Southern
Tributary

Figure 2. Southern branch of the Monterey Canyon head, based on observations
and measurements by divers along transects. Large circles are
biological sampling stations, and small circles major topographic
measurement stations on the transect grid.

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10 to 50 percent and varies seasonally. Shepard (1948) observed a 50-
percent slope from a similar shallow sandflat on the north wall of the
main branch (Fig. 1).

A Kaiser Company submarine outfall was placed parallel to the terrace
along the edge of the north submarine ridge (Fig. 2). Trenching opera-
tions exposed an underlying, consolidated silt-clay material to depths of
6.1 meters below the existing bottom in some areas. In the main axis,
several silt-clay outcrops were present on the steep part of the north
wall. These outcrops contained a number of living burrowing bivalves, in-
dicating that the outcrops were usually free of sand cover. Vertical
walls of consolidated silt-clay material were also exposed in the main
axis after a sediment slump in October 1972 (Fig. 3). Thus, the head of
the southern branch appeared to be formed of a consolidated silt-clay
material covered to varying depths by fine sand.

Observation dives and sample collections were made between June 1971
and November 1972, using scuba and underwater diver vehicles (Farallons).
Underwater visibility (0 to 1.2 meters) was usually poor. Maximum infor-
mation was obtained on the few days that visibility increased 3 to 7.6
meters.

In late spring of 1972, permanent transect lines were established to
detect changes in gross topographic features and sediment movement.
Transects were marked at 9.1l-meter intervals between permanent stations
by 2.4-meter fence anchors (Slattery and Oliver, 1972), and the distance
from the top of the anchor to the bottom was periodically measured.
Figure 2 was compiled from the diver observations and measurements made
along these transects from April to October 1972.

Seasonal physical changes of the canyon axis and the south canyon wall
were of special interest. To test the dynamic conditions present in the
axis at a 30.5-meter depth, five 0.6-meter fence anchors were arranged in
a straight line across the 10.7-meter width (Fig. 2, line C-3 to P-3),. and
oriented normal to the canyon walls. To test the southern slope condi-
tions, a similar transect was placed at right angles to the contours of
the steep slope south of the P-3 transect line (Fig. 1).

The greatest changes in topography occurred along the shallow-water
terraces (6.1 to 12.2 meters) and in the channeled areas. Submarine
ridges and deeper canyon walls were more stable.

Water depths at the head of the Moss Landing Pier changed from 6.1
to 7.6 meters in the summer of 1972, and 10.7 to 12.2 meters in the fall
and early winter. In the summer the bottom under the pier consisted of
coarse sand; in the fall the surface sand moved away from the pier. The
slope from the end of the pier to the flat part of the canyon floor was
considerably steeper during the summer. In early fall of 1972, three
sand terraces, 0.6 to 0.9 meter high, about 15.2 to 30.5 meters apart,
and arranged perpendicular to the main axis, occurred along this slope.
The activity around the Moss Landing Pier indicated periodic migration
of large amounts of shallow-water sediment into the main axis of the
canyon head.

In September and October 1972, large depth changes in the main axis
of the southern branch (Fig. 3) coincided with the slumping of the
shallow-water terraces above the north wall and at the end of Moss Land-
ing Pier, and activity on the southern wall of the main axis shoreward of
the submarine ridge (Fig. 4). The probable sequence was: (a) Shallow
areas shoaled in calm summer months and sediment accumulated on the walls
and especially in the channels, and (b) rough seas caused sediments to
move down channel, stimulating slumps in deeper channels. The main axis
accumulated more sediment, received more input from shallow water, and
changed in depth more than the other channels.

Sediment input at the canyon head was primarily from longshore drift
and tidal scour of the Elkhorn Slough and Moss Landing Harbor. Fragments
of thallophytic algae accumulated all year but input was highest in the
summer. In June and July 1971, the main axis floor contained a 0.3-meter-
deep mud layer; algal fronds were half-buried in the sediment. Oxygen
concentration was low and the hydrogen sulphide odor was strong in water
samples taken 1.5 meters above the substrate. By September the fronds
had broken into many smaller pieces and were mixed into the sediment.

In December 1971 the floor was covered with coarse sand.

Further evidence of activity during most of the year came from obser-
vations of dredged material deposition. Material was piped to the head
of Moss Landing Pier at three different times during the year. Coarse
sediments accumulated in a pile directly below the end of the pipe, then
slumped into the canyon. During a previous monitoring (Harville, et al.,
1968), the dredged material had been dumped in August 1967 and the piles
had moved completely into the axis by December 1967. Diver observations
revealed a mound of sediment in the axis at a depth of about 30.5 meters.
Material deposited in November 1969 and April 1972 appeared to move with-
in 1 to 2 months.

Shepard (1948) concluded that there was little change in the major
topography of the canyon head since earlier soundings were made by the
U.S. Coast and Geodetic Survey in 1933. Observations in the southern
branch indicated no major changes in the topography described by Shepard.
Thus, main topographic features have appeared stable for the last 40
years.

Summary

a. Sediment and algae accumulation was highest during the calm
summer months.

b. Sediment movement increased in the fall and continued through
the winter into early spring.

c. Accumulation was low in the winter; activity was high.

d. The largest topographic changes occurred during the fall with
the first rough seas.

e. Largest topographic changes also occurred along shallow sand
terraces and in canyon axes.

f. Sediment probably moves by ''creeping'' down slopes, especially
in canyon or axes.

III. FAUNAL DISTRIBUTION AND SEDIMENT MOVEMENT

Barnard (1966) reported a distinct relationship between dominants and
sediment grain size in two adjacent shallow-water communities, and Masse
(1972) described the effect of exposure to wave energy on faunal distribu-
tion. Substrate consolidation is mostly a function of grain size which
is determined by waves moving sediment. Since no attempt was made to
separate these phenomena, sediment movement here refers to the general
instability of a moving substrate.

This section discusses the physical aspects of sediment movement
described previously, and shows the significance of sediment movement in
determining animal distributions.

In addition to the observations and measurements of sediment movement
in the canyon and the routine biological sampling, a sampling line
(transect) was located along the outer end of the Kaiser Company's con-
SERUCtIONMeresitle) (Falg. 2 bents) Zento) 29). ihe transect followed a
gradient of substrate stability on the 18-meter isobath parallel to the
submarine terrace north of the canyon. The seaward end of the transect
(station R19) was on the stable part of the northern submarine ridge.
Shoreward of station R19, stations were adjacent to terrace slopes of
increasing incline and decreasing stability as they approached the area
of large topographic change and sediment activity near bents 18 and 19
(Fig. 2). Because all stations were located at equal depths (18 meters),
the effects of sediment movement could be isolated from other factors
associated with changes in water depth.

One sample (five replicate cores) was taken from each of the four
ridge stations (stations R26 to R29) in December 1972 and abundance
changes of the major groups of animals with increased substrate stability
were noted (Table 1). In a comparison of fauna at control stations (C6,
C10, and C20) with fauna from less stable canyon stations (P6, P10, and
P20), stability was a greater influence on abundance than depth although
there was a gradual but distinct change in the fauna with increasing water
depth (Table 2). Resuspension and migration of sediment caused by wave
action was of major importance in determining animal distributions.

In the canyon head the benthic assemblages changed abruptly in re-
sponse to sediment movement or substrate stability. Many animals charac-
teristic of the control stations were also found on the relatively stable
submarine ridges but few inhabited the unstable terrace slopes; e.g., the
fauna on the flat, stable part of the north ridge (Fig. 2) was more similar
to the assemblage at a comparable depth on the control transect (Fig. 1)
than the fauna on the deeper south ridge (Fig. 2, P-3), which had a

15

Table 1. Ridge stations of equal depths (18 meters)
in order of increasing sediment stability
from left to right!.

Sand dollar

1Mean numbers of organisms per 0.018 square meter
times 10.

Table 2. Comparison of fauna at control stations (C) in
stable areas with fauna at canyon stations (P)
at 6-, 10-, and 20-meter depths.

Fauna C6 P6
(6 m)

Worms

Sand dollars 0 0 280 0 44 0

steeper slope. Fewer animals were found in channeled areas and their
number decreased with increasing sediment movement and accumulation.
Accumulation of both algae and sediment accompained by high decomposition
rates decreased available oxygen and increased hydrogen sulfide concentra-
tion, thereby limiting many benthic animals.

The canyon and control transects had many species in common but the
general composition of assemblages differed (Tables 3 and 4). The number
and kinds of animals at the two shallow-water canyon stations were vari-
able with seasonal lows occurring in winter when topographic changes were
greatest. Most species were present only intermittently; the few con-
stant ones were also found at the same depths on the control transect.

The most convincing evidence of sediment movement as the main factor
controlling benthic faunal distribution in the study area came from the
comparison of ridge stations at the same depth arranged by substrate
stability along the Kaiser Company trestle (Table 1). The total numbers
of worms increased with increased stability. Crustaceans were most
abundant at low and intermediate substrate stability; mollusks were more
abundant with increasing stability.

The distribution and relative abundance of many species were similar.
The worms, Amaeana occidentalis, Nothria elegans, Lumbrineris nr. lutt,
and the crustaceans, Paraphoxus dabotus, Euphtlomedes oblonga, E.
carcharodonta, were characteristic of deeper stations and found in areas
of increasing substrate stability on the ridge. The worms, Dispto
uneinata, Scoloplos armiger, Onuphus ertmita, Paraphyoxus lucubrans,
cumaceans, and the mollusk, Olivella, were characteristic of shallow
stations and found in areas of decreasing substrate stability along the
ridge. The crustaceans, Euphilomedes longiseta, the mollusk, Tellina
modesta, and the common sand dollar, Dendraster excentricus, were charac-
teristic of stations of intermediate depths and found in areas of inter-
mediate substrate stability along the ridge gradient.

The overwhelming trend was for species composition and abundance to
change in a similar manner with stability changes rather than with depth.
Sediment movement was the most important environmental parameter affect-
ing the distribution of macroinvertebrates at the control area and in
the canyon.

Many small crustaceans (amphipods and ostracods) are well adapted to
shifting or gradual accumulation of sediment. They are characteristic
of coarse, unconsolidated sediments (Barnard, 1963; Masse, 1972), but
intolerant of the mass accumulation of sediments in the burial experiment.
The crustaceans' presence at the shoreward ridge stations indicated that
sediment probably did not move in mass slumps; instead, the sediment crept
gradually down adjacent terrace walls, as suggested by Shepard and Dill
(1966), creating an environment to which crustaceans can readily adjust.

No active or passive migration of species characteristic of shallow-
water stations along the control or canyon transects was evident which

17

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19

strongly indicated there was also no occurrence along the north ridge ter-
race. The only exception was the polychaete, Nephtys californtensis, which
lives on the intertidal and very shallow subtidal beach. A few individuals
were found during the winter and early spring only at the shallow canyon
station P-1. The large amount of sediment slumping around the pier and the
proximity of the canyon head to the beach probably explain this seasonal
occurrence. Generally, populations appeared local and immobile within the
confines of the sampling stations.and periodicity.

In summary, benthic macroinvertebrate assemblages in the canyon head
changed, as predicted, in response to changes in sediment movement or sub-
strate stability. A naturally controlled experiment indicated that sedi-
ment movement was also the critical factor determining the distribution
of animals along a gently sloping sand bottom.

IV. REPRODUCTIVE ACTIVITY OF SELECTED INVERTEBRATES

Knowledge of the reproductive activity of the local fauna is essential
to understand natural variations in benthic assemblages, to interpret the
sequence rate and end state of recolonizations, and to increase predictive
abilities.

Reproductive data are from larval settling jars and benthic sampling.
The larval settling jars were similar to those used by Thorson (1946) and
Reish (196la). Widemouthed plastic jars were positioned vertically in a
rack 1.5 meters above the bottom at the 20-meter control station (Fig. 1).
Exposure intervals of 8, 16, and 32 days were tested; jars exposed for 16
days produced more species and individuals. A collection was made every
8 days and the jars with and without sediment added were compared. The
added sediment did not appear to stimulate larval settling. The contents
of each jar were washed through a screen with 0.25-millimeter-square open-
ings, stained with rose bengale, preserved in 10-percent Formalin, and
sorted under a dissecting microscope. Animals were identified, enumerated,
and transferred to 70-percent ethanol and 5-percent glycerin. A thin layer
of particulate material accumulated in the jars in 1 day and was 1 to 4
centimeters thick by the end of 16 days.

Jars were first tested in March and April 1972. Regular sampling be-
gan on 12 September 1972 and ended on 1 June 1973. The three summer months
were not included; however, some information is available on the macro-‘
invertebrates in the benthic samples.

The jars must be considered as selective sampling devices. Animals
may brood their young (many crustacea (amphipods and ostracods) and some
polychaetes (S. arminger)), have a very short or suppressed pelagic larval
stage, or do not settle in jars. The degree of selection is unknown.
Wilson (1951) made numerous laboratory studies of substrate selection by
invertebrate larvae. However, very. little is known about selection under
natural conditions.

20

Gravid (egg-bearing) females and polychaetes and crustacea juveniles
were identified and recorded when found in the benthic samples. Size
measurements and counts were made of males, females, gravid females, and
juveniles of several common amphipod species taken at the control stations.
Larval settling time and growth rates were observed for a few abundant
colonizers at the dredging and disposal sites.

Most of the bivalves that settled in the jars were too small to be
identified to species. Therefore, only the total number of bivalve
individuals per exposure interval was presented. Although settling oc-
curred sporadically throughout the study period (Fig. 5), a larger number
of individuals settled in the winter and in the spring. Most of the
individuals were the juveniles of several species commonly found in fine
sediments. A few adult organisms present were too large and deep in the
sediment to be adequately sampled. A high mortality was caused by
physical events subsequent to larval settling. There was no obvious
indication of predation (e.g., shells with boring), although it was a
possibility.

The reproductive activity for many of the common nonmolluskan macro-
invertebrates is shown in Figure 5. Most of the species of the worm
fauna that settled in the jars were polychaetes. The number of species
was highest in the spring. The large number of individuals in the fall
was primarily due to Capttella capttata; in the spring, Armandta
btoculata and Wephtys cornuta accounted for most of the individuals.

Armandta btoculata had two distinct settling periods, the spring and
fall (Fig. 6). The worms also occurred in large numbers at the dredged
harbor station in late fall 1971, and during March and April 1972 when
the jars were first tested.

Capttella capttata larva settled in large numbers at disposal and
dredged stations in October 1971 and in the jars in October 1972 (Fig. 6).
They had also been present in March and April 1972, but none were found at
the end of the testing on 1 June 1973. Although settling varied during
spring and summer, there was a similarity between the 1971 and 1972 fall
peaks.

Magelona sacculata was the dominant polychaete at the 20-meter control
station. It had a definite pelagic larval stage, but did not settle in
the jars. Large numbers of juveniles were present in the spring benthic
samples (Fig. 7). Presumably, magelonids prefer a sandier substrate and
respond negatively to the fine sediment accumulated in the jars.

Phoronopsts virtdis (phoronid) had many juveniles settle in the jars
and at the harbor station during late March, April, and early May 1973
(Table 5). The spring settling seemed distinct, and agreed with the
findings of Rattenbury (1953).

Reproductive patterns of crustaceans can be determined by examining
egg-carrying females and the size classes in populations. The patterns

2|

30

(eS) oO
N

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| OOO

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(e)
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50

Nov. Dec. ay

Oct.

IQbS)

1972
Settling jar occurrence during study period.

Each bar

represents the number of individuals o species per jar

per overlapping 16-day exposure interval.

Figure 5.

22

100

Nematoda

Individuals

Armandia btoeulata

Capttella capttata

Nothria elegans

Figure 6.

Oct. Nov. Dec. Jan. Feb. Mar. Apr. May
iSia2 1973

Settling jar occurrence during study period. Each bar
represents the number of individuals per jar per over-
lapping 16-day exposure interval.

23

Species

Individuals

50

25

Mean per Core and 95-percent Confidence Interval

150

100

50

Mean per Core and 95-percent
Confidence Interval

Figure 7. Number of species of worm fauna (upper graph) and number of

individuals of worm fauna and Magelona sacculata (upper graph)
at the control station.

24

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25

of the amphipods and ostracods (Euphtlomedes) are seasonal; ovigerous
females are present to some extent all year but peaks of relative abun-
dance occur early in the year (Table 6).

Three species of ostracods, HE. carcharodonta, E. longiseta, and
E. oblonga, were predominantly represented by females and juveniles.
Females of this genus swarm in the water column to mate, chew off the
ends of the bristles on their swimming antennae, and spend the rest of
their lives on the bottom. They brood their eggs mostly through winter
to late spring (Table 6); an influx of juveniles occurs later in spring.
The males are strong swimmers but they die soon after mating (Kornicker,
personal communication), which probably accounts for their low abundance
in the samples.

The peaks of relative abundance of reproductive females of
Eohaustorius senctllus were followed by peaks of juveniles in the next
sampling period (Fig. 8). There was a predominance of reproductive
females in the 2.5- to 3-millimeter size range; few were larger. This
suggests that the females breed once and die. Paraphoxus dabotus and
P. eptstomus seem to follow a similar pattern to that of FE. sencillus
but later in the year (Fig. 8).

Relative abundance of reproductive females was highest in March, fol-
lowed in the next sampling period by peaks of juveniles. Since amphipods
brood their young which are burrowers with relatively immobile females,
an influx of juveniles from another population is not likely. Males are
active swimmers and generally more mobile than females. This may be part-
ly the reason for the 1:20 ratio of males to females. Fecundity is dif-
ficult to estimate because eggs are usually lost from the females marsupium
(egg pouch) during collection. Larger females carry more eggs than the
smaller females. Paraphoxus eptstomus, 5 millimeters long, carry 18 eggs;
the ismalilien stemalesi.5). 5) bom4 amilliaime ters lonicn. acauqinyaar/, stOmlAmemeses
Paraphoxus dabotus, 3 millimeters long, carry 8 eggs. The fairly distinct
peak of reproductive females with a small variation in their sizes (most
P. eptstomus are 3.5 to 4 millimeters; most P. daboius, 3 to 3.5 milli-
meters). The low occurrence of larger females indicate that they pro-
bably breed only once.

The main influx of pelychaete juveniles occurred in the fall and
spring; the main influx of crustacea occurred in the spring. Distinct
winter reproductive activity was apparent for certain species, but settl-
ing of bivalves was more sporadic. Polychaetes are more flexible in their
reproductive strategies than crustaceans or mollusks. A single species
which will often occur over a large geographical range, may be capable of
brooding young in higher latitudes and producing pelagic larvae in warmer
seas.

Many of the polychaetes in the study area are found in deeper parts
of the Monterey Bay (Hartman, 1963; Hodgson and Nybakken, 1973), and
along the coast of southern California (Allan Hancock Foundation, 1965)
and Washington (Lie and Kisher, 1970). In contrast, most of the shallow

26

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(pct)

Paraphoxus eptstomus (|0m)

Juveniles

—— Reproductive Females

(pct)

Paraphoxus dabotus (10m)

Eohaustortus senctllus (10m)

Figure 8. Seasonal peaks of reproductive females and juveniles by
percentages of total population for three amphipod species.

28

amphipod and ostracod species have more restricted distributional pat-
terns.

Thorson (1946) discussed the importance of temperature as a critical
reproductive cue, and the synchrony of spawning with yearly plankton
blooms. The monthly temperature and standing stock chlorophyll values
at several hydrographic stations in Monterey Bay are shown in Figure 9.
Although the chlorphyll data are extremely variable, distinct fall and
spring blooms are common in the bay and at this latitude.

V. EFFECT OF DISPOSAL OF DREDGED MATERIAL ON THE BENTHIC FAUNA
1. The Control Area.

There are no published studies of the spatial and temporal variations
of the fauna within an exposed subtidal sand-bottom community on the west
coast. Barnard (1966) described some shallow-water communities from Santa
Barbara to San Diego but no seasonal data were presented. Many of the
genera and species listed by Barnard were common to this study. Lie and
Kisher (1970) surveyed the benthos off the coast of Washington; the shal-
lowest station was at the same depth as the present study's deepest, but
he had sampled only once. Temporal studies have been made in other benthic
environments on this coast. Jones (1961) studied a mudflat in San
Francisco Bay and found that the variations within that community had no
seasonal trend. Lie (1968) found no such trends in Puget Sound. On the
east coast, Smith (1971) observed no seasonal trend in the changes in com-
munity structure on a bottom similar to that in the present study area.

Masse (1972) investigated the fauna in a number of sand bottoms in
shallow waters (1.5 to 11 meters) in the Mediterranean. He discussed
three major changes that explain the range of variation in quantitative
data: (a) Short-term changes that are often correlated with hydro-
graphic or trophic conditions and affect mainly motile macrofauna with
little effect on biomass; (b) seasonal changes that are correlated with
reproductive and recruitment processes that often vary for different
species and have little effect on biomass; (c) long-term changes that
are correlated with successful recruitment of new or uncommon species
that are irregular and unpredictable events which can affect biomass.
For many quantitative data, sampling error must also be added to the
list; however, this source of variation can be reduced by establishing
permanently marked stations and by prior investigation of sampling meth-
odology, including the detection of gross patchiness or spatial heteroge-
neity of the fauna.

A quantitative sampling plan was developed at the 20-meter control
station in March 1971 and substantiated in March 1972 (App. A). Eight
replicate cores sampled 82 percent of the species of worms present in
28 cores; cumulative species diversity stabilized after 4 to 5 cores.
Samples of 10 replicates from four progressively larger areas did not
differ significantly; the benthos appeared homogeneous along the 20-meter
depth contour. Variation among samples at nearly the same time is a good

2g

50

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Lo))
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= 20
a
=
fo)
= lO
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0
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°
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Figure 9. Seasonal changes in chlorophyll a at several shallow-water
stations in Monterey Bay (upper graph) and the mean sur-
face water temperatures from stations in the central bay
and the range of station means, (lower graph) (from
Broenkow, 1972; Broenkow and Benz, 1973).

30

check on the adequacy of a sampling methodology. Since variation was low
at the 20-meter control station, temporal changes were confidently studied
and partitioned into the three groups proposed by Masse (1972).

Because of the bottom stability and general accessibility of the 20-
meter control station, ancillary studies were made on the vertical distri-
bution of the infauna (Oliver, 1973), the effect of experimental mass
accumulation of sediment, larval settling, and fish predation. Although
the faunal assemblage differed between the control station and the dis-
posal area, it did provide an adequate and important measure of the natu-
ral variations within a benthic assemblage.

The control transect was located perpendicular to the shoreline on a
gently sloping sandflat approximately 1.6 kilometers south of the Monterey
Canyon head (Fig. 1). The transect consisted of three stations at 6-,
10-, and 20-meter depths. Prevailing winds and waves approached from the
northwest, although the largest winter storms often approached from the
south. Currents were primarily tidal, with a net southerly flow. Veloc-
ities often reached 50 centimeters per second (Broenkow and McKain, 1972).
During many low tides a plume of suspended material from the Elkhorn
Slough and Moss Landing Harbor reaches the control area. Turbidity varies
seasonally, and is usually highest in the winter because of storms. The
Salinas and Pajaro Rivers also add a large amount of particulate matter
in the winter rainy season. Yearly temperature fluctuations are presented
in Figure 9. Upwelling in the Monterey Canyon head causes periodic tem-
perature changes in most seasons; a variation of 4° Celsius occurred in
one tidal cycle. The standing stock of chlorophyll in shallow water fluc-
tuates with the seasons. High chlorophyll values occur in spring and
summer; low values in the winter (Fig. 9).

The bottom sediment is mostly fine sand. Seasonal changes at the
beach move sand to depths of at least 10 meters (Fager, 1968; Oliver,
1973). Large waves create a dense layer of suspended sand that oscil-
lates inshore and then offshore. The intensity of movement and resuspen-
Sion of sediments decrease with increasing water depth.

Development of the sampling plan began in March 1971. The first reg-
ular sampling was in July 1971 and the last in May 1973. Generally, 8
replicate cores were taken from each station per sampling period; 10 cores
were taken in March 1972. All sampling was done by divers using scuba.
The corers were 1.4-kilogram coffee cans which were opened at both ends
and could be capped underwater and easily transported. Depth of corer
penetration was 15 centimeters, and the surface area sampled was 0.018
Square meter (15-centimeter diameter). With few exceptions, biological
data are presented as number of animals per core or sample (eight cores).
Ninety-six percent of the individuals were found about 10 centimeters in
the sediment at the 10-meter station, and 93 percent (excluding one
species) at the 20-meter station (Table 3). Samples were washed through
a 0.5-millimeter mesh screen. The residue was stained with rose bengale
and preserved in 10-percent Formalin. All animals were sorted from the
debris under a dissecting microscope, transferred to 70-percent ethanol

3]

and 5-percent glycerin, and identified to the lowest possible taxon; the
number of individuals per taxon was recorded for each core.

One sediment sample per sampling period was taken at each station.
Median diameter, sorting (Folk and Ward, 1957), and percent sand and silt
were computed using Emery's (1938) tube analysis. Total carbon was meas-
ured by a Leco Carbon Analyzer (Table 7).

Table 7. Average sedimentological parameters at
the three control stations.

Stations
Parameter 6 m 10 m 20 m
Pet carbon 0.08 0.08 OR
Pet sand 9768 90.4 QBs
Pee sake Boll 9.6 Teas
Sorting 0.41 0.44 0.40
__ Median grain size 0.11 O99 0.95

Biomass was estimated because of the shallow penetration (15 centi-
meters) and the small area sampled (0.018 square meter) by the corers.
Large animals have the most effect on biomass; they are more widely dis-
tributed and live deeper in the sediment (Holm, 1964; Masse, 1972; Smith
and Howard, 1972; Oliver, 1973). At the 10-meter control station, 54
percent of the biomass was above 10 centimeters in the sediment; 95 per-
cent was above 20 centimeters (from the top 50 centimeters) of the sedi-
ment (Oliver, 1973). At the 20-meter control station, 39 percent was
above 10 centimeters and 61 percent above 20 centimeters.

For brevity and clearness, a number of groups were classed under
"worms''; over 80 percent of the species and individuals of the worm fauna
were polychaetes. The taxa were grouped because of their obvious morpho-
logical and ecological similarities (App. B).

The number of species (lowest taxon) was presented in two ways: (a)
The total number of species per sample (usually in eight replicates), and
(b) the mean number of species per core (0.018 square meter) with 95-
percent confidence intervals. These are two distinct parameters, but
they generally follow the same trend. The number per core gives a meas-
ure of variation.

Species diversity was measured by Shannon and Weaver's (1963) equation;

evenness by J (Pielou, 1966). Both were computed for the total sample
(Peterson, 1972):

32

Species diversity = H'' = Y — log —

i=1 N .
S = total number of species
; ath 3
ny = the proportion of the i species
N = total number of individuals
Hmax = natural log of S.

Evenness = J = H"/Hnax

The most important environmental parameters along the control transect
are related to wave action. Grain size increases and substrate consolida-
tion decreases with increasing wave action. Movement or resuspension of
sediment is undoubtedly the most significant ecological factor. Sediment
Stability effects species composition and abundance.

The 6-meter station was located near the edge of a large bed of the
common sand dollar, Dendraster excentricus. The bed moved inshore and
offshore in response to wave action. Adult sand dollars were present at
the shallow station during certain times of the year; juvenile sand dol-
lars (1 millimeter) occurred sporadically in relatively large numbers at
the two deeper stations.

There was a distinct change in sediment stability between the 10-
and 20-meter depth and a consequent change in the fauna. The composition
of deep sediment strata changed; substrate consolidation and the vertical
distribution of the infauna increased (Oliver, 1973). The number of per-
manent tube and burrow-dwelling animals and the commensals living in the
burrows and tubes of other animals (e.g., pinnotherid crabs and scale
worms) increased with increasing water depth. The permanent tube and
burrow inhabitants included many polychaetes and Calltanassa. In addi-
tion, a number of large bivalves that live deep in the sediment were also
present at the 20-meter station. The gaper clam (7resus) was the most
conspicuous. Maximum density was reached in 30 meters of water; only a
few individuals were found in water shallower than 15 meters. Tresus is
a sedentary suspension feeder which is intolerant of scouring, deposition,
and resuspension of coarse sediment in shallow water.

The crustaceans were dominant at the two shallow stations (Table 8).
These were mostly small amphipods and ostracods that are motile and bur-
row in the top few centimeters of sediment. At the 20-meter station, the
worm fauna dominated; this trend also continued into deeper water (Oliver,
UO7S))

Most of the mollusks were juveniles of the bivalve, 7. modesta (1 mil-

limeter). A number of other species of juvenile bivalves were present as
transient, sporadic members of the assemblages and suffered high mortality

33

Table 8. Average number of species (S) per sampling
period and individuals (N) per core at the
6-, 10-, and 20-meter control stations.

72
S

Sal 56 Ze 17
A: 22 14 Zi

Fauna

6m
34
10

Crustaceans

N
S
Mollusks N 3 6 35 Zak 30 24
S 5 19 al 22 13 19
Worms N 10 Pal 37 23 75 59
S 12 44 28 56 41 60
Total N 163
S 50

after settlement. The rare adult bivalves were usually found at the 20-
meter station.

The 10- and 20-meter control stations were characterized by W. elegans.
Euphtlomedes spp. and Paraphogzus spp. were codominants with W. elegans at
the 10-meter station; Magelona spp. was codominant with W. elegans at 20
meters. Adult Tellina were rare; they were common in a shallow (16 meters)
area studied in the north Monterey Bay (Watson and Stephenson, 1972). The
6-meter station was characterized by small crustaceans and D. eccentricus.

Barnard (1963) found that crustacean abundance increased to a depth
of 60 meters and was more abundant in deeper water; however, a benthic
survey of the north Monterey Bay (16- to 60-meter depths) indicated that
crustacean density was highest at the shallowest station sampled (Hodgson
and Nybakken, 1973). At the control area, crustaceans were more abundant
at the 10-meter station. Lie and Kisher (1970) and Masse (1972) also
found a greater number of crustaceans in considerably shallower water
than Barnard (1963) did. In addition, the number of crustaceans per meter
square at the control area was an order of magnitude greater than that
reported by Barnard.

Lie and Kisher (1970) and Masse (1972) noted the same general increase
in crustaceans and decrease in worm fauna in shallow water that was ob-
served along the control transect. The primary reason for this separation
is the physical stress created by wave-induced sediment movement. Tubes,
burrows, and other structures are difficult to maintain in shallow water.
Sediment stability allows an increase in habitat diversity, which probably
accounts for much of the increase in species from the shallow to deeper
stations.

The dominant crustacean at the 20-meter control station was P. dabotus.
There was a highly significant correlation (r = 0.89, p 0.001) between the
number of P. dabotus and the total number of individuals. The correlation

34

between the number of species and individuals was not significant

(r = 0.50, 0.1 < p > 0.05). Paraphoxus dabotus was a persistent member

of the assemblage and the dominant crustacean in every sampling period,

but there was a fairly distinct seasonal trend. The numbers of species

and individuals decreased toward the winter and increased in the spring.
Paraphoxus dabotus breeds year round and has a reproductive peak in spring.
Most individuals probably live only 1 year.

The only echinoderm present was D. eccentrtcus which was represented
only by occasional juveniles and is not included in the total fauna anal-
WSLS

The dominant mollusk was 7. modesta. There was a significant correla-
tion between the total number of individuals and the number of 7. modesta
(r = 0.91, < p > 0.001), and between the number of species and individuals
(vr = 0.76, 0.01 < p > 0.001). The only discrepancy was in September 1971
when Protothaca staminea were as abundant as T. modesta. The P. staminea
were gone by the next sampling period. Tellina modesta abundance through
the year characterizes the general temporally sporadic density of juvenile
bivalves in the study areas. Again, the largest part of the individuals
were juvenile bivalves.

Over 80 percent of the worm fauna were polychaetes. The dominant
species was M. sacculata with the highest number of species and individ-
uals in summer. There was no seasonal trend in species diversity or
evenness in the worm fauna (Fig. 10). Both parameters remained relatively
stable through time. The high diversity in October 1972 was primarily due
to a large decrease in density; the number of species stayed fairly con-
Steme CPiess 7 eaovel 10),

Species diversity was not computed for the other parts of the fauna
because the numbers were too small.

Polychaetes dominated the 20-meter control station (Table 8).
Magelona sacculata, N. elegans, Lumbrinerts lutt, Prinospto pygmaeus,
P. etrrifera, and Haploscoloplos elongatus were common persistent members
of the worm fauna. An average of 80 percent of the species had an abun-
dance of less than two individuals per core. Seasonal changes in relative
abundances were much greater than changes in species composition (Table 3).
Many species were found in all the sampling periods. A notable exception
was the large terebellid polychaete, A. occtdentalis, which was common
after June 1972, but had not been found before then.

At the 10-meter station, the worm fauna accounted for 60 percent of
the number of species and individuals. Changes in the number of species,
number of individuals, species diversity, and evenness for the total fauna
(Figs. 10 and 11) were similar to changes in the same parameters for the
worm fauna (Figs. 7 and 10). The seasonal trend in the number of species
and individuals was observed for the total fauna (Fig. 11), and species
diversity was fairly constant (Fig. 10). The low values in July 1971
cannot be explained without samples from previous seasons.

35

H” (diversity )

| J (evenness )

ge ee a 6 ee ©) aa

Calculated Values

H' (diversity )

Calculated Values
ine)

J (evenness )

oe ee ees oi

a
®
ip)
197 |

Figure 10. Species diversity and evenness for the worm fauna (upper
graph) and the total fauna (lower graph) at the control
station.

May

36

-_—_ =
= a
50 . Ss

; : age Sa.
a oe

Mean per Core and 95-percent Confidence Interval

300

290

200

Individuals

150

100

Figure 11. Number of species of total fauna (upper graph) and number
of individuals of total fauna (lower graph) at the 10-
meter control station.

37

Short-term changes and cause and effect relationships were the most
difficult to detect. Seasonal changes were distinct. Similar seasonal
phenomena were also observed at the shallower stations. Reproductive
cycles, recruitment processes, and natural mortality explain the general
trends. Adverse physical conditions increased mortality and restricted
recruitment during winter months. Winter recruitment was probably more
successful in deeper water, where wave action had less effect on substrate
stability. Thus, physical and biological conditions were both important
in determining the observed seasonal variations.

Long-term changes were also observed. The most noteworthy was the
successful recruitment and persistence of A. occetdentalts from June 1972.
Another factor that caused long-term irregular variations in the fauna was
yearly changes in climatic conditions. These irregular changes favor the
successful recruitment of different species at different times. Milder
conditions during the first year caused less mortality and spring recruit-
ment was high.

Significant correlations between dominant species and number of indi-
viduals indicated that dominants were of major importance in determining
the variations. However, at the same time significant correlations be-
tween the number of species and individuals indicated a general increase
in mortality and recruitment of all species.

The decrease in the number of species with decreasing depth and in the
number of species and individuals during winter months suggests that these
assemblages are primarily physically controlled (Saunders, 1968).

De Experimental Burial of the Benthic Fauna.

The 20-meter control station was located on a relatively stable, flat
bottom (Fig. 1). The benthic population at this station consisted of
small epifauna and shallow infauna. To test the effect of burial under
controlled conditions, bottom areas were experimentally buried on two
occasions near the 20-meter control station (Fig. 1).

Two open-ended sheet metal frames 1.5 by 1.5 by 1 meter high were
pushed 0.5 meter into the sediment. Each enclosed a 2.25-square meter
bottom area. Sediment, which was devoid of animals, was dumped into the
framed areas until a 15-centimeter layer covered the old substrate. The
first frame was positioned on 26 August 1972; the second on 3 May 1973.

Coarse beach sand (median diameter 0.32 millimeter) was placed in the
first enclosure in August 1972. Six small cores (7.5-centimeter diameter,
30-centimeter height) were taken at various times from the experimental
area during the 2 weeks following burial, and one large core (15 by 30
centimeters) at the end of 3 weeks (Table 9). The cores were partitioned
at the interface of the old and new sediment and processed.

38

Table 9. Effect of experimental burial on benthic fauna!

Fauna Buried enclosure
(od 7)

Crustaceans and mollusks

Ne 0

S 0
Worms

Ne 63

S 20
Nematodes

Ne 25

S NA2
Medtomastus cali forntensts

Ne 12
Prionospto ctrrtfera

Ne al
Nothria elegans

Ne 9
Gyptis brevtpalpa

Ne 4
Notomastus tenuts

Ne 1

Control

(n

= 10)

LSS
24

125

60

52

1

Iaverage number of individuals per 0.018-square meter
core (Nc) and total number of species (S) are given
for the enclosure buried August 1972 and for the

nearby unburied control area.

2Not available.

SS)

Fine sand (median diameter 0.111 millimeter) was dumped into the
second enclosure in May 1973. After 1 day, the new bottom was still 15
centimeters above the old; by the third day almost all of the introduced
sediment had been scoured out of the enclosure and the original bottom
was exposed. The scouring was probably the result of rough seas and use
of finer sediment than that of the first experiment. Five days after
burial, five cores (15 by 15 centimeters) were taken from the second
experimental area, and one from the nearby unburied control area.

Both experiments were concerned with the immediate effects of heavy
sedimentation or burial on the benthic fauna. The introduced sand layer
in the first enclosure remained intact for the 3-week observation period;
the fauna in the second enclosure was buried only 2 days. Since the
experimental conditions were not the same, each enclosure is discussed
separately.

The first enclosure was observed 24 hours after the initial burial.
A large specimen of Callianassa sp. (ghost shrimp) and one Solen stcarius
(razor clam) were found on the surface of the introduced sediment. In
addition, the tube-dwelling polychaete, W. elegans, had burrowed through
the coarse sand and constructed new tubes from it. Wothria elegans was
one of the few animals whose abundance was not decreased by burial (Table
1); it is also a dominant large polychaete (5 to 15 centimeters long) in
water depths from 10 to 30 meters on the open coast of central and south-
ern California (Barnard, 1963).

Specimens of the gaper, Tresus nuttallit, had extended siphon holes
to the surface of the introduced sediment, similar to those described for
the mahogany quahog, Arctica islandica, after burial by 9 to 17 centimeters
of sediment (Hale, 1972). Neither the gapers nor the quahogs had moved up-
ward. Sailia, Pratt, and Polgar (1972) concluded that slow sedimentation
would probably not endanger mahogany quahogs.

The first enclosure data are presented in Table 9, and were compared
to samples taken from undisturbed control areas in July and August 1972.
All of the small crustaceans and mollusks were killed by burial. They
were found dead at the old bottom surface.

Compared with the control, 66 percent of the worm species and about
50 percent of the individuals were killed by burial (Table 9). Polychaetes
were the dominant group of worms. There were more nematodes in the exper-
imental area than in the control area. All of the animals that survived
the burial are commonly found in lower sediment strata.

There are several animals characteristic of lower strata. Two poly-
chaete worms, WV. elegans and Magelona spp., are active at the sediment
surface, live in vertical burrows, and withdraw deep into the sediment
when disturbed. Consequently, they were often recorded in lower strata;
however, their reactions to burial are different. Wothria elegans ad-
justed to the accumulation of sediment but the magelonids suffered a 90-
percent mortality.

40

In addition to those animals that use the lower strata as a refuge,
some are commensals in the tubes and burrows of other organisms. Deep-
living commensals must be able to withstand the physical conditions in
lower strata, but probably have limited burrowing abilities. They may
tolerate a short-term burial, but may be incapable of vertical migration.
Prinospto ctrrifera was commensal in the burrows of Calltanassa sp.
(Oliver, 1973), and survived burial.

Several of the species actively burrowed into the lower strata. Some
were usually below 10 centimeters (e.g., Notomastus tenuts), but most
species were more common nearer the surface. Larger species or larger
individuals of these species were generally found deeper in the sediment
(Smith and Howard, 1972; Oliver, 1973); however, there were exceptions.
One of these Mediomastus californiensts, a small capitellid polychaete
worm, occurred deep in the sediment.

Low oxygen concentration, low interstitial water content, increased
compaction, and high-reducing conditions result from burial, and are
characteristic of lower sediment levels.

The bottom in the second enclosure was buried for only 2 days. Data
from the five cores taken inside the enclosure, and cores from the control
area are presented in Table 10.

Table 10. Effect of experimental burial on benthic fauna! .

Fauna Buried enclosure Control
(a = 5) @ 2 2)

Crustaceans and mollusks
Nc

Sc

St

Total fauna
Ne 55 110

Sie 17 30
SE 36 73

laAverage number of individuals per 0.018-square meter
core (Nc), average number of species per core (Sc),
and total number of species (St) are given for the
enclosure buried May 1973 and for the nearby unburied
control area.

Larger animals were able to withstand the short-term burial better
than smaller ones. About 82 percent of the individuals and 69 percent of

4|

the species of crustaceans and mollusks were killed by the burial (Table

10). Percentages are based on a comparison of sample from the enclosure
and control stations. Survivors in these groups were all larger individ-
uals.

Worm mortalities were again low. About 34 percent of the number of
individuals and 39 percent of the species were killed (Table 10). Most
of the larger worms lived after burial; mortality was higher for smaller
Species and individuals. Very few juveniles. of polychaete worm, Magelona
sacculata, and no specimens of the polychaete, A. occidentalis, were pre-
sent in the enclosed area, yet they were common outside.

Two polychaete worms, M. caltforntensts and P. cirrifera, survived
the burial and their numbers remained similar to those of the control
Stations. They also tolerated burial in the first experiment (Table 9),
and were common below 10 centimeters in the sediment.

In both experiments, members of the worm fauna (primarily polychaetes)
were least affected by burial. Survival was highest in the active bur-
rowers, and especially those active burrowers common in lower sediment
strata. Small species and individuals of larger species were generally
less tolerant of burial. The only exceptions were inhabitants of the
lower strata. Surface-dwelling crustaceans and mollusks were most af-
fected by the deposition; all died in the first experiment.

Capability to withstand burial can be predicted by animals’ morphology,
behavior, usual vertical distribution in the sediment, and stability of
the substrate inhabited. These experiments present new information and
agree with the review presented by Sailia, Pratt, and Polgar (1972).

At the disposal site (canyon head), the fauna is adapted to a larger
amount of seasonal sediment movement. The dominant animals were active
deposit-feeding polychaetes that apparently restricted the presence of
small crustaceans and mollusks. The disposal caused a 60-percent reduc-
tion in the number of individuals and an 8-percent reduction in the number
of species. On the stable flat bottom, 50 percent of the individuals and
66 percent of the species were killed by the first experimental burial.
The two locations were subjected to different types of deposition, but
the data are still comparable. Canyon fauna is much better adapted to the
effects of mass accumulation of sediments. Investigations have involved
only the shallow canyon head, and do not necessarily apply to deepwater
assemblages.

Se wine Ethece Ot: Disposal on the Benthos.

The effect of dumping dredged materials on the benthos was reported by
O'Neal and Sceva (1971) and Sherk (1971). Sailia, Pratt, and Polgar (1972)
reviewed the most pertinent studies. Where disposal did create a contin-
uous stress and the toxic content was low, recovery of the benthos was
completed within 1 to 3 years (Virginia Institute of Marine Science, 1967;
Harville, et al., 1967; Pfitzenmeyer, 1970; Sailia, Pratt, and Polgar,
1972)\..

42

This section deals primarily with the 20-meter canyon station, which
received most of the dredged material. It describes the effect of dumping
on an assemblage adapted to conditions of natural sediment movement and the
details of recovery.

Stations (Fig. 1) were marked with permanent buoy systems (Slattery
and Oliver, 1972). Major disposal occurred in August 1971. Twelve
samples of eight cores each were taken between July 1971 and April 1973.
Two predisposal samples of eight replicate cores each were taken on 14
July 1971, the first postdisposal samples on 6 September 1971, and the
last two samples on 4 April 1973. Sample replication in July and April
is presented as a measure of spatial variation within the 20-meter sta-
tion. Sampling dates are shown in Figure 12.

The benthic assemblages at the 20-meter station were dominated by two
species of capitellid polychaetes, Heteromastus filobrachus and Capttella
capttata. The C. capttata were mostly large adults. Heteromastus
ftilobrachus were commonly found in the longshore submarine canyon by
Hartman (1963). Both animals are deposit feeders that do not maintain a
permanent burrow system. Permanent tube or burrow dwellers present were
the polycheates, M. sacculata and N. elegans. Mollusks and crustaceans
were scarce (one or two per core). Thus, the benthos consisted primarily
of an active burrowing deposit-feeding assemblage of polychaetes.

Approximately 0.26 meter of dredged material was deposited at the 20-
meter station. Fine sands were dredged and dumped first; muds were last.
Median particle size of the bottom sediment changed from 0.212 millimeter
before disposal to 0.111 millimeter soon after disposal (September 1971),
total carbon from 0.13 to 0.64 percent by weight, sorting from 0.51 to
ORS7 7 "and silt from/07.8 to 22.2 percent. Im November) 1971.) 0.26 meter
of sand moved over the station from shallow water. Most of the finer
dredged material was transported to deeper water, but some was covered by
sand. A mud layer of varying thickness was present below this. The layer
was not observed 2 months later. Changes in topography caused by the
disposal probably allowed more sand than usual to move over the station.
Sediment parameters changed little during the remainder of study. Average
median particle size was 0.125 millimeter, total carbon 0.12 percent, sort-
ing 0.45, and silt 8.5 percent. Bottom surface level was relatively stable
during the 1972-73 winter.

Disposal caused approximately a 60-percent reduction in the number of
individuals. No large C. capitata were found in September 1971, but a
number of small individuals had settled. By October 1971, the density of
small C. capttata was 200 per core. Capitella capttata also settled in
large numbers at the dredged harbor station in October 1971 and in the
settling jars in October 1972. In November 1971, they were found in dense
patches that caused the high variation in the data that month; by January
1972 they were gone.

Capttella capttata is a well-known opportunistic species which appears
in disturbed areas where competition is low (Hutchinson, 1951; Margalef,

43

Individuals

2,000

1,500

|,000

500

Ealotne 2.

——

July

\
\

Phoronopsis \ /

/
Wells “Sy ; Na
/ el Nee Armandia ‘ Ny

Ai Bias Control
Wo. es Capttella Rew
0 ie ial ~~ -
= > c y = a oO
(ob fF = o [oe
86 = S = a a =
1971 1972 | 1973

Number of individuals of the total fauna and dominant
species at the 20-meter station before and after dumping
(arrow indicates dredging).

44

1963; Connell, 1972). It has a short reproductive cycle (1 month) and
probably has poor competitive and high dispersal abilities (personal
communication, Dr. Reish, Long Beach State College, 1972). The worm is
often found in polluted marine harbors, near sewage discharges, and in
other areas of natural or unnatural stress (Reish, 1955, 1957; Felice,
1959; Rosenberg, 1972); it is also common in the mudflats and muddy bot-
toms in Elkhorn Slough and Moss Landing Harbor.

The dredge spoil disturbance caused a slight drop in the number of
species. During recovery the total number of species rose to a high in
June 1972, and decreased steadily thereafter. The number of species and
individuals at the control (Fig. 11) and the dredged harbor stations (Figs.
12 and 13) were also highest in June 1972. These June peaks may be related
to seasonal or possibly long-term variations rather than any time sequence
characteristic of recovery. The sequence and rate of recovery (or recol-
onization) are probably a function of the initial time of exposure and the
particular set of ecological conditions present during the recovery pe-
riod.

During recovery, species composition was more stable than relative
abundance. The common species and their abundances for each sampling
period are listed in Table 4. Mollusks and crustaceans were irregular
members of the assemblage; many of the worm species were present through-
out the study period.

In June 1972, the polychaete worm, A. occidentalis, settled at the
disposal and control stations. It was uncommon at both locations before
June, but was more abundant later at the disposal station. This large
terebellid polychaete lives in a Semipermanent U-shaped burrow, and is
capable of burrowing deep into the sediment. Its tentacles are usually
spread just below the bottom surface and their expanded distal ends extend
into the water colum.

Changes in species diversity and evenness followed a trend similar to
that for the number of species (Fig. 14). Disposal had little effect on
their values. The bloom of Capttella in October 1971 lowered evenness
and consequently diversity. Both parameters increased until June 1972.
After the dumping, density was much lower (Fig. 15), but the dominants
accounted for a similar percentage of the total. In June, no dominant
mollusks (Fig. 15) were present and the number of species was highest
(Fig. 14). A large population of juvenile Tresus settled in December 1972
(Fig. 15), and both parameters decreased (Fig. 14). The combination of
an increase in the number of species and a decrease in the abundance of
the two predisposal dominants Heteromastus and Capttella, caused evenness
and diversity to increase. Thus, recovery from disposal resulted in a
more diverse fauna, although an earlier large decrease was observed be-
cause of the large number of juvenile Capitella. This general increase
in diversity is undoubtedly related to the increase in substrate stability
and structural diversity due to the presence of Amaeana.

45

20

2.0

Calculated Values

Control
fo}

R
Lo
60 ae
/ \
/ \
Le \
/ \
F ¢ \ 2
Total Species per Sample,’ ‘ y,
yf \ Va
i} \ Bk
/ \ 7
/ \ ee
40 |
/ Veale
IN /
2) LN /
2 ee /
ra vs wey Control
® / \ / @
Qa e N\
/
wn g i
/
/
20 /
Soap Mean per Core and Range Control ¢
WW
0
> ianeeeess = L = a © L
= CIS S) is) S 5) CB) ® a
= On On >) = =) (ep) a) <a
1971 1972 | 1972
Figure 13. Species diversity and evenness of the total fauna

(upper graph) and number of species of the total fauna

(lower graph) (arrow indicates dredging).

46

Species

Figure 14.

BetFSsaq, e

2 eres Whee wee
= Deca aie He (diversity ae
i a r)
= 2 /

/
Gs) /
@ es /
= 5 aa dh
S| we
3S \ e
Ss ee J ( evenness )

Mean per Core and 95-percent Confidence Interval

Species diversity and evenness of the total fauna
(upper graph) and number of species of the total fauna
(lower graph) (arrow indicates disposal).

47

Individuals

300
200
3S
2
2
100
Figure 15.

Mean per Core and 95-percent Confidence Interval

\ Mean per Core of 4. ftlobranchus

Mean per core of juvenile bivalves (upper graph) and number
of individuals of the total fauna and Heteromastus
fitlobranchus (lower graph) (arrow indicates disposal).

48

About 1.5 years after disposal, the number of individuals was still
60 percent lower than before disposal. This reduction was as great as
that immediately after the disposal (Fig. 15). The number of species and
species diversity and evenness were considerably higher (Fig. 14). There
was little change in biomass because of the large terebellid, A.
ocetdentalts. These results were different from those reported by
Pfitzenmeyer (1970) who studied the recovery of a disposal site in an
estuarine environment. He concluded that after 1.5 years the same species
reestablished in the disposal area, and biomass and species diversity were
similar to predisposal levels. The general pattern of recovery in the
present study was similar to that observed by Sailia, Pratt, and Polgar
dig72).

Paine (1966) and Dayton (1971) described the effect of biological and
physical disturbances increasing diversity in rocky intertidal communities
after clearing space occupied by the competitive dominant. Dayton and
Hessler (1972) discussed the role of disturbance in maintaining high div-
ersity in the deep sea. In contrast, Deevey (1969) reviewed the negative
correlation between disturbance and evenness; in southern California,
Peterson (1972) experimentally disturbed bivalve assemblages and reduced
evenness.

No general trend exists between disturbance and species diversity or
its components. Sampling over a large disposal area, Sailia, Pratt, and
Polgar (1972) reached the same conclusion in relation to disturbance of
the bottom by dredged material dumping. In the present study, dredged
material disturbance reduced the numerical dominants (and possibly com-
petitive dominants); species richness and evenness increased during re-
covery. The bottom consisted of fine sand. Although turbidity is generally
high, strong tidal currents flush the channel several times a day, keep-
ing the bottom free of fine sediments and stagnant water. Current veloc-
ities often exceed 100 centimeters per second. The average water tempera-
ture was 13° Celsius (range, 9° to 17° Celsius, and salinity varied from
31.5 to 33.8 parts per thousand with a mean of 33.4 parts per thousand)
(Broenkow and Smith, 1972).

In July 1971, two samples of eight replicates each were taken from the
harbor station before dredging; the fauna at the control and dredge sta-
tions were similar. Individual species (three capitellid polychaetes and
one oligochaete) (Table 5) were dominant. The dominant polychaete was
Notomastus tenuts, which was also dominant in the mudflats of lower E1k-
horn Slough and in the north harbor. The oligochaete occurred in the
highest numbers, but represented less than 5 percent the biomass of
N. tenuts.

Two species of large bivalves dominated the biomass. The bent-nosed
clam, Macoma nasuta, which is an active suspension and deposit feeder,
was more numerous than the large suspension-feeding gaper clam, Tresus
nuttalltt. Both animals live in the lower intertidal mudflats to water
depths of a least 40 meters. Because the gaper was uncommon, essentially
sedentary, and lived deep in the sediment, it probably had little direct
effect on community structure.

49

VI. THE EFFECT OF DREDGING ON THE BENTHOS
1. Introduction.

There are few studies of community development in unconsolidated
marine sediment. Reish (196la, 1962, 1963) observed no obvious sequence
of colonization in recently dredged boat harbors in southern California.
The principal species were present during the entire study period.

Sailia, Pratt, and Polgar (1972) described a general pattern of coloniza-
tion for the Rhode Island Sound disposal area that was similar to the dis-
posal area in this study. Species arrived in order of their power of dis-
persal. Motile animals moved in first, and within a year nonselective
larvae of opportunists settled.

Migrations of animals into the dredged and the disposal areas at
Moss Landing were not observed. Larvae of opportunists were the first
to settle in the dredging and disposal areas, although at the disposal
station their numbers were apparently restricted by the presence of ani-
mals that survived the dumping.

There is no evidence that opportunists alter or prepare the environ-
ment for later species. Evidence does support Connell's (1972) argument
that the sequence is related to life history characteristics of oppor-
tunists and dominants rather than site modification by pioneers.

2. The Control and Harbor Stations Before Dredging.

A permanent station was located in 6 meters of water along the edge
of the Moss Landing Harbor entrance channel (Fig. 1) where dredging
occurred. The middle of the channel was not dredged in this part of the
harbor; the area served as a control station about 25 meters from the
dredged station.

In summary, before dredging the harbor station and control were in-
habitated by a deposit-feeding assemblage of active, burrowing infauna.

The dominant species are listed in order of abundance in Table 5.

3. Recovery of the Benthic Fauna.

The harbor station was dredged in late August 1971. The bottom was
dredged 1.5 meters below its original level, exposing patches of clay
that were gradually covered by fine sand from the steeply cut channel
wall. The first postdredging sample was taken on 12 September 1971; the
last ones on 2 April 1972. Lateral movement of fauna into the dredged
area was slight and restricted to large mobile epifauna (decapods and
gastropods), and possible some bivalves (Peterson, 1972).

Eighty-six percent of the total number of individuals were removed by
the dredging. Most of the specimens taken in September 1971 were recently
settled A. bioculata (polychaete), and some oligochaetes. The dominant

50

deposit-feeding capitellids and bivalves were absent; the biomass was
drastically reduced.

In October 1971 the polychaetes, A. bioculata and C. capitata, settled
in large numbers. Both animals have a larval settling peak in the fall,
are small (1 centimeter) surface deposit feeders, and are common in the
Slough and harbor. Capttella capttata is generally found in muddy de-
posits, but is known to invade disturbed habitats. By January 1972, all
the C. capttata were gone.

The density of A. btoculata remained about the same from November 1971
to January 1972, decreased in March and June 1972, and further decreased
in September 1972 (Fig. 12). From November to January there was a definite
increase in individual size. Armandia btoculata had another settling peak
in the spring and additional recruitment probably occurred at that time.

The decline in the number of A. btoeculata was undoubtedly precipitated
by the tremendous settling of Phoronopsts viridis in March 1972 (Fig. 12).
Phoronopsts viridis is a suspension-feeding phoronid worm that builds and
lives in a permanent sand tube. The new population reached adult size
by June 1972, with a density of about 1,000 individuals per 0.018 square
meter. As the phoronids grew, their tubes occupied more space, drastically
reducing the amount of the deposit-feeding habitat, thus, decreasing the
number of A. btoculata. Woodin (1972) supports this conclusion with exper-
imental evidence. She found that the density of A. brevis on San Juan
Island, Washington, increased when the larvae of several tube-building
polychaetes were prevented from settling. She concluded that the increase
in A. brevis abundance was the result of decreased interspecific competi-
tion for space.

Little is known about the ecology of A. btoculata which has the char-
acteristic of an opportunistic species, similar to C. capttata.

From March 1972 until April 1973, P. virtdts dominated the benthic
assemblage. Its density dropped steadily from the March settlement to
December 1972, and in April 1973 there was a second large recruitment.
Phoronopsts virtdis may spawn into the early summer; however, in both
years early recruitment and fast growth left little space for additional
settlement. In March 1972, about 1,200 individuals per core settled, and
200 A. bioeulata per core were present. In April 1973, about 500 phoronids
per core settled in a population of large adults (200 per core). The
difference in recruitment between successive springs again suggests that
available space limits the number of settling larvae.

Several species of bivalves settled in relatively large numbers at
times during recolonization (Table 5). Most were gone by the next sampl-
ing period and very few reached adult size. The situation was similar at
the disposal station. Settling conditions were optimal for a short period,
and subsequent events caused heavy mortality. Apparently, the environment
was marginal for most of the bivalves.

5|

Very few crustacea were present, although occasionally a number of
amphipods, Caprella sp., were found on small clumps of algae (Ulva) or
hydroids (Aglaophenta) .

Larval settling in the harbor was observed at the control station and
the dredged station. At the control station, undisturbed by dredging, no
great number of larvae settled and persisted, either because they selected
not to settle or they settled and were eaten by the existing residents,
Notomastus tenuis, a large deposit-feeding worm. In contrast, a newly
exposed surface at the dredging station was recolonized by several species
in large numbers (the tube worm, Capttella, the polychaete, Armandia, and
the plumed worm, Phoronopsts). Presumably, competition for space resulted
in phoronid dominance. By April 1973, the dredged area supported a popula-
tion of adult P. virtdis. At that time, there was another large recruit-
ment of phoronids and no significant, detectable settlement of polychaetes,
although Armandia was present in the water and a persistent patch of
P. vtrtdts was established at the dredged station. What was once an
active-burrowing, deposit-feeding assemblage was replaced by sedentary,
suspension-feeding tube worms. The patchy distribution of animal assem-
blages in the slough and harbor probably increases the number of alternate
sequences and end products of recolonization. In a stable, homogeneous
benthic community such as the offshore 20-meter control station, the
probability of reestablishing both trophic and taxonomic structure after
disturbance is considerably higher.

The number of species decreased over 60 percent from July to September
1971, immediately following dredging. The biomass was small in September
because the individuals were small and apparently newly settled. After
September the number of species increased to a maximum in June 1972, when
there were twice as many species as before dredging. By September 1972,
the number of species remained relatively stable, but was above pre-
dredging values. There was a decrease in the number of species in January
1972, and an increase in April 1973. This was probably the result of
winter mortality and spring recruitment, respectively.

The control area was sampled in April 1973 and the fauna was similar
to that at the dredge station before dredging (Figs. 12 and 13). The
variation in species per core was small at all stations. There was a
Significant difference between the values in July 1972 and the species per
core after recolonization (April 1973).

The rate of recolonization (Fig. 13) and also the rate of recovery at
the disposal station (Fig. 14) were similar to that determined in other
investigations (Reish, 1963; Odum 1969; Simberloff and Wilson 1969, 1970).

Species diversity, H} and evenness, J, did not follow the same
trend as the number of species (Fig. 13). Species diversity and evenness
before dredging and at the control station in April 1973 were similar,
but differed from the dredged station after recolonization (Fig. 13).
Diversity increased directly after dredging, although the density and
number of species decreased (Figs. 12 and 13). This was primarily due to

32

the even apportionment of individuals among the few species present. In
October 1971, evenness dropped slightly, but the number of species in-
creased from 10 to 22; diversity also increased (Fig. 13). In November
1971, the dominant species were Capttalla and Armandia. By January 1972,
the number of species had decreased and Armandta was the only abundant
animal (Fig. 12). Both diversity and evenness dropped by winter. From
January to June 1972, the number of species more than doubled (Fig. 13);
Armandta and several species of bivalves (mostly juveniles) were present
in large numbers. Despite the fact that the density of Phoronopsis was an
order of magnitude greater than the second most abundant animal (Fig. 12;
Table 5), both evenness and diversity increased (Fig. 13). In September
1972, Armandia and bivalve densities were very low; the number of species
decreased from 64 to 38 (Fig. 13), and Phoronopsts was the only abundant
species. Evenness and diversity both decreased (Fig. 13). From September
to December 1972, Phoronopsts density decreased from 412 per core to 154
per core (Fig. 12), causing an increase in evenness and diversity (Fig.
13). Finally in April 1973, the large spring recruitment tripled the
density of Phoronopsts (Fig. 12), and evenness and diversity decreased
again) (Fase a3).

By comparing Figures 12 and 13 it is apparent that species diversity
cannot be properly interpreted without information on the number of
species (richness) and their relative abundances (evenness).

Some of the decreases in species diversity were related to life history
characteristics, mortality caused by physical stress, or perhaps predation
and competition. Increases were associated with the same phenomena under
differing conditions, except there was no indication that competition in-
creased diversity.

At the disposal station, there was a marked increase in the number
of species, species diversity, and evenness during the later phase of
recovery (Fig. 14). At the dredged station, there was an increase in
species diversity and evenness after almost complete removal of the native
fauna; 1.5 years later the diversity was still much lower than it was be-
fore dredging because of Phoronopsts dominance (Fig. 13). Thus, the
effect of dredging and disposal was not a decrease in species diversity.
The reestablished or recuperated assemblages differed considerably from
the originals; in one case, the diversity was higher and in the other,
lower.

There is no positive correlation between species diversity and the
"health" or "desirability" of any of the above situations. Therefore,
the use of this parameter in summarizing community structure or changes
in this structure due to man's activity is not recommended.

The sequence of recolonization at the dredged station involved two
relatively distinct phases. In the earlier phase, the opportunistic or
fugitive species quickly colonized the open space; i.e., Capttella and
Armandta. They are generally considered poor competitors, and are rela-
tively small, with short reproductive cycles, fast growth rates, and high

53

dispersal capacities (Hutchinson, 1951; Margalef, 1963; Odum, 1969;
Connell, 1972). In the second phase, the community dominant was estab-
lished; i.e., Phoronopsts. Dominant species have a longer life cycle,
larger size, and superior competitive abilities (Margalef, 1963; Odum
1969; Connell, 1972).

Whether the colonized phoronid patch is a stable assemblage or merely
a stage in a long-term sequence of recolonization is unknown. The dominant
deposit feeders present before dredging and adjacent to the patch might
invade and successfully exclude the tube dwellers. There is a spectrum of
possibilities, and as mentioned earlier, it is just as likely that the
patchy nature of the slough bottom increases the number of possible se-
quences of recolonization and stable end products. In Buzzards Bay and
Cape Cod Bay, Massachusetts, studies have shown the persistent separation
of communities of deposit-feeding and suspension-feeding animals (Rhoads
and Young, 1970, 1971; Levington, 1972). Maintenance of this separation
is apparently due to sediment characteristics and the behavior and eco-
logical requirements of the two trophic groups. In this study, the sedi-
ments do not differ, but the adults of one trophic group may prevent
recruitment of the other.

The similarity between the predredging and control conditions 1.5
years later is remarkable. It appeared to be a very stable deposit-
feeding assemblage, although there were changes in the species composi-
tion. In contrast, the recolonized harbor area was completely different,
in terms of species number, composition, number of individuals, species
diversity, evenness, and trophic dominance.

There is a need for experimental studies to determine the importance
of physical phenomena, life history characteristics, and animal inter-
actions in benthic communities. If this information was available, the
relationship between community structure (spatial heterogeneity) and
temporal changes, including recolonization, could be adequately studied
for marine ecosystems.

VII. SUMMARY AND CONCLUSIONS

The benthic assemblages differed with changes in amount of sediment
movement or substrate stability. Many animals were characteristic of the
relatively stable submarine ridges but few inhabited the unstable terrace
slopes. Even fewer animals were found in channeled areas, and their num-
bers decreased with increasing sediment movement and accumulation. Accu-
mulation of sediment directly buried animals and seaweed. Burying the
animals and algae raises the decomposition rate, thereby decreasing
available oxygen and increasing hydrogen sulphide concentrations to toxic
levels. Sediment movement was the most important environmental factor
affecting the distribution of macroinvertebrates at the control area and
in the canyon.

Dredging removed 60 percent of the original population of benthic

animals. After 1.5 years, the number of individuals was low but the
species diversity and evenness indexes were higher than before dredging.

54

Reproductive activity of the benthic organisms has two peak periods
correlated with the winter-spring and fall-winter seasons. Both seasons
are characterized by the rapidly changing length of days. Two peak phyto-
plankton blooms also coincide with the two periods of high reproductive
activity by the benthos that frequently have young that form part of the
zooplankton and feed upon phytoplankton. Many of the benthic animals are
sporadic spawners; some spawn in winter and others almost all year long.
Yearly changes in currents, water temperatures, and wave energy at critical
early life can affect the successful settlement of benthic animals and
cause the composition of benthic populations to differ yearly.

Experimental burials were made at two enclosed areas on the stable
flat bottom at a water depth of 20 meters. One of the areas was covered
with coarse sand to a depth of 15 centimeters and sampled at various times
during the 2 weeks following burial. The other area was covered with fine
sand to the same depth but by the third day the covering had been scoured
away and the original bottom exposed. This area was sampled 2 and 5 days
after burial.

The first enclosure had several tube-dwelling worms (Wothrta) burrow
up through the coarse sand and construct tubes from it. WNothria was one
of the few animals whose abundance was not decreased by burial. Some
gaper clams extended their siphon holes to the new surface. All the small
crustaceans and mollusks were killed by burial; burial also killed 66
percent of the worm species and 50 percent of the individuals. All of the
animals that survived burial are commonly found deep in the bottom.
Nematode worms increased in the experimental area.

The bottom of the second area was buried for only 2 days. About 69
percent of the species and 82 percent of the individual crustaceans and
mollusks were killed by the short burial. Worm mortalities were low.

Disposal of the dredged material affected benthic animals in a less
stable substrate. There was an 8-percent reduction in the number of
species and a 60-percent reduction in the number of individuals.

Capability to withstand burial can be predicted by the animals' struc-
ture, behavior, usual vertical distribution in the bottom, and the sta-
bility of the substrate normally inhabited.

One and one-half years after disposal, the number of individuals was
still 60 percent less than before disposal. However, the number of
species, species diversity, and evenness was higher than before. Biomass
was little changed although the species composition had changed.

The immediate effect of dredging upon the channel area was to remove
the two species of large bivalves (the bent-nosed clam and the gaper clam)
that dominated the biomass. The bent-nosed clam was more numerous than
the larger gaper. Many oligochaete and polychaete worms were also removed.
The original population was a stable deposition-feeding assemblage. In
contrast, the recolonized area was completely different after dredging and

55

also differed from the control area. Species number and composition,
number of individuals, species diversity, evenness, and trophic dominance
all changed.

The sequence of recolonization after dredging occurred in two parts:
First, two opportunistic species (worms Capttella sp. and Armondis sp.)
quickly occupied the newly exposed bottom. They are poor competitors,
and have a short reproductive cycle and high dispersal capabilities.
Second, the community dominant, Phoronopsts, became established and was
still dominant after 1.5 years.

Temporal variations in bottom communities, the sequence and rate of
colonization, and the end state of recolonization can be predicted only
if the reproductive patterns of the local benthic fauna are known; e.g.,
larvae settling jars and benthic samples. Data from the different sources
show that many of the benthic organisms spawn in the spring and fall sea-
sons although some animals reproduce throughout the year.

Organisms adapted to unstable bottom conditions survive burial better
than others do; however, disposal caused about 60-percent reduction in the
number of individuals in the area. The number of different species drop-
ped slightly. During recovery the number of species increased for the
first year then decreased. Species composition was more stable than rela-
tive abundance. Many worm species were present throughout the study period
but mollusks and crustaceans occurred irregularly. The number of individ-
uals was still 60 percent lower 1.5 years after disposal, but the species
diversity and evenness were higher.

The results of this study suggest:

1. The ultimate recovery or recolonization of a dredged area or a
disposal area depends upon the timing of the action in relation to the
reproduction cycles and distributive abilities of the benthic organisms
present in and around the area.

2. In Monterey Bay, spring and fall are the most active spawning
seasons for many benthic organisms; dredging or dumping should be avoided
at those times.

3. Underwater disposal of dredged material should be made in unstable
areas if possible.

4. Dredged areas or disposal areas may take more than 1.5 years to
return to the original conditions.

56

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GRIGGS, G.B., CAREY A.G., and KULM,L.D., "Deep-Sea Sedimentation and
Sediment-Fauna Interactions In Cascadia Channel and Cascadia Abyssal
Plain, Deep-Sea Research, Vol. 16, 1969, pp. 157-170.

GRIGGS, G.B., and KULM, L.D., "Sedimentation in Cascadia Deep-Sea Channel,"
Geological Society of America Bulletin, Vol. 81, 1970, pp. 1361-1384.

62

HADERLIE, E.C., "Marine Fouling and Boring Organisms in Monterey Harbor,'"!
Veltger, Vol. 10, No. 4, 1969, pp. 327-341.

HADERLIE, E.C., ''Growth Rates in Sessile Marine Invertebrates of Monterey
Bay ,'' Veliger, (in preparation).

HEATWOLE, H., and LEVINS, R., "Trophic Structure Stability and Faunal
Change during Recolonization," Heology, Vol. 53, No. 3, 1972,
pp. 531-534.

HEWATT, W.G., "Ecological Succession in the Mytillts caltforntanus Habitat
as Observed in Monterey Bay, California," Heology, Vol. 16, No. 2, 1935,
pp. 244-251.

HILASKI, R., "Stomach Contents of Flatfishes,'' Master's thesis, Moss
Landing Marine Laboratories, Moss Landing, Calif., 1972.

JOHNSON, R.G., "Variations in Diversity within Benthic Marine Communities,"
American Naturaltst, Vol. 104, 1970, pp. 285-300.

JOHNSON, R.G., ''Animal-Sediment Relations in Shallow Water Benthic
Communities ,'"' Martine Geology, Vol. 11, 1971, pp. 93-104.

KELLER, G.H., et al., "Bottom Currents in the Hudson Canyon," Setence,
Wool, USO5 WO, yoyo Il Siliyes

MacARTHUR, R.H., and WILSON, E.0., The Theory of Island Biogeography ,
Princeton University Press, Princeton, N.J., 1967.

MARGALEF, R., ''Temporal Succession and Spatial Heterogeneity in Phyto-
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MYERS, A.C., '"Tube-Worm-Sediment Relationships of Dtopatra cuprea (Poly-
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63

ROWE, G.T., "Observations on Bottom Currents and Epibenthic Populations
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Vol. 145, 1964, pp. 1042-1046.

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WONG, V.D., ''Moss Landing Harbor: A Case Study," Shore and Beach, Oct.
1970, pp. 26-39.

64

APPENDIX A
DEVELOPMENT OF A QUANTITATIVE SAMPLING PLAN
I. INTRODUCTION

Generally, it is not possible to study the sampling problems involved with
a particular environment and set of research objectives before the initiation
of benthic surveys. As a result, development of a sampling plan often de-
pends upon information generated from other studies and the experience of the
investigators. This is to be expected since one of the primary objectives of
many surveys is the identification of the fauna.

The objectives of this study were more specific and required a prior
understanding and reduction of the variations due to sampling error.
Sampling was restricted to a few permanent stations that were maintained and
sampled by divers within a locally defined area.

Three major problems should to be solved to develop a quantitative sampl-
ing plan for the study area:

(a) Does the sampling device catch all or most of the organisms
found in a given volume of sediment?

(b) How many replicates must be taken to be confident, within
certain statistical limits, that the parameters used to describe a
fauna are adequately estimated?

(c) How should the replicates be distributed over the environ-
ment?

II. THE SAMPLING DEVICE

The sampling device is a standard 1.4-kilogram coffee can with both ends
removed. Careful placement of corers by divers minimizes bottom disturbance
and snap-on plastic lids create a watertight seal that allows transportation
of intact sediment cores both in water and air. Depth of penetration can be
adjusted by diver operation so the constant surface area (0.018 square meter)
is associated with the same volume of sediment. Corers were inserted to
maximum penetration which produced an average core height of 15 centimeters.

Quantitative measurements of biomass were not made since they require a
sampler that covers a large surface area and penetrates deeper than 15 centi-
meters into fine sand (Masse, 1968; Oliver, 1973). This is primarily due to
the effect of sparsely distributed large animals on the biomass.

A recent comparison of benthic samples taken with the 1.4-kilogram
coffee can corer, a diver-operated suction dredge, and a Smith-McIntyre
grab at Moss Landing indicated that all three techniques produce similar
estimates of the number of species per unit area, number of individuals

65

per unit area, and index of species diversity (personal communication,
Hodgson, Moss Landing Marine Laboratories, 1972). The small area sampled
by the corers had a significant effect on estimates of the abundance of
certain larger and less common species, and on the total number of species
in the community. However, the other sampling techniques had disadvantages
of equal magnitude. Thus, the use of coffee can corers is adequate for
sampling when compared to other conventional sampling techniques. In
addition, the hand placement by divers permits good replication and precise
control of the area sampled.

III. THE NUMBER OF REPLICATES

A number of parameters were used to describe the benthic infauna: The
number of species, total number of individuals, number of individuals per
species, and species diversity. To determine the number of replicate corers
needed, the precision of estimating as many of these parameters as possible
should be maximized.

Twenty-eight cores were taken from an area near the 20-meter control
station to examine the relationship between the parameters listed and the
number of replicate cores collected. The 28 cores were taken from the
three smaller areas in Figure A-1. This number of cores is well above the
maximum which would be taken at any one station in a routine sampling
program. Although sampling was not strictly random, individual cores were
chosen at random from the combined group (28 cores) for the following
analyses.

1. Number of Species)

Species were recorded in two ways: The total number of species col-
lected in all cores (species per sample), and the average number per core.
Both are sample values which grossly underestimate the actual number of
Species in the community, but are very useful as relative parameters.
Averaging the number per replicate allows a measure of variance. However,
a single core collects fewer species than the total sample which covers
enough area to include most of the characteristic species though many of
these occur in low abundance.

The slopes of the curves in Figure A-2 indicate the rate at which new
species are accumulated as the area sampled is increased (Jones, 1961).
They are averaged from three random orders of the 28 cores. Considering
all 28 cores as 100 percent, 16 cones represent 5/7 percent of the aneasand
contain 92 percent of the species, 8 cores are 30 percent of the area wath
76 percent of the ‘species, and) 4 cones are) 14 percentwom the arcawandmasy,
percent of the species. Hodgson (personal communication, 1972) found the
corer was compared to two other devices which sample a much larger area;
however, almost identical ratios of percent area to percent species were
found for all three devices.

To examine the relationship between the number of replicates and the

estimation of number of species per core, replicates were drawn at random
from the 28 cores; means and confidence limits were computed for

66

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saigads

progressively larger sample sizes of 4, 8, 16, and 28 cores. The average
number of species per core and the 95-percent confidence limits changed
little with increasiny sample size (Table A-1).

Thus, within relatively narrow confidence limits, each core is expected
to contain about 34 different species. Figure A-2 shows that 8 cores would
be necessary to accumulate about 90 species (75 percent of those present
in 28 cores).

2. Number of Individuals.

In Table A-1, the common species have been ranked and three main groups
delineated on the basis of abundance. Means per core and their 95-percent
confidence limits are listed for the four sample sizes. The 20 species are
distinguished by the following characteristics: (a) They contain 87 per-
cent of the total number of individuals of all species (by group: 90-per-
cent mollusks, 90-percent crustaceans, and 87-percent worms); (b) variance
to mean ratios are greater than 1 in all cases and less than 7 with the
exception of P. cirrifera and Mediomastus californtensts; and (c) the
mean abundance per core is greater than 1.5. The lower cutoff point in
Table A-1 is somewhat arbitrary, since abundance decreases gradually and
there is no clear-cut distinction between the last species included and the
first one excluded. Dominance of a few species can be seen by the fact
that 90 percent of the individuals are contained in about 20 percent of the
species. For most of the species, the confidence limits decrease sharply
from 4 to 8 cores and continued to decrease gradually to 28 cores. Excep-
tions are some of the species with the highest variance to mean ratios.

Table A-1 also shows changes in the estimation of the total number of
individuals per core and individuals of major groups per core.

3. Species Diversity and Evenness.

Although this study was not concerned with estimating absolute species
diversity of the community (Brillouin, 1965; Pielou, 1966a), the Shannon
and Weaver (1963) formula was still used as the measure of diversity and
J (Pielou, 1966b) for evenness. The use of the parameters in a strictly
relative sense justified using these equations.

Cumulative species diversity and evenness values are plotted in Figure
A-3 from an average of five random orders of the 28 cores; diversity and

evenness appeared to stabilize between 4 and 8 cores.

4. Choice of the Number of Replicates.

In chosing the number of replicates taken at each station, the pract-
ical limitations of time and resources, the nature of the research objec-
tives, and the results of this analysis were considered. Further, as
mentioned previously, sampling was confined to permanently marked stations
of a limited and well-defined area.

69

Table A-1. Effect of increasing sample size on means per core (X) and
their confidence limits (CL) of major groups and species.

Species per core
Individuals per core

Individuals per core of:
Worms
Crustaceans
Mollusks

COWNW
ofo

Telltna modesta

Magelona sacculata
Paraphoxus dabotus
Prionospto pygmaeus

WO OW
Oo @& oC
WkaO
woOnWnuUo

OMNWNW
AWA An

unprn
noo

NNWeE
NANO
orwnAr

Nothria elegans
Lumbrineris lutt
Prionospto ctrrifera
Stltqua patula
Mediomastus cali forniensts
Hemilamprops californica

nanNowoan
NON FON
ofuhQo
FPNNFE ND W
anu fh
DEDAWO
NWeENFN
NP ODNe
J 610 Oo 6.0
NWeE DOF
NPE WAP e
NON UWS

Haploscoloplos elongatus
Euphtlomedes oblonga
Sptophanes misstonensis
Pinnixa_franctscana
Synchelidtun spp.
Armandia btoculata
Nephtys cornuta
Chaetezone setosa
Tellina meropsis

FPWNORON FN
WOOT AWOWW SO
NANO! WNHN
ouuMNo!t nsw
RPNNFNOF BN
WAWWWe OOF
ee oe et
SCMWANDAWWUh
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NOOrFrOMMOoONnN
SRK MON MND WwW
URDROONWWASO
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WAN —& OA Co

70

Based on these considerations, a sample size of eight replicate cores
was chosen. The sample size contained 76 percent of the number of species
in 28 cores, and only about 20 of these species were important numerically;
i.e., they contained 87 percent of the total individuals. The confidence
limits for the 20 species indicate how accurately each species' abundance
can be estimated with eight cores as compared to more or less; 8 appears to
be the optimum number in most cases. In addition, the number of species
per core is estimated well with only four cores; eight is satisfactory for
the number of individuals per major group. Figure A-3 indicates that eight
replicates also provide a good estimate of species diversity and evenness.

IV. SAMPLE DISTRIBUTION

It was beyond the scope of this study to examine the detaiied patterns
of distribution of the species sampled. However, to construct a quantita-
tive sampling plan it is necessary to have some measure of the gross
patchiness of the fauna. Sampling was stratified once by locating stations
at different depths, but it was unknown whether the magnitude of spatial
variation of the infauna warranted further stratification of sampling with-
in a depth contour.

To determine the gross patchiness of the infauna, four sets of repli-
cate cores were taken randomly from progressively larger areas: 10 from
each of the two 2-meter squares, and 8 from a 10-meter square and a 1.6-
kilometer swath approximately 200 meters wide. The distribution of the
samples at the 20-meter control station is shown in Figure A-1l. If any of
the major parameters changed significantly from one area to the next, it
might be possible to adjust the sampling plan to produce a more accurate
representation of the fauna.

Means of individuals per core of the dominant species were calculated
for each area and tested with the Kruskal-Wallis test and Wilcoxon-Mann-
Whitney a postertort test. The species are listed by abundance in Table
A-2; significant differences of means, species, diversity, and evenness
are also indicated. Table A-3 is a matrix of the number of significant
differences between areas for each species, summed from Table A-2.

Similarity coefficients (Bray and Curtis, 1957) were computed for all
the possible pairings of the means of the dominant species (two individuals
per core or more) for each of the four areas (Table A-4). The index has
no statistical basis so that differences cannot be tested. It equals the
sum of the lower relative abundance values for all the species common to
both of the samples being compared.

Differences or similarities between the four areas may also be char-
acterized by changes in the rank order of the dominant species as listed
in Table A-2. Notable differences between each area and the remaining
three are: (a) In area 2M2-a, 7. modesta and M. sacculata exchanged rank,
and the abundance of P. ctrrifera and H. caltforntensts was higher; (b)
in area 2M2-b, the abundance of NV. elegans was the lowest; (c) in the 1.6-
kilometer swath, M. sacculata and P. pygmaeus exchanged rank, and

C1

Of a2 r4 on Gir BrchOr neue le ale MIG a2Oe 22 C4 wacomacs

Replicates

(Zien SANE « Yael = | enema | ae |S opal |< SrA O Yorn a72emme bre AS) 245}

Replicates

Figure A-3. Cumulative species diversity, H" (Shannon and Weaver, 1963)
(upper graph) and evenness, J (Pielou, 1966 ) (lower graph)
with increasing sample size (calculated from mean of five
random orders).

te

Table A-2. Comparison of means per core of major
species and groups of the four areas;
numbers not connected show significant
difference at 5-percent level. (Dotted
lines span dissimilar means to connect
similar ones. )

Species 2M2a 2M2b 10M2 Mile
Tellina modesta E567 58.4. GlsS — S056
Magelona sacculata A556 80:2 80.9 14.5
Prtonospto pygmaeus 15.5 i154 1968 - 27.9
Paraphoxus dabotus LGot 1NGs8 NS.8y \ ildled!
Nothria elegans SoOrt Sol) Va 6.6
Lumbrinerts lutt 4.8 Sod HS) Soe
Prionospto ctrrifera 10.3 Bod 2.6 0.0
Stltqua patula 4.2 508 Sys) 1 6
Mediomastus caltforntensts 6.1 2.6 4.0 Bol
Hemtlamprops caltforntca CoB Deol 0.4 Iho dh
Euphtlomedes oblonga Ao) 2.0 4.3 S739
Chaetezone setosa Mog Omen oe) 6.3
Haploscoloplos elongatus Bed Pees 4.0 eS
Protothaca stamtnea Ori 0.3 0.9 8.8
Synchelidtum spp. 3.9 1.5 15 @ 25

Euphtlomedes caracharodonta 1.8 Ded 16 3.4

Anthogoa OR 1.6 I) 8.3

73

Table A-3. Matrix of the number of
Significant differences
in species abundance
between areas derived
from Table A-2.

Table A-4. Matrix of similarity
coefficients of the
four areas.

74

P. etrrifera was absent; the abundance of (C. setosa, anthozoa, and
P. staminea (bivalve) was higher, and the density of the other bivalves,
T. modesta and S. patual, was lower. i

In summary, Tables A-3 and A-4 show that the 1.6-kiiometer swath area
is the least similar of the four areas sampled. The quantitative and
qualitative information in Table A-2 supports this conclusion. Samples
from the three smaller areas which were closer together are similar.
Thus, the fauna appears to be homogeneous on a smaller scale within the
20-meter depth contour. Since the permanent stations were restricted to
an equally small area, stratification of sampling was not necessary.

V. SUMMARY

1. Diver-operated coffee can corers (area,0.018 square meter; pene-
tration, 15 centimeters) permit good replication and precise control of the
area sampled.

2. Eight cores sampled had 76 percent of the species present in 28
cores.

3. The effect of increasing sample size on the means and 95-percent
confidence limits was examined for various parameters. In most cases,
the confidence limits decreased sharply from 4 to 8 cores and continued to
decrease gradually to the largest sample size (28 cores).

4. Cumulative species diversity and evenness values appeared to
stabilize between four and eight cores.

5. A comparison of samples from four progressively larger areas
indicated a general similarity among the three smaller areas; the largest
deviated from these.

6. It was concluded that a sample size of eight replicate cores was
sufficient to estimate most of the important parameters and that the fauna
appeared homogeneous within the 20-meter depth contour for an area equal
to that of the permanent stations.

tS

APPENDIX B
SPECIES LIST

POLYCHAETES

Aedictra nr. pactfica

Amaeana oectdentalis

Ampharete nr. labrops
Anattides groenlandica
Anatttdes willtamst
Anetstrosyllis namata

Artectdta suectca

Artctdea nr. suectca

Artetdea sp.

Arabella pectinata (nr. gentculata)
Armandta btoculata

Asychts dispartdentata
Axtothella rubroctneta
Boceardia bastlarta

Capttella capitata

Chaetozone setosa

Chone ecaudata

Chone gractlis

Cossura sp.

Decamastus sp.

Dispto uncinata

Dtopatra ornata

Eteone nr. alba

Eteone nr. caltfornica (nr. longa)
Eteone nr. spetsbergensts
Eteone sp. (juvenile caltforntca?)
? Euelymene sp.
Eumtda tubt formis

Eusyllts - Typosyllis

Glycera americana

Glycera capitata

Glycera convoluta

Glycera robusta

Glycera spp. (juveniles)
Glyctnde sp.

Gontada ? maculata

Gyptts brevipalpa
Haploscoloplos pugettensts
Harmothoe ltunulata

Harmothoe prtops

Hestonella sp.

Hesperone laevis (nr. complanata)
Hesperone sp. (juvenile laevis)
Heteromastus filobranchus

76

APPENDIX B
SPECIES LIST-Continued

POLYCHAETES-Continued

Heteromastus nr. filoformis
Laontece etrrata
Leptdasthenta longictrrata
Lumbrineris caltforntensts
Lumbrinerts ltmicola
Lumbrinerts nr. lutt
Lumbrtnerts tetraura
Magetona nr. pttelkat
Magelona sacculata
Magelona sp. a

Magelona spp. (mostly juveniles)
Mediomastus californtensts
Nephtys caecotdes (including W. parva)
Nephtys caltforntensts
Nepthys cornuta

Nepthys sp.

Nerets zonata

Nerine sp.

Wertnides acuta

Nerinides sp.

Nothria elegans

Notomastus ? lineatus
Notomastus magnus
Notomastus tenuts

Onuphus eremita

? Orbinta sp.

Ortopsts sp.

Qwenta collaris

Paranaitis polynotdes
Parandalta sp.

Paraontdes platybranchia
Pectinarta cali forntensts
Phyllodoce sp.

Phy llodoetdae

Pherusa inflata

Pholoe glabra

Phylo feltx

Pilargis berkeleyae

Pista cristata

Platynerets btcanaltculata
Poectlochaetus johnsont
Polydora neocardalia (or brachycephatla)
Polydora sp.

Prionospto ctirrtfera

at

APPENDIX B
SPECIES LIST-Continued

POLYCHAETES-Continued

Prtonospto malmgrent
Prionospto pinnata
Prionospto pygmaeus
Pseudopolydora sp.
Rhynchospto sp.
Seoloplos armiger
Stgambra tentaculata
Sptophanes bombyx
Sptophanes misstonensts
Sthenelats verriculosa
Telepsavus costarumn
Thalenessa spinosa
Tharyx mont laris
Travista gigas
Typosyllis armillaris
Typosyllts sp.

MISCELLANEOUS WORMS

Anthoza
Echturotdea
Enteropneusta
Holothurotdea
Nematoda
Nemertinea
Oltigochaeta
Phoronopsts virtdts
Stpuneultda

MOLLUSKS

Snails

Acteoctna spp.

Aglaja spp.

Cylichna spp.
Epttontum bellastriatum
Kurtzta sp.

Mangelta barbarensis
Mitrella sp.

Nassartus fossatus
Nassartus mendicus
Wassarius ? perpinguis
Nassarius rhinetes
Odostomta spp.
Oltvella biplicata

78

APPENDIX B
SPECIES LIST-Continued

MOLLUSKS-Continued

Oltvella pyena
Polintces draconts
Rictaxts spp.
Turbonttla spp.
Bivalves
Clinocardiun nuttallit
? Cooperella sp.
Cryptomya caltfornica
Lyonsta cali forntca
Maecoma acolasta
Macoma tndentata
Macoma tinquinata
Macoma nasuta
Macoma secta
Macoma yoldtformis
? Mactra sp.
Modtolus sp.
Mya arenarta
Mysella aleutica
Mytilus sp.
? Memocardium sp.
Nuculana cf. minuta
Nuculana taphria
Protothaeca staminea
Stltqua patula
Stliqua lucida
Solen stcartus
Tellina bodegensis
Tellina ? meropsts
Tellitna modesta
Tellina nuculotdes
? Transennella sp.
Tresus nuttallit

CRUSTACEANS

Ostracods
Bathyleberts sp.
Euphtlomedes carachrodonta
Euphtlomedes longiseta
Euphtlomedes oblonga
Podocopid ostracoda
Amphipods
Allorchestes sp.
Ampeltsca cristata

9

APPENDIX B
SPECIES LIST-Continued

CRUSTACEANS-Continued

Aorotdes columbtae
Argtssa hamattpes
Atylus sp.
Bathymedon roquedo
Caprella angusta
Caprella caltforntca
Corophtum ? caltforntanum
Corophtum ? acherusteum
Dultchta sp.
Eohaustortus senctllus
Isaetdae
Ischyroceri dae
Listrtella dtffusa
Lystanasstdae
Megaluropus longimerus
Metaphoxus fultont
Monoculodes spintpes
Pachynus barnardt
Paraphoxus dabotus
Paraphoxus eptstomus
Paraphoxus lucubrans
Paraphoxus obtustdens
Paraphoxus vartatus
Phott dae
Photts caltforntea
Pleusttdae
Protomedeta ? penates
Syncheltdium spp.
Tiron biocellata
Isopoda and Tanaidacea
Austrostgnum tillerae
Bathycopea daltonae
Edotea subltttoralis
Leptochelta sp.
Munna ubiquita
Mysidaceans
Acanthomysts davtst
Archaeomysts maculata
Cumaceans
Anchtcolurus oectdentalis
Cyclaspts nubtla
Diastylts spp.
Diastylopsts tenuis
Hemtlamprops caltforntca

80

APPENDIX B

SPECIES LIST-Continued

CRUSTACEANS -Continued

Lamprops spp.
Mesolamprops sp.
Decapods
Blephartpoda oectdentalts
Calltanassa spp.
Cancer gracilts
Cancer jordant
Cancer magtster
Holopagurus ptlosus
Optsthus transversus
Pagurus granotmanus
Pinntxa franetscana
Seleroplax granulata

ECHINODERMS

Amphtodia urttea
Amphtura arcystata
Dendraster excentricus

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"OL00-O-€L-ZZMOVA 3OBAJUOD ‘*AEeRUeD YOTeSSoYy BuTseuTsUg TeIseOD “OL00-0-€2L-ZZMOVG 2981}U0D *19}2UeD YDIeesey BuTisesuTsUy_ Te seo)
"S'N “AL °SL-9£ ‘ou aeded TeoTuypey ‘1ejUeD YyoAvesey BuTIosUTsUg “"S°N “AIL °GL-9Z ‘ou aoded TeoTuyoe, *ieqUeD YyoIeesey BuTIee9UuTsUuq
peqseop “Ss : Seftses “ITI ‘az0yjne qurof ‘*N taqeq £41099"TS “II Teqseog *S*n : Setteg “JIT “*rzoyane jutof S*yN zeqeg A1999eTS “II
“OTUTL “I °SETeO SAeg Aezequoy *¢ ‘Tesodstp Ttods *Z ‘soyqueg *| “OTJEL °I “FETeO SAeg Avaajquoy *¢ “Tesodstp Ttodsg *zZ ‘soy ueg *|
*pessnostp ole SeTIT[TTqe eat Onporadea pue *pessnostTp ere setTTTqe aatTqjoOnpoidez pue
uoTjnqF1z3SsTp Teuney pue ‘Azavode1 pue uoTjeztTuoToOIe1 Juenbesqns ‘TeTI uoT4yngtlISstp Teunez pue *AzaAoVeT pue UOT eZzTUOTOD.eI JUeNbesqns ‘TeT1
-a}eu pesperip jo TesodsTp pue B3uTSpeip jo sjoezze ‘sedsueyo ARTTTqGeqS -ej}eu pespeip jo TesodsTp pue 3uyTSpezp jo sjoesyze ‘sesdueyo AITTEWQeIS
ajzeizsqns pue ses’eTquesse OTYJUeq UT suoTJeTIeA [Te1odweq [einjeN ajeiqsqns pue sos’etquesse of-yJUeq UT suoTJeTIeA Terodwe} TeinjzeN
‘zg °d : AyderasotTqtg *zg °d : Ayder30TTqQTg
(0L00-9-€2-ZZMOva (0L00-0-€2-ZZMOVa
$ zeque9 yoreesey BuTTeeuTZuq Te}SeOD = JOP1}U0D) OSTY (C1 -9/ “OU £ Zequep yDieesey BuTrseuTsugq TeIseoD = JoOeP1IqUOD) OSTY (C1 -9/ “Ou
§ zaque9 yoreesoy BuTrseuTSsuq Te yseog - teded TeoTuyoey) “TTF : *d 1g $ zaque9 yoreesey ButTrsoUTSUg TeIseog - Jeded TeotuyseL) “TTT : *d 1g
°Q/6, ‘1e3Ue9 YOTeesey BuTzseuTsuq TeISeOD *S*n =: °RA “9/6, S2eqUaD YOTReSey BuTAseuTSugq TeIseoD *S°*N : “eA
Satoateg *3q — *42999eTS “*N 4e9eq pue TeATTO *S uYyor Aq / eTUTOZTTeD ‘atoaTeg *3q — *A2099"TS °N 103eq pue APATTO *S uYor Aq / BTUIOFTTED
‘keg Aorta uOW Je sOYyjUsq ouos uo TesodstTp pue BSuTZpeiIp Jo szOezITq ‘keg Aataquoj] Je soyjueq ewos uo Tesodstp pue Supspeap jo sjoeFFyq
*s uyor ‘22ATTO "s uyor ‘224770
eee
daigcn* L729 GL-9/*0u dargcn° €0ZOL daigcn* 1729 GL -9L"0u dargsn* €0ZOL
*OL00-0-€2-ZZMOVG JOPAWUCD *19RUeD YOTPESeY ZuTAseUuTSUY [TeISeOD “OL00-O-€2-ZZMOVG 3081QUOD *AaR}UeD YOIeasey BZuTIseuT3Uq Te seOD
"S'N “AL "S| -92 ‘ou zeded Teotuyoey, ‘1eqUeD YI1ReSey BUTIveUTSUY "S°N CAL «°G{-92 ‘ou azoded TeoTuyse, ‘taqUeD yoreesey BuTrseuT3uq
qeqseop “sn : setaeas “TIT ‘*toyjne qutof ‘*N 1e3eq *A1879eTS “II qTeaseop *s'n : Setzeg “IIT ‘“soyane qupof ‘*y azeqeqg ‘41099eTS “IT
‘OTATL ‘I *sETeO ‘keg Aezoquow *¢ ‘“Tesodstp Tfods *Z *soyjueg *| ‘OTATL *I ‘FTTeO ‘heg Aotaquoyl *¢ ‘Tesodstp Tfods *z ‘soy ueg *|
*pessnosTp aie saTiTTTqe eat onpordez pue *passnosTp o1e seTITTTqe eATAOnpordesz pue
uoyT3nqT43stp Teuney pue ‘Ax9A0Ie1 puke UOTIEZTUOTODeI Juanbaesqns ‘TeT4 uoTynqtTiqystp Teunez pue ‘ATeaAOeT pue UOTIeZTUOTODeA1 JQuenbesqns ‘TeTI
-a}eu pespeip jo Tesodstp pue BuTspeip jo sqoazze ‘sadueyo ATT TGeIS -o}eU pespeip jo Tesodstp pue BuTspeip jo sqoezjyo ‘sasueyo AITTEWQeIS
aqeijzsqns pue ses’eTquesse OTYyjUeq UT suOTJeTIeA Terodwez TeINjeN aqeaqzsqns pue sa3etTquasse oTYyJUeq UT suOoTJeTIeA TertoOdwWaz TeinjeN
‘79 *d : Aydearsotpqrg °zg ‘d : Aydea30tTqT@
(0100-9-€4 -2<MOVvd (0100-0-€2-zZmova
{ daquep yoieesey BupieeuTsug TeISeOD = JORIIUOD) OSTY (G1 -9/ “OU § 10quUe9 YyOITeesoy BuTAsveUuTSUq Te seoD =- 39B19U0D) OSTY (G1-9/ “OU
$ zeque9 yoreesey BuTiseuTsugq [TeqseoD - aeded TeoTuyoeL) “TTT “dig $ qeque9 yoIeesey ButTrseuT3ug ~Teqseog - aoded Teotuyoey) “TIT : ‘d 1g
“9/6, ‘teqUeD YD1eeSey BuUTIeeUuTSUq TeISeOD *S'N : “BA 976, ‘2equeQ yoreesey BuTieeuTSug Teqseog “SN : “EA
SatoaTog ‘34 — *42099"TS “N JOeqeg pue AeATTO *S UYyoL Aq / eTUIOFTTeD “atoateg ‘iq — *h1099eTS *N 4090q pue AeATTO *s uYyor Aq / eTUIOFTTED
‘keg AviejuoW je soyjueq euos uo Tesodstp pue BSuTspeip Jo szoeTFq ‘keg AazaquoW ye soyjUueq aos uo TesodsTp pue BuTSperp jo sq0esIq
"Ss uyor *2e8ATTO *s uyor ‘12ATTO

d31gcn* Le9 Gh=92 500 da,gcn° €072OL

“OL00-0-€2-ZZMOVA 29e81}U0D *Aa}zUeD YOIeeSey ZuTiseuTsuq Te zseoD

"S°N “AL “SL-92 ‘ou azeded Teotuysey ‘“1eqUeD YyDAeeSey BuTseUuT3Uq

Teqseo) *S'N : SaTzesg “ITI ‘*‘Aoy;ne AutTol ‘°N Aaqeg SAzAIIeTS “IT
“OTITL “I «‘stTeD ShAeg Aerequoy *¢ ‘*Tesodstp [tods *z ‘soyjqueg “|

*passnosTp aie SoTITTLqe eATIONpoadesa pue

uotqnqtajstp ~Teuneyz pue ‘AxaAODaT pue UoT}eZTUOTOVeA JUuanbasqns ‘TeTI

-a}]eu pespeip jo Tesodstp pue 3uTspeip jo sjzoezza Ssasueyo AQTTTqGeIS
ajeiqsqns pue sa8eTquesse ITYy}Ueq UT SUOTJeTIeA TeATOdwajz TeinjeN
"7g ‘d : AyderZ0TT qt

(OL00-9-€2-ZZMOVa

{ Jaquep yoieasey BuTiseuTsuq Teqyseog = 39e172U0D) OSTY (G1 -92 ‘OU
Jaques) yoieesey ButTieeuT3suq ~Teqseop - aeded TeotTuyoeyl) “TTT : *d 1g

"9/6, ‘1aqUeD YOTeaSay BuTAveuTSuq TeIseoD *S*n : “eA

“AToATeg *Iq — *A41997PTS “N 1070q pue ABATTO *S UYyoLr Aq / eTUIOFTTeD
‘keg AvteqzUOW Je SOYJUaq euos uo TesodsTp pue BuUTZspeaAp Jo sjdeFIq

*s uyor ‘12aATTO

daigcn* £79 GL-9L°0u daygsn° €07OL

“OLO0-D-€2-ZZMOV 29RAQUOD “*1e}UaD YDIeesey BuTAseUTZUY TeIsSeOD

“S°N “AL “GL-9Z *ou azoded Teotuyoey, *1raquUeDQ YOIeAasay BupTrvoUuT3Uuyq

yTeyseop *s*n : SeTtesg “TIT ‘*zoyane jutof ‘*y aaqeg £A41099eTS “II
“OTITL °I «‘*FtTeo SAeg Aezejquojyy *¢ ‘*Tesodstp [Tfods *z ‘soyjueg *]

*possnostp e1e seTITTTqe sat ONporadez pue

uoTINGTAISTp TeuneFz pue *AaAODeAT puke UOTJezTUOTODeI quanbesqns ‘TeTI

-9]eU paespeip jo [Tesodstp pue Buy3speip jo sjzoezzo Ssasueyo ARTTTqGeqIS
ejJeiqjsqns pue seseTquesse oTYyUeq UT SUOTJeTAeA TeroOdue} TeinjeN
“79 *d : AydersoTTqta

(0L00-0-€2-ZZMOVa

£ Taquep yoieesey BuTTseuTsug TeIseog - JOeI.UOD) OSTY (GL -9/ ‘ou
Jajue) yAeesey BuTAseuT3uq Te yseop - azeded TeoTuydel) “TIT : *d 1g

“OL6| ‘IeqUeD YOIeeSsey BuTiveuTSuq TeqseoD *S'Nn : “eA

‘aToaTeg ‘34 — *AI973ETS *N 1030q pure APATTO “Ss uYyor Aq / eTUIOFTTED
‘keg Aazejuoy] Je soyqueq swos uo Tesodstp pue ZuT3speip jo sqoezTq

“Ss uyor *29ATTO

dargcn: as) GL-9/*ou dargcn* €07ZOL

“OLOO-O-€2-ZZMOVG 39819U0D *1a}UaeD YOTPeSeYyY BuTAsouTZUq [Te IsSeoD

“S'N “AI ‘G1-92 ‘ou aeded Teotuyoey ‘1eqUeD YOARSeSSy BuTAsvsuTsuq

qTeaseop "S*n : Setzeg “JIT ‘Azoyjne qutol ‘*y azaqjeq £h1999"TS “II
“OTITL “1 6*FTTeD SAeg Avtaquow *¢ ‘Tesodstp [Ttods *Z ‘soyjueg ‘|

*passnosTp oie SaTIT[TTqe vATIONpoadata pue

uoTINqtaAISTp Teuneyz pue ‘AzaAODaI pue UOTJeZTUOTODeA JQUenbasqns ‘{TeTIz

-2}eWU paspeip jo [esodstp pue Burspeip jo sjoeyze ‘sadueyo AAT[TTqGeqIs
ajeiqsqns pue sas’eTquesse ITYyJUeq UT sUOTJeTIeA TetoOdweq TeinjeN
"79 *d : Aydeasorpqrg

(OL00-9-€4-cZMOva

£ Jequeg yoieesey BuTIseuTsuq Te seo) - 39e1U0D) OSTY (G1 -9/ “OU
Jejue) ydieesey ButTrseuTsuq Teqseog - 1eded Teotuyosey) “TTT : *d 1g

"9/6, ‘2e}Uag YOAeVSay BuTAsvouTZuyq Teqyseong *S*n : “eA

“ITOATag “Iq — *A1077ETS °N Je}eq pue AeATTO *S uYyor Aq / eTUIOZTTeD
‘Keg AavraqUoW 3e SoYyjueq awos uo Tesodstp pue BuTspeip jo sqzoesFq

"gs uyor *19ATTO

dapgcn* L729 GSU dargcn* £02OL

"OLO0-O-€2-ZZMOVG 2ORAQUOD ‘*TajUeD YoOAReSey BuTAseuT3Uq Te seo)

"S°*N TAL “GL -92 ‘ou aaeded [TeotTuysey ‘*1eqUe9 YoAeVseoy BSufrseuT3uy

pTeaseop *s*m : Setaeg “TI ‘zoy;ne qutol ‘°N azaqeg £h1099eTS “IT
“OTITL “I “3TTeD ‘Aeg Aozejuoyy *g ‘Tesodstp [Tfods *Z ‘soyjueg *|

*pessnostp ete set TT Tqe aAtzOnpoidez pue

uoT4nqtajsTp Teunez pue ‘k19AODIeA pue uoTezTUOTOVeI JUanbasqns ‘TeTI

-9}eW pespeip jo ~Tesodstp pue 3uTspeip jo sjzoezzo ‘sadueyo ATT TqQeIS
aqeazqsqns pue sadeTquasse oTYyJUeq UT sUuOTJeTIeA TerOdweq TeInjeN
"zg *d : Aydearz0tT qQTg

(OL00-0-€2-ZZMOva

{ 1a}uUa9 YyO1eesey BuTissuTSug Te}seoD = 39e19U0D) OSTY (G|-9/ ‘ou
4ejuep yoreesey BuTAveuTSug Teqseog - teded [eotuyder) “TIT : *d 1g

“9/6, ‘1e3Ue9 YOIeeSey BuTAseuT3uq TeqseoD *S*Nn : “eA

*atoateg *3q — *A1097eTS “N 1990q pue ABATFTO *S uYyor Aq / eTUAOFTTED
‘keg AvTaUOW Je SOYJUsq oWOS uo TeSsOodsTp pue BuT3peip jo sqIeTTY

*s uyor ‘19ATTO

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