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Research Note
PNW-RN-498
December 1990

Abstract

Introduction

Mammoth Lakes Revisited—
50 Years After a Douglas-fir
Tussock Moth Outbreak .

Boyd E. Wickman and G. Lynn Starr

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For five decades after an outbreak of Douglas-fir tussock moth (Orgyia Resndotsuacta
(McDunnough)), radial growth of defoliated white fir trees (Abies concolor{Gord. &
Glend.) Lindl.), was significantly greater than that of nondefoliated hest tres nearby.
The increased growth probably was due to the thinning effect, a oS moffality and
increased nutrient availability.

Keywords: Douglas-fir tussock moth, white fir, tree growth.

One of the earliest recorded Douglas-fir tussock moth (DFTM; Orgyia pseudotsugata
(McDunnough)) outbreaks on white fir (Abies concolor (Gord. & Glend.) Lindl.) oc-
curred at Mammoth Lakes, California, from 1936 to 1938 (Wickman and others 1973).
A 5-acre plot was established there in 1938 to study the effects of defoliation. This
infestation caused mortality (30 percent of the stand), growth loss, and top-kill
(Wickman 1963). The plot was reestablished in 1970 to investigate pathological-
entomological relations on top-killed trees (Wickman and Scharpf 1972). In 1977

the plot was relocated, boundaries were marked, and selected trees were cored for
measurement of radial growth of survivors. We found that radial growth of defoliated
white fir was significantly greater than that of nondefoliated host trees nearby for 36
years after the outbreak, but in 1977 growth of all trees declined sharply as a result
of a severe drought (Wickman 1980).

Information on long-term effects of DFTM outbreaks on growth of host trees is rare
but has been recorded for a few sites in California and Oregon. A study 10 years
after a DFTM infestation in northeastern California showed that growth of both host
and nonhost trees in the defoliated area surpassed preoutbreak rates, but the reverse
was true for nearby nondefoliated trees (Wickman 1978). The same area was re-
measured 20 years after the outbreak with similar findings, but nonhost pine basal
area has increased 32 percent (Wickman 1988). Radial growth measurements 10
years after a DFTM outbreak of grand fir (Abies grandis (Dougl. ex D. Don) Lindl.)
and Douglas-fir (Pseudotsuga menziesii var. glauca (Beissn.) Franco) in northeastern
Oregon showed a similar relation: postoutbreak growth of defoliated trees was sig-
nificantly greater than preoutbreak growth (Wickman 1986b). But in another old out-
break area in the central Sierra Nevada, there was little difference between preout-
break white fir growth and growth 30 years later (Wickman 1986a). The actual de-
foliation history of the sample trees was unknown in this study because the old re-
search plots were destroyed by fire. The sample could have been taken in an area
of light or moderate defoliation, in which case little or no thinning effect may have
resulted from outbreak-caused tree mortality, and the defoliated stands were also on
better sites than those in other study areas (Wickman 1986a).

BOYD E. WICKMAN is chief research entomologist
and G. LYNN STARR is a computer analyst, Forestry
and Range Sciences Laboratory, 1401 Gekeler Lane,
La Grande, Oregon 97850.

Methods

The increased growth found at the Mammoth Lakes Study area nearly 40 years after
a DFTM outbreak subsided and the fact that the stand was still being protected from
harvest by the Inyo National Forest encouraged us to make a 50-year postoutbreak
measurement of tree growth in 1987. In addition, we wanted to know how the dif-
ferent classes of trees would respond after the severe 1976-77 drought. Would de-
foliated white fir growth regain the predrought dominance exhibited in the 1977
measurement?

The study area is in the Inyo National Forest on the east side of the Sierra Nevada
several miles north of Mammoth Lakes Ranger Station. Elevation is about 8,000 feet.
The mixed conifer stand is composed mainly of white fir and Jeffrey pine (Pinus
jeffreyi Grev. & Balf.) but also contains scattered California red fir (Abies magnifica
A. Murr.) and lodgepole pine (Pinus contorta Doug.). Before the outbreak, the live-
tree volume of white fir was 36,400 board feet per acre. Volume of pine was not
recorded. Many old-growth white fir were killed by secondary insects shortly after
the infestation. A total of 10,900 board feet per acre or 29.9 percent of the stand
was dead by 1942. In 1945 the area was Selectively logged for some old-growth
pine and any remaining overmature fir. The first relogging took place in spring 1970,
when about 2,000 board feet per acre was removed in a Sanitation cut (removal of
top-killed, diseased, or damaged trees).

Sample size was limited by lack of long-term records and the area of the plot avail-
able for measurements. Twenty dominants or codominants were selected from each
of three tree classes: defoliated white fir, nonhost Jeffrey pine on the defoliated plot,
and nondefoliated white fir nearby. Eight Jeffrey pine also were sampled on the non-
defoliated site. The defoliated white fir were on the 1938 plot; on average, defoliation
in 1938 was 53 percent but ranged from 10 to 100 percent. In 1987, white fir average
age was 125 years, and diameter at breast height (d.b.h.) was 30 inches. The Jeffrey
pine on the plot averaged 186 years in age and 35 inches in d.b.h. Because of the
small size of the plot (5 acres), every dominant or codominant fir and pine was in-
cluded in the sample in addition to three white fir and two pines that were boundary
trees and may or may not have been on the original plot. Because the plot was in
the middle of the 600- to 1,000-acre 1938 infestation, exact location of the trees was
not considered critical.

Twenty nondefoliated white fir were located in a similar stand 1 to 2 miles northwest
of the plot. Average age was 151 years, and average d.b.h. was 30 inches. Four
Clusters of five dominant or codominant fir were selected, each in a 2- or 3-acre area
every 0.25 mile along an old logging road. These trees were not always the same
white fir that were measured in 1977 because one of the clusters had been logged
just before the 1987 visit. Increment cores taken in 1977 showed that growth of all
check trees had increased rather than declined during 1937 and 1938, an indication
that the area was outside the main infestation (fig. 1). The check spots were similar
to the defoliated plot in elevation, soil, plant cover, tree species, and stocking and
had been logged at the same time, except for new logging in 1987. In addition, two
dominant or codominant Jeffrey pine were cored at each of the four nondefoliated
Clusters. Average age of the pine was 171 years, and average d.b.h. was 36 inches.

Results and
Discussion

on

Outbreak and growth loss —»>

5S

()

—_

Radial increment (mm)

(0) :
1900 1910 1920 1930 1940 1950 1960 1970 1980
Year
— Defoliated host ---- Nondefoliated host
Sennen Plot Pine —= Off-plot pine

Figure 1—Average annual radial growth of white fir and Jeffrey pine at Mammoth Lakes, DFTM
outbreak area.

From each tree at breast height, two increment cores were taken 90 degrees from
each other (usually from the north and west quadrants). Cores were glued to blocks
of wood and measured on an incremental measuring machine integrated with a
desktop computer. Cores were averaged for each tree and each class. Analysis of
variance was used to determine if radial growth differed among the four classes of
trees or between time periods. A least significant difference (LSD) test was used to
compare the individual means.

In the 1977 study, analysis of variance of growth rates for the 36-year preoutbreak
period (1900-35) showed no significant difference (P > 0.05) between defoliated and
nondefoliated fir trees. The pine grew slower than both defoliated fir and nondefoliated
fir throughout this period. Fluctuations in growth during this period were similar for all
tree classes, an indication that all classes probably were affected similarly by environ-
mental factors, mainly precipitation (Wickman 1980).

During the 36 years after the outbreak (1942-77), defoliated fir grew considerably
faster than nondefoliated fir (fig. 1). Thus, the defoliated fir grew faster during the
entire postoutbreak period, even though rates for nondefoliated and defoliated trees
were similar before the outbreak (Wickman 1980).

From 1978 to 1987, more than 40 years after the outbreak, analysis of variance of
growth rates and the LSD test showed significant differences (P < 0.01) between
defoliated fir and the other three classes and between both nondefoliated fir and
Jeffrey pine and off-plot Jeffrey pine (table 1). This relation is evident in figure 1,
which shows defoliated white fir with the highest growth rate, nondefoliated white fir
and on-plot Jeffrey pine with lower and almost identical growth rates, and off-plot
Jeffrey pine with the slowest growth.

Table 1—Average annual radial growth for 4 classes of trees during preoutbreak
(1900-36) and postoutbreak (1978-87) periods

1900 1978
to to
Class Number 1936 1987
SE ee eS ee a ee ee
--- -------- Millimeters - -- ---------
Defoliated fir 20 1.80b* 3.58a
Nondefoliated fir 20 1.75b 1.98b
Jeffrey pine on-plot 20 1.36bc 1.88b
Jeffrey pine off-plot 8 .81C MG

—_—k eo Ea

* Means with different letter are significantly different at the 0.01 level.

Comparing the preoutbreak period (1900-36) with the last 10-year postoutbreak
period (1978-87) (table 1) shows that defoliated white fir are still growing significantly
(P < 0.01) faster than before the outbreak, but nondefoliated fir and both groups of
pine returned to their preoutbreak growth rates (fig. 1). The severe 1975-77 drought
depressed growth of all classes to a low and similar level, but only the defoliated
white fir rebounded to their predrought high levels. The long-term growth of defoliated
white fir was still almost double what it was before the outbreak. Unfortunately, be-
cause of logging on the study sites, this cannot be related to a comparison of net
stand growth for defoliated versus nondefoliated white fir. It therefore is not appro-
priate to infer that long-term growth response to the outbreak surpassed the short-
term tree mortality and growth losses. The outbreak-area white fir stand is similar in
appearance, however, to the nonoutbreak white fir stand in terms of age, species
composition, and stocking. Fifty years after the outbreak, both fir and pine are growing
faster on this site than on nonoutbreak sites.

The effects of thinning caused by tree mortality and the probable increased nutrient
availability during and after the outbreak may have resulted in some long-term posi-
tive growth effects that are still accruing 50 years later. The results to date indicate,
for this stand at least, that DFTM played an important role in primary forest productiv-
ity (Mattson and Addy 1975) through increased nutrient availability in these nitrogen-
deficient deep pumice soils. Similar nutrient availability enhancement has been sug-
gested by Klock and Wickman (1978) and Stoszek (1988.)

In a study reported by Alfaro and MacDonald (1988), defoliation and radial growth
reduction of Douglas-fir (Pseudotsuga menziesii (Mirb.) Franco) by the western false
hemlock looper (Nepytia freemanii Munroe) was similar to that caused by DFTM.
After recovery from defoliation, many Douglas-fir had greater than average growth
rates for 5 years; however, because there was little or no tree mortality, a thinning
effect was not a factor. They also found that the postoutbreak growth increase was
absent in the less defoliated (0 to 10 percent) tree class. At the Mammoth Lakes plot,
records of the defoliation history of individual trees have not been maintained, but 39
of the 163 trees orginally had 10 to 25 percent defoliation. Presently only 20 dominant
or codominants on the plot are large enough to have been recorded in 1938, and all
these trees exhibit enhanced growth.

Literature Cited

In other studies after DFTM outbreaks, the lightly defoliated classes (10 and 20 per-
cent) have shown enhanced growth after the outbreak (Wickman 1978, 1986b). There
are often 2 years of severe defoliation in DFTM outbreaks versus 1 year in western
false hemlock looper outbreaks, and this additional year of frass and litterfall may
help to explain the difference.

Outbreaks by DFTM in these situations provide a stabilizing feedback system (Odum
1969) that promotes the vigor and survival of host trees and may dampen or delay
for many decades future DFTM population eruptions. Because data on nutrient cycling
in forest stands before and after insect outbreaks are scarce, only continued long-
term studies will uncover these intriguing insect-plant relations. In the meantime, pest
managers should not ignore the long-term beneficial aspects of some DFTM
outbreaks.

Alfaro, R.!.; MacDonald, R.N. 1988. Effects of defoliation by the western false hem-
lock looper on Douglas-fir tree ring chronologies. Tree Ring Bulletin. 48: 3-11.

Klock, G.O.; Wickman, B.E. 1978. Ecosystem effect. In: The Douglas-fir tussock
moth: a synthesis. Brookes, M.H.; Stark, R.W.; Campbell, R.W., eds. Tech. Bull.
1585. Washington, DC: U.S. Department of Agriculture, Forest Service: 90-95.

Mattson, W.J.; Addy, N.D. 1975. Phytophagous insects as regulators of forest
primary production. Science. 1920: 515-522.

Odum, E.P. 1969. The strategy of ecosystem development. Science. 164: 262-270.

Stoszek, Karl J. 1988. Forests under stress and insect outbreaks. The Northwest
Environmental Journal. 4: 247-261.

Wickman, B.E. 1963. Moriality and growth reduction of white fir following defoliation
by the Douglas-fir tussock moth. Res. Pap. PSW-7. Berkeley, CA: U.S. Department
of Agriculture, Forest Service, Pacific Southwest Experiment Station. 15 p.

Wickman, B.E. 1978. A case study of a Douglas-fir tussock moth outbreak and
stand conditions 10 years later. Res. Pap. PNW-244. Portland, OR: U.S. Depari-
ment of Agriculture, Forest Service, Pacific Northwest Forest and Range Exper-
iment Station. 22 p.

Wickman, B.E.; Mason, R.R.; Thompson, C.G. 1973. Major outbreaks of Douglas-fir
tussock moth in Oregon and California. Gen. Tech. Rep. PNW-5. Portland, OR:
U.S. Department of Agriculture, Forest Service, Pacific Northwest Forest and
Range Experiment Station. 18 p.

Wickman, B.E.; Scharpf, R.F. 1972. Decay in white fir top-killed by Douglas-fir
tussock moth. Res. Pap. PNW-133. Portland, OR: U.S. Department of Agriculture,
Forest Service, Pacific Northwest Forest and Range Experiment Station. 9 p.

Wickman, Boyd E. 1980. Increased growth of white fir after a Douglas-fir tussock
moth outbreak. Journal of Forestry. 78: 31-33.

Wickman, Boyd E. 1986a. Growth of white fir after Douglas-fir tussock moth out-
breaks: long-term records in the Sierra Nevada. Res. Note PNW-440. Portland,
OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research
Station. 8 p.

Wickman, Boyd E. 1986b. Radial growth of grand fir and Douglas-fir 10 years after
defoliation by the Douglas-fir tussock moth in the Blue Mountains outbreak. Res.
Pap. PNW-367. Portland, OR: U.S. Department of roneute: Forest Service,
Pacific Northwest Research Station. 11 p.

Wickman, Boyd E. 1988. Tree growth in thinned and unthinned white fir stands 20
years after a Douglas-fir tussock moth outbreak. Res. Note PNW-RN-477. Portland,
OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research
Station. 11 p.

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