Stanislaus County Almond Pest
Management Alliance Project
2001 Final Report
Roger Duncan, UCCE Farm
Advisor, Stanislaus County; Walt Bentley, IPM Advisor, UC Kearney Agricultural
Center, Parlier; Cara Cross & Clinton Bowman, Field Technicians, Stanislaus
County UCCE; Merlyn Garber, grower; Art Bowman, pest control advisor, Salida Ag
Chem
Objectives of the Stanislaus
County Almond Pest Management Alliance project:
·
To scientifically evaluate
the long-term effectiveness and economic viability of less broadly toxic pest
management programs.
·
To extend gained information
to the almond industry.
·
To demonstrate IPM monitoring
techniques and decision-making processes.
We
have completed our third season in the Stanislaus County PMA trial.
The original three pest management regimes were maintained similar to the
first two years (grower’s standard practice and two “reduced risk”
treatments). Because reject levels
have been very low for all three pest management regimes during the first two
years, a fourth, “untreated” program was added in 2001.
Each pest management program is replicated three times within a 120 acre
Nonpareil: Carmel orchard west of Modesto.
Each plot is approximately 13.5 acres in size.
The treatments are:
1) Grower’s Standard Practice:
(fairly common in the Northern San Joaquin Valley).
¨ A dormant application of Asana® (a
pyrethroid), 6 gallons of oil, & 8 lb. Kocide®.
¨ A May spray with an organophosphate (Lorsban).
¨ Omite® if needed for mites.
¨ Lorsban for ant control.
2) Soft Program #1:
¨ A dormant application of copper & oil (no
insecticide).
¨ A “bloom” spray of Success® at ~
30% PTB emergence (piggy-backed with fungicides).
¨ A May spray of Confirm®.
¨ Savey® for mites if monitoring deems
necessary.
¨ Clinch® (Abamectin) bait for ants if
monitoring deems necessary.
3) Soft program #2:
¨ A dormant application with oil only.
¨ Two “bloom” applications of Bt (@ ~20% PTB
emergence & ~ 80% emergence).
¨ Two May sprays of Bt (300-350 & 450-500 DD
after biofix).
¨ Potassium nitrate & oil for mites if
monitoring deems necessary.
¨ Esteem® bait for ants if monitoring
deems necessary.
4)
“Untreated”: only
mites and ants are controlled if necessary.
¨ No dormant copper, oil, or insecticide
application.
¨ No bloom Bt applications.
¨ No May or hull split sprays.
¨ Potassium nitrate & oil for mites if
monitoring deems necessary.
¨ Esteem® bait for ants if monitoring
deems necessary.
Overwintering nuts (“mummies”) were removed
and destroyed in all treatments to reduce overwintering naval orangeworm.
Cover crop management, fertilization, and fungicide treatments were the
same for all treatments other than no dormant copper was applied in “soft
program #2” and the “untreated” areas.
Monitoring:
Each
plot had two PTB pheromone traps, two SJS pheromone traps, four sticky tape
traps for SJS crawlers, and two NOW egg traps for a total of 120 traps in the
trial. PTB and NOW traps were
checked twice weekly while SJS pheromone and sticky traps were monitored weekly
throughout the season (March through October).
In addition, mites and mite predators were monitored bi-weekly with the
presence / absence leaf sampling technique.
Ants were monitored periodically using hotdog bait traps.
In the dormant period, spurs were sampled to monitor SJS populations.
Results:
Peach Twig Borer.
Early in the season, PTB moth catches were roughly half as high in areas
treated with Asana or Success compared to “untreated” or Bt treated areas.
Most of the difference was due to a peak of moths caught May 9 in the Bt
treated and untreated areas. After
May, PTB moth catches were very similar for all treatments (Fig. 1).
By the end of the season, cumulative moth catches were also very similar
for all treatments and showed no clear advantage to dormant and in-season
spraying (Fig. 2).
Mites. Brown
almond mite (BAM) feeding damage was most severe early in the year and mostly
restricted to individual trees within the orchard. In this trial, BAM numbers were highest in untreated areas
(Fig. 3). On the first date of mite
monitoring using the presence / absence method (May 22), about 15% of leaves
sampled from untreated trees had BAM. The
dormant oil and Bt treated trees had approximately 7% infestation while the
dormant oil & Success or Asana treatments each had approximately 2%
infestation. By mid-July, BAM
numbers were similar for all programs. By
the end of August, no BAM were found on sampled leaves.
Very few European red mites were found in the trial.
It is very difficult to draw conclusions from the
spider mite data. Due to lengthy
pre-harvest interval and re-entry restrictions, miticides can be applied no
later than about one month before harvest.
Even though two-spotted mite numbers in 2001 were higher than the
previous two years, none of the treatment areas had reached economic thresholds
by the time mite sprays had to be applied.
Despite leaf infestation levels of only about 12%, all areas were treated
for mites on July 19 & 20 (treatment threshold is approximately 33%
infestation). The “untreated”
areas were sprayed a second time with potassium nitrate and oil on August 3. Despite spraying, spider mite levels exceeded the treatment
threshold on August 21in all but “Soft” program #1 (Fig. 4).
Areas treated with a dormant applied pyrethroid did not develop higher
mite numbers than areas that did not receive dormant or in-season insecticide
sprays. However, each area was
treated with different in-season miticides with differing efficacies and
residual effectiveness, making it difficult to draw sound conclusions.
In the future, all areas will be treated with the same in-season miticide
to alleviate this problem.
San Jose scale and scale parasitoids.
In general, SJS numbers were very low in this trial.
Untreated areas (areas not sprayed with oil or an insecticide) had higher
pheromone trap catches than areas sprayed with dormant oil.
Cumulative season totals for the grower’s standard, soft program #1,
soft program #2, and “untreated” areas were 92, 30, 33, and 320 scale caught
per trap. As in previous seasons,
approximately twice the number of scale parasitoids were caught in areas that
were not sprayed with dormant Asana and in-season Lorsban (Fig. 5).
The vast majority of parasitoids caught were Encarsia
sp. although Aphytis sp. were also
present in the orchard. Ratios of
parasitoids to scale were very high (70:1) in the two treatments that received
dormant oil sprays but no dormant or in-season insecticides.
Although the “untreated” areas had high numbers of parasitoids, these
areas also had the highest scale numbers resulting in a less favorable
parasitoid to scale ratio (6:1). Observations
over future seasons will determine if high parasitoid numbers in untreated areas
can maintain scale levels below economic thresholds without the use of oils.
Spur samples collected after the 1999 and 2000
growing seasons showed almost no SJS present in any of the treatments.
Samples will be collected in January 2002 to determine scale numbers
overwintering from the 2001 season.
Ants. Bait
materials (Esteem and Clinch) were applied approximately five weeks prior to
harvest (July 19) in the two “soft” treatments and in “untreated” areas.
No ant treatment was applied in the grower’s standard treatment.
Ants were monitored on July 17 (prior to treatment) and again just after
harvest. Twenty vials containing
pieces of hot dog were placed throughout each replication in early morning and
collected after 3-4 hours. Vials
were transported back to the lab and put into a freezer.
After 24 hours, frozen ants were identified and counted under a
dissecting microscope. Almost all
ants collected were identified as black pavement ants with only an occasional
southern fire ant captured. Just after Nonpareil harvest, ants were again
collected and counted. Fewer ants
were caught in the reduced risk program areas in the pretreatment samples (Fig.
6). This may have been due to a
carry over effect from bait materials used the previous season.
By harvest, there were very few ants in any of the treatments.
Harvest Evaluation:
At
harvest, 500 almonds were randomly collected from each replication (1500 per
treatment) and examined for insect damage.
Reject levels for all treatments were very low.
There were no differences between treatments from damage due to NOW or
PTB (Table 2). The grower’s
standard treatment had high ant damage in one of the three replications,
resulting in an average of 1.8% ant damage over all.
Areas treated with Clinch or Esteem baits had 0.1 – 0.2% ant damage.
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Table 2. Harvest
Evaluation of Nonpareil Almonds Farmed Under Four Pest Management Programs. Stanislaus
County Almond PMA Trial, 2001 |
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Treatment
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%
NOW |
%PTB
|
%
Ant |
Total
% Rejects |
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|
Standard |
0.1 |
0.1 |
1.8 |
1.9 |
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|
Success |
0 |
0 |
0.1 |
0.1 |
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|
Bt |
0.1 |
0.1 |
0.2 |
0.4 |
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|
Untreated |
0.2 |
0.1 |
0.1 |
0.4 |
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Costs
Associated with Four Almond Pest Management Programs* Stanislaus
County Almond PMA Trial, 2001
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TREATMENT |
APPLICATION
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COST PER PLANTED ACRE |
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Grower’s
Practice (RED) |
Dormant Spray (1-20-01) |
Asana XL @ 8 oz
Kocide DF @ 8 lb.
Gavicide Super 90 @ 6 gal Application costs: Subtotal: |
$8.00 $18.58 $16.73 $13.65 $56.96
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May Spray (5-14-01) |
Lorsban 4E @ 4 pints
Nu-Film 17 @ 12.8 oz Application
costs: Subtotal: |
$23.89 $3.36 $13.65 $40.90
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Mite Spray (7-20-01) -spot sprays to 17.9 acres (45% of plot acreage) |
Omite 6E @ 2.5 pints
Nu-Film 17 @ 12.8 oz Application
costs @ $13.65 per treated acre Subtotal:
|
$16.47
$1.51
$6.14 $24.12
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TOTAL PROGRAM COSTS
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$121.98
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“Soft” Program #1 (WHITE) |
Dormant Oil
& Copper Spray (1-22-01) |
Kocide DF @ 8 lb.
Gavicide Super 90 @ 6 gal Application
costs Subtotal
|
$18.58 $16.73 $13.65 $48.96
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Bloom Spray (3-12-01) (piggy-backed
with fungicide spray) |
Success @ 4 oz Application
costs Subtotal
|
$23.46
$0.00 $23.46
|
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May Spray (5-9-01) |
Confirm 2F @ 1 pt Application
costs Subtotal
|
$25.16 $13.65 $38.81
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Mite Spray (7-20-01) -spot sprays to 17.2 acres (43% of plot acreage) |
Savey @ 4 oz
Nu-Film P @ 6 oz Application
costs @ $13.65 per treated acre Subtotal
|
$31.21
$0.57
$5.87 $37.65
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TOTAL
PROGRAM COSTS |
$148.88
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“Soft” Program #2 (BLUE) |
Dormant Oil
Spray (1-22-01) |
Gavicide Super 90 @ 6 gal Application
costs Subtotal
|
$16.73 $13.65 $30.38
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Bloom
PTB Sprays (piggy-backed with one fungicide spray) (3-13-01) (3-22-01) |
Dipel DF @ 1 lb. (3-13-01) Application
costs
Dipel DF @ 1 lb. (3-22-01) Application
costs Subtotal
|
$10.78
$0.00 $10.78 $13.65 $35.21
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May PTB Sprays (5-10-01) (5-18-01) |
Dipel DF @ 1 lb. (5-10-01)
Nu-Film P @ 6 oz Application
costs
Identical second application (5-18-01)) Subtotal
|
$10.78 $1.32 $13.65 $25.75 $51.50
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Spot Mite
Sprays 7-19-01
– 30% of area
8-3-01 – 28%
of area |
Potassium
nitrate @ 10 lb / 100 applied @ 200 gpa
Super 90 oil @ 1.5 gal / 100 applied @ 200 gpa Application
costs Potassium
nitrate @ 10 lb / 100 applied @ 200 gpa
Super 90 oil @ 1.5 gal / 100 applied @ 200 gpa Application
costs Subtotal
|
$1.80
$2.51
$4.10
$1.57
$2.19
$3.82 $15.99
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TOTAL
PROGRAM COSTS |
$133.08 |
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Costs
Associated with Four Almond Pest Management Programs* Stanislaus
County Almond PMA Trial, 2001 (Continued) |
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TREATMENT |
APPLICATION
|
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COST PER PLANTED ACRE |
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“Untreated”
(ORANGE) |
Dormant Spray |
(none) |
$0.00 |
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|
Bloom
PTB Sprays |
(none) |
$0.00 |
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May PTB Sprays |
(none) |
$0.00 |
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Spot Mite
Sprays 7-19-01
– 30% of area
8-3-01 – 28%
of area |
Potassium
nitrate @ 10 lb / 100 applied @ 200 gpa
Super 90 oil @ 1.5 gal / 100 applied @ 200 gpa Application
costs Potassium
nitrate @ 10 lb / 100 applied @ 200 gpa
Super 90 oil @ 1.5 gal / 100 applied @ 200 gpa Application
costs Subtotal
|
$1.80
$2.51
$4.10
$1.57
$2.19
$3.82 $15.99
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TOTAL
PROGRAM COSTS |
$15.99 |
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*Costs
do not include ant treatments because the grower’s standard treatment was not
treated for ants.
Conclusions:
After 3 years of intensive monitoring, we have not
seen an increase in any pest in the two “soft” treatment programs compared
to the standard grower’s practices. There
also have not been any differences in rejects due to PTB, NOW or ants at
harvest. In 2001 we added an
“untreated” program where no sprays are applied to control NOW, PTB or SJS.
This program does allow for mite management with potassium nitrate and
oil and for ant control with bait. After
one year, there is no indication of increased populations of NOW, PTB or ants in
these untreated areas. Harvest
reject levels were also very low and similar to treated areas.
It is clear SJS parasitoids are significantly
reduced in areas where a pyrethroid is applied in the dormant period and an
organophosphate is applied in-season. In
the two “soft” programs where oil was applied in the dormant period,
extremely low levels of scale were caught in-season and very high numbers of Encarsia
scale parasitoids were present. In
these areas, 70 Encarsia parasitoids were caught for every 1 SJS, a very
high ratio of parasitoids to the pest. In
the grower’s standard practice treatment, SJS numbers were also low but
parasitoid numbers were only half as high as in the other three programs,
leading to a ratio of 12 parasitoids to 1 scale.
In the northern San Joaquin Valley, almond and stone fruit orchards
rarely have significant damage from SJS whether orchards are treated with
insecticides or not. However, in
areas where SJS is a serious threat, growers should understand that the use of
some insecticides could exacerbate their scale problems.
In the untreated program where no dormant oil was applied, high
parasitoid numbers were present but SJS numbers were significantly higher than
the other treatment programs (a ratio of only 6:1).
Although scale numbers were still too low to cause concern, these areas
will need to be watched closely in the future to determine if natural predation
will be enough to keep SJS under control.
Brown almond mite numbers were highest in the
“untreated” areas. This could
be expected because dormant oil can kill mite eggs.
However, BAM numbers were not serious and obvious feeding injury was
limited to a few isolated trees. Even
this amount of feeding could not be expected to cause economic levels of damage.
There was no clear relationship between pest
management program and spider mite numbers.
It has been shown in other experiments that the use of broad-spectrum
insecticides, primarily pyrethroids, can lead to large increases in spider
mites. This has not been observed
in the three-year duration of this trial. However,
miticides have been applied each year before mite levels have reached
established threshold levels. This
is largely because conventional miticides have lengthy re-entry and pre-harvest
intervals (Omite is 28 days). This
leads many growers to apply these materials for “insurance” even when mites
are present in low levels. If a
miticide is not applied and then mites build shortly before harvest, growers are
unable to treat and thus risk defoliation.
In addition, the use of different miticide materials with different
efficacies and residual levels makes it even more difficult to interpret the
effects of dormant and in-season sprays on mites.
Beginning in 2002, one miticide with the shortest pre-harvest interval
will be used in all treatment programs.
Very few ants were captured on the harvest
sampling date even though no treatment for ant control was applied in the
grower’s standard program. This
orchard had a moderate infestation of Fuller’s rose beetle, which lays its
eggs in micro sprinklers and clogs them. The
entire trial area was sprayed with Lorsban shortly before harvest to control
this pest. It is certain that this
spray substantially reduced ant numbers in all treatments.
It will be valuable to observe if the bait products hold ant populations
down into the 2002 season.
In the spring, areas treated with and without
dormant copper were examined for brown rot and shot hole diseases.
No brown rot strikes were observed in any treatment.
In addition, very few shot hole lesions were observed on the fruit and no
treatment differences were detected. It
is doubtful that dormant applied copper has a significant effect on brown rot or
shot hole if a strong bloom-time fungicide program is maintained.
We have shown over the past three years that
almonds can be farmed without some of the more traditional broad-spectrum
insecticides and still have very low damage to the crop, at least in cases where
pest pressure is low. In addition,
using only dormant oil and in-season sprays that do not harm scale parasitoids
may better control SJS than a “conventional” program.
However, programs that utilize newer reduced risk materials are often
more expensive than using pyrethroids and organophosphate insecticides.
In our trial, the “soft” program #1 using Success, Confirm and Savey
was the most expensive program, a cost increase of 22% over the grower’s
normal practice. Soft program #2
utilizing Bt and Savey cost 9% more than the grower’s normal practice.
The cost increase in the Bt program was largely due to increased labor
and equipment costs where two applications at bloom and in May were required
instead of the normal single application required with more conventional
insecticides. Under present
economic conditions, almond growers cannot afford to adopt practices that
increase their costs. The
“untreated” program was the least expensive by far in this trial (only 13%
of the grower’s standard program). However,
leaving orchards completely untreated increases the risk of experiencing
periodic economic damage. Although
there was very little insect feeding in the untreated areas in 2001, more years
of observation are necessary to evaluate the long-term consequences of this
practice. Better monitoring
techniques to determine treatment thresholds for PTB and SJS need to be
developed before almond growers can reduce pesticide usage with confidence.