The Toll of Mid-Season Heat and Drought on Peanut Yield and Grade in Virginia
ID
SPES-672NP
Why This Matters to Growers
Mid-season heat and drought stress (HS+DS) severely impacts peanut growth, slashing yields by up to 50% and degrading kernel quality—key factors in market pricing (Puppala et al. 2023; Balota 2012& 2020). For Virginia-type peanuts, which command premium prices due to their large kernel size and superior grade (especially the "fancy" classification), HS+DS reduces both yield and percentage of total sound mature kernels (TSMK). This dual loss directly undermines profitability, as poor grades can offset gains from high productivity. With grade standards serving as a critical benchmark for growers and shellers, mitigating HS+DS is essential to preserving both yield and market value. This article discusses the effects of HS+DS on peanut yield and grade and highlights the importance of this combined stress.
Trial Overview
Category |
Details |
|---|---|
Location |
Tidewater Agricultural Research and Extension Center, Suffolk, VA |
Trial Duration |
17th May – 7th October 2024 |
Genotypes Tested |
6 Virginia Tech and University of Florida (VTUF) breeding lines
5 Commercial Cultivars
1 Runner Check
|
Stress Setup |
Rainfed Group: Open plots (control) (Figure 1A, B, D). HS+DS Group: Rainout shelters blocked rainfall for 70 days (July 17th – September 9th) (Figure 1A, C, D). |
Micro-Climate Monitoring |
|
Harvest |
7th October 2024 (144 days after planting). |
Yield Calculation |
Adjusted to 7% moisture: Yieldd (lbs/acre) = (Pod weight (kg) * 10000 m2 * 0.892179) / Plot area (m2) |
Post-Harvest Grading |
Conducted by Virginia Department of Agriculture and Consumer Services. Grades Tracked:
|
Key Notes from trial overview (Table 1):
- Stress Timing: HS+DS applied during critical flowering/pod-fill stages.
- Data Collection: Sensor-based monitoring ensured precise environmental tracking (Figure 2).
- Grade Metrics: Focused on market-critical traits (Fancy, ELK, TSMK) for Virginia-type peanuts.
Weather during growing season
Figure 2. Weather data including precipitation (A), soil volumetric water content monitored at ~7-inch depth (B), mean air temperature (C), maximum air temperature (D), soil temperature (E), and relative humidity (F).
Parameter |
Implications |
|---|---|
Rainfall |
Stressed plots received 52% less rain—mimicking severe drought conditions (Figure 2A). |
Soil Moisture |
60% less soil water under stress—critical during pod fill (Figure 2B). |
Avg Daily Air Temperature |
4°F increase in daily temperature stressed plants during flowering (Figure 2C). |
Maximum Daily Air Temperature |
100°F spikes during pod fill shrank kernels and reduced grades (Figure 2D). |
Soil Temperature |
Heat stress came from air, not soil—so focus should be on canopy cooling (Figure 2E). |
Relative Humidity |
Drier air increased water loss from the leaves (Figure 2F). |
How Yield and Grade Fared Across Treatments
Genotype |
Treatment |
Yield (lbs/ac) |
Fancy (%) |
ELK (%) |
SMK (%) |
TSMK (%) |
$/ac |
||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
13x101-4-5-2-1-B |
Rainfed |
5244 |
bc |
87 |
a-e |
49.3 |
ab |
66 |
a |
67.8 |
a |
1494.6 |
bc |
HS+DS |
3067 |
ef |
84 |
b-e |
36.3 |
c-f |
51 |
b-d |
52.3 |
bc |
874.2 |
ef |
|
13x101-4-5-3-1-B |
Rainfed |
5937 |
a-c |
80.5 |
b-e |
47.5 |
a-c |
64 |
a |
66 |
a |
1692.0 |
a-c |
HS+DS |
296 |
ef |
79.5 |
c-f |
31.8 |
d-g |
46 |
d |
48 |
c |
846.0 |
ef |
|
13x101-4-9-1-1-B |
Rainfed |
6234 |
ab |
84.3 |
b-e |
49 |
ab |
65 |
a |
67.8 |
a |
1776.5 |
ab |
HS+DS |
1979 |
f |
84.3 |
b-e |
28.5 |
e-g |
45.8 |
d |
46.3 |
c |
564.0 |
f |
|
14x009-1-5-1-1 |
Rainfed |
7322 |
a |
92.3 |
a |
49.8 |
ab |
68 |
a |
69.25 |
a |
2086.7 |
a |
HS+DS |
3299 |
d-f |
84.7 |
a-e |
29.3 |
d-g |
45.7 |
d |
47 |
c |
940.1 |
d-f |
|
14x039-1-3-1-1 |
Rainfed |
6333 |
ab |
82 |
b-e |
50.5 |
ab |
63.5 |
a |
66 |
a |
1804.7 |
ab |
HS+DS |
2301 |
f |
75.7 |
e-g |
22 |
g |
42 |
d |
42.7 |
c |
655.9 |
f |
|
14x085-2-10-1-1 |
Rainfed |
6234 |
ab |
84.3 |
b-e |
39.8 |
b-f |
66 |
a |
66.8 |
a |
1776.5 |
ab |
HS+DS |
2168 |
f |
72.3 |
fg |
27.5 |
fg |
50.8 |
b-d |
52 |
bc |
617.9 |
f |
|
Bailey II |
Rainfed |
5739 |
a-c |
86 |
a-e |
50 |
ab |
66 |
a |
67.8 |
a |
1635.6 |
a-c |
HS+DS |
2573 |
ef |
83.5 |
b-e |
35 |
d-g |
50.5 |
b-d |
51.5 |
bc |
733.2 |
ef |
|
Emery |
Rainfed |
4354 |
c-e |
81.8 |
b-e |
53 |
a |
68 |
a |
69.5 |
a |
1240.8 |
c-e |
HS+DS |
2293 |
f |
81.7 |
b-e |
32.7 |
d-g |
49.7 |
b-d |
50.7 |
bc |
653.5 |
f |
|
NC-20 |
Rainfed |
5046 |
b-d |
88 |
a-e |
40.5 |
b-f |
60.5 |
ab |
64.3 |
a |
1438.2 |
b-d |
HS+DS |
3265 |
d-f |
88.3 |
a-e |
27.8 |
fg |
46.8 |
cd |
48.3 |
c |
930.6 |
d-f |
|
Sullivan |
Rainfed |
5739 |
a-c |
83.5 |
b-e |
47.5 |
a-c |
65.5 |
a |
67.8 |
a |
1635.6 |
a-c |
HS+DS |
3067 |
ef |
78.3 |
d-f |
32.8 |
d-g |
46.8 |
cd |
48 |
c |
874.2 |
ef |
|
Walton |
Rainfed |
5244 |
bc |
70.3 |
g |
41.25 |
a-d |
65.3 |
a |
67.5 |
a |
1494.6 |
bc |
HS+DS |
2771 |
ef |
78.3 |
d-f |
32 |
d-g |
49.5 |
b-d |
50.3 |
bc |
789.6 |
ef |
|
PI478818 |
Rainfed |
5145 |
bc |
15.5 |
h |
27.5 |
fg |
66.3 |
a |
70 |
a |
1466.4 |
bc |
HS+DS |
2968 |
ef |
14.8 |
h |
28.8 |
e-g |
58 |
a-c |
61 |
ab |
846.0 |
ef |
|
Overall treatment means |
Rainfed |
5714 |
a |
77.7 |
a |
45.5 |
a |
65.3 |
a |
67.5 |
a |
1628.5 |
a |
HS+DS |
2727 |
b |
75.3 |
b |
30.5 |
b |
48.7 |
b |
50 |
b |
777.1 |
b |
|
Stress Treatment (T) |
|
*** |
|
* |
|
*** |
|
*** |
|
*** |
|
*** |
|
Genotype (G) |
|
ns |
|
*** |
|
* |
|
ns |
|
ns |
|
ns |
|
T X G |
|
ns |
|
ns |
|
ns |
|
ns |
|
ns |
|
ns |
|
Means sharing the same letter(s) are not statistically different, at P=0.05 based on Fisher’s LSD test. *, **, *** indicate the significant treatment effects at p < 0.05, p < 0.01, p < 0.001 respectively and ns indicates non-significant variation across treatments. ELK-Extra-large kernel, SMK- Sound mature kernel, SS-Sound splits, TSMK- Total sound mature kernel. $/ac=$/acre was calculated based on the year 2024 price of
$0.285/lb. (source: Billy Gwaltney, personal communication).
Percentage Declines in Yield and Grade Under Stress
To understand the impact of the reduction due to stress (Table 2 and Figure 2), we calculated the percentage reduction under HS+DS compared to the rainfed conditions using the following equation:
Heat and Drought: How They Hurt Peanut Profits
Key Findings at a Glance
Yield Insights |
Grade Insights |
Net Returns Insights |
|---|---|---|
HS+DS reduced yields by ~40–50% compared to rainfed conditions (5,714 lbs/ac → 2727 lbs/ac) (Table 3, Figure 3A). |
HS+DS caused a 33% decline in ELK, critical for premium pricing (Figure 3C). |
Net returns dropped from +388 $/acre (rainfed) to -198 $/acre (HS+DS) for most genotypes (Figure 4). |
| Breeding line 14x009-1-5-1-1 achieved the highest yield under rainfed conditions (Table 3). | Total sound mature kernels (TSMK) fell by 26% under stress, directly lowering market value (Figure 3E). |
NC-20 and 14x009-1-5-1-1 minimized losses (-64 $/acre) compared to other varieties (-198$/acre) (Figure 4). |
NC-20 and 14x009-1-5-1-1 maintained relatively higher yields under HS+DS (3,265–3,299 lbs/ac) than other varieties (Table 3). |
Variety Walton experienced increased fancy pod percentage under stress, suggesting trait-specific resilience (Figure 3B). |
HS+DS turned all genotypes into net losses. |
Lines 13x101-4-9-1-1-B and 14x039-1-3-1-1 lost 65–68% yield under HS+DS (Figure 3A). |
Commercial cultivars (Bailey II) retained better grade stability than most breeding lines under stress (Table 1, Figure 3 B- E). |
At $1,000/acre production costs, only NC-20 and 14x009-1-5-1-1 approached near breakeven under stress (Figure 4). |
| Yield losses were most severe due to long-term HS+DSduring flowering/pod-fill (July– September). | Lower ELK and TSMK under HS+DS reduced profitability by ~$500/acre for sensitive genotypes (Figure 3F). |
Lower grades (smaller kernels, fewer fancy pods) reduced price premiums, amplifying financial losses. |
Conclusions and Future Directions
Based on the observations from Tables 3 and 4, commercial cultivars generally maintained better grade quality under stress than breeding lines, though the latter excelled in rainfed conditions. These findings highlight the need for breeding programs to integrate stress resilience without compromising yield or grade. Repeated trials in 2025 will validate these results, guiding the development of climate-resilient peanuts to protect Virginia’s agricultural economy.
Acknowledgments
The authors would like to thank the NIFA-AFRI A1143 program for funding this study. Special thanks to Mr. Jacob Forehand, Extension Specialist at Tidewater AREC, for providing seeds and assisting with planting and harvesting. The authors also acknowledge the Crop Physiology Lab members and Tidewater AREC Technical Staff for their support during the trial.
References
Balota, Maria. 2020. “Rainout shelter-induced water deficit negatively impacts peanut yield and quality in a sub-humid environment”. Peanut Science 47(2):54-65. Balota | Rainout Shelter-Induced Water Deficit Negatively Impacts Peanut Yield and Quality in a Sub- Humid Environment | Peanut Science
Balota, Maria. 2012. “Effects of Drought and Heat on Peanut (Arachis hypogaea L.). Production.” . https://www.pubs.ext.vt.edu/content/dam/pubs_ext_vt_edu/AREC/AREC-27/AREC- 27NP-pdf.pdf
Puppala, Naveen, Spurthi N. Nayak, Alvaro Sanz-Saez, Charles Chen, Mura Jyostna Devi, Nivedita Nivedita, Yin Bao, et al. 2023. “Sustaining Yield and Nutritional Quality of Peanuts in Harsh Environments: Physiological and Molecular Basis of Drought and Heat Stress Tolerance.” Frontiers in Genetics 14 (March). https://doi.org/10.3389/fgene.2023.1121462
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