Palmer Amaranth and Velvetleaf Control in Conventional Soybean Using Overlapping Residual Herbicide Programs
The cost of soybean seed has been increasing over the years, with herbicide-resistant soybean seed cost being higher than that of conventional soybean for having a technology fee. With the depressed corn and soybean prices in recent years in the United States, growers have shown interest in conventional soybean for better after-harvest incentives. A survey conducted in Nebraska in 2015 ranked Palmer amaranth and velvetleaf among the top six most problematic weeds in Nebraska (Sarangi and Jhala 2018). In Nebraska, Palmer amaranth biotypes resistant to acetolactate synthase (ALS)-, hydroxyphenylpyruvate dioxygenase (HPPD)-, photosystem (PS) II-inhibitors, and glyphosate have been confirmed.
Weed management in no-till conventional soybean is mostly herbicide-dependent; therefore, herbicide programs should be selected carefully that provide season-long weed control and high soybean yield. Unlike Roundup Ready- or LibertyLink soybean systems, there are few “rescue” POST herbicides available in conventional soybean, meaning that a pre-emergence (PRE) herbicide application is even more critical.
Field experiments were conducted in 2016 and 2017 at South Central Ag Lab, Clay Center, NE. Pre-emergence (PRE) and PRE followed by (fb) post-emergence (POST) herbicides, and PRE fb POST herbicide with residual (POST-WR) product tank-mixed were evaluated. Herbicides applied PRE including Trivence, Optil PRO, Valor XLT, Fierce, and Authority MTZ provided 95% to 100% control of Palmer amaranth and velvetleaf at 14 and 28 days after application (Table 1). Due to decline in the residual activities of the PRE soil-applied herbicides, PRE-only programs resulted in 66% control of Palmer amaranth at 28 DAPOST compared with 86% control for PRE fb POST programs (Table 2). Most of the PRE fb POST-WR programs resulted in greater than 97% control of Palmer amaranth at 28 DAPOST (Table 2). The PRE fb POST herbicide programs substantially improved velvetleaf control (98%) over the PRE-only herbicide programs (89% control) at 14 DAPOST (Table 3).
Table 1
| Palmer amaranth controlc | Velvetleaf controlc | ||||
|---|---|---|---|---|---|
| Herbicide trade name | Herbicide active ingredient | 14 DAPRE | 28 DAPRE | 14 DAPRE | 28 DAPRE |
| --%-- | --%-- | ||||
| Trivence | Chlorimuron-ethyl/flumioxazin/metribuzin | 99 a | 97 a | 98 a | 96 a |
| Optill PRO | Saflufenacil/imazethapyr + dimethenamid-P | 100 a | 98 a | 99 a | 97 a |
| Valor XLT | Flumioxazin/chlorimuron-ethyl | 100 a | 98 a | 98 a | 97 a |
| Fierce | Flumioxazin/pyroxasulfone | 100 a | 98 a | 98 a | 98 a |
| Authority MTZ | Sulfentrazone/metribuzin | 100 a | 98 a | 97 a | 95 a |
| P-value | 0.7 | 0.09 | 0.06 | 0.13 | |
a Abbreviation: DAPRE, days after pre-emergence herbicide application.
b Data presented in this table were pooled across both years (2016 and 2017).
c Data were arc-sine square-root transformed before analysis; however, back-transformed original mean values are presented based on the interpretation of the transformed data, and the weed control data for the nontreated control plots were not included in the analysis.
d Means presented within each column with no common letter(s) are significantly different according to Fisher’s protected LSD where α = 0.05.
Table 2
| Herbicide program | Palmer amaranth controlc,d | Densityd | Biomass reductionc,d | |||
|---|---|---|---|---|---|---|
| Pre-emergence herbicide | Post-emergence herbicide | 14 DAPOST | 28 DAPOST | At harvest | 28 DAPOST | 56 DAPOST |
| --%-- | # pl m-2 | --%-- | ||||
| Nontreated control | 0 | 0 | 0 | 110 a | 0 | |
| Trivence | _____ | 76 cd | 67 ef | 42 ef | 37 b | 68 e |
| Marvel | 97 a | 90 cd | 85 bc | 10 d | 89 cd | |
| Marvel + Warrant | 99 a | 97 ab | 95 ab | 2 d | 98 a | |
| Optil PRO | _____ | 77 bcd | 61 ef | 28 fg | 42 b | 56 e |
| Cobra | 99 a | 91 c | 81 cd | 8 d | 90 bcd | |
| Cobra + Zidua | 99 a | 99 a | 97 a | 1 d | 100 a | |
| Valor XLT | _____ | 71 d | 61 ef | 36 efg | 38 b | 58 e |
| Ultra Blazer | 98 a | 88 cd | 83 c | 9 d | 86 d | |
| Ultra Blazer + Outlook | 99 a | 97 ab | 90 abc | 3 d | 97 ab | |
| Fierce | _____ | 87 b | 83 d | 67 d | 16 cd | 86 d |
| Cadet | 96 a | 92 c | 80 cd | 8 d | 88 cd | |
| Cadet + Prefix | 99 a | 99 a | 97 a | 1 d | 98 a | |
| Authority MTZ | _____ | 71 d | 58 f | 22 g | 47 b | 60 e |
| First Rate | 83 bc | 70 e | 45 e | 33 bc | 68 e | |
| First Rate + Anthem Maxx | 97 a | 94 bc | 82 c | 9 d | 96 abc | |
| P-value | < 0.001 | < 0.001 | < 0.001 | < 0.001 | < 0.001 | |
| Contrastse | ||||||
| PRE-only vs. PRE fb POST | 76 vs. 95** | 66 vs. 86** | 39 vs. 75** | 36 vs. 14** | 66 vs. 84** | |
| PRE fb POST vs. PRE fb POST-WR | 95 vs. 99* | 86 vs. 97** | 75 vs. 92** | 14 vs. 3* | 84 vs. 98** | |
a Abbreviation: DAPOST, days after post-emergence herbicide application; POST-WR, post-emergence herbicide with residual activity.
b Data presented in this table were pooled across both years (2016 and 2017).
c Data were arc-sine square-root transformed before analysis; however, back-transformed original mean values are presented based on the interpretation of the transformed data.
d Means presented within each column with no common letter(s) are significantly different according to Fisher’s protected LSD where α = 0.05.
e a priori orthogonal contrasts; ** = significant (P < 0.01) and * = significant (P < 0.05).
Table 3
| Herbicide program | Velvetleaf controlc,d | Densityd | ||
|---|---|---|---|---|
| Pre-emergence | Post-emergence herbicide | 14 DAPOST | 28 DAPOST | 28 DAPOST |
| --%-- | # plants m-2 | |||
| Nontreated control | 0 | 0 | 45 a | |
| Trivence | _____ | 93 bc | 92 abc | 7 bc |
| Marvel | 97 ab | 94 abc | 4 c | |
| Marvel + Warrant | 97 ab | 97 ab | 2 c | |
| Optil PRO | _____ | 89 cd | 88 bc | 9 b |
| Cobra | 99 a | 96 ab | 3 c | |
| Cobra + Zidua | 99 a | 99 a | 0 c | |
| Valor XLT | _____ | 93 bc | 93 abc | 8 bc |
| Ultra Blazer | 98 ab | 94 abc | 4 c | |
| Ultra Blazer + Outlook | 97 ab | 97 ab | 1 c | |
| Fierce | _____ | 89 cd | 85 c | 10 b |
| Cadet | 98 ab | 95 abc | 3 c | |
| Cadet + Prefix | 99 a | 98 a | 1 c | |
| Authority MTZ | _____ | 79 d | 67 d | 15 b |
| First Rate | 96 ab | 91 bc | 6 c | |
| First Rate + Anthem Maxx | 94 abc | 94 abc | 5 c | |
| P-value | < 0.001 | < 0.001 | < 0.001 | |
| Contrastse | ||||
| PRE-only vs. PRE fb POST | 89 vs. 98** | 85 vs. 94** | 10 vs. 4** | |
| PRE fb POST vs. PRE fb POST-WR | 98 vs. 97 NS | 94 vs. 97 NS | 4 vs. 2 NS | |
a Abbreviation: DAPOST, days after POST herbicide application; POST-WR, POST with residual.
b Data presented in this table were pooled across both years (2016 and 2017).
c Data were arc-sine square-root transformed before analysis; however, back-transformed original mean values are presented based on the interpretation of the transformed data.
d Means presented within each column with no common letter(s) are significantly different according to Fisher’s protected LSD where α = 0.05.
e a priori orthogonal contrasts; ** = significant (P < 0.01); NS, non-significant (P ≥ 0.05).
However, averaged across herbicide programs, velvetleaf control was similar in PRE fb POST-WR and PRE fb POST programs at 14 and 28 DAPOST. The year-by-treatment interaction was significant for soybean yield; therefore, yield data from 2016 and 2017 were presented separately. It is believed that the higher Palmer amaranth density in 2017 led to the lower soybean yield in all the treatments and nontreated control. Averaged across herbicide programs, PRE fb POST programs resulted in higher soybean yield compared to the PRE-only herbicide programs (Table 4). For more information read this article.
Table 4
| Herbicide program | Soybean yieldb,c | ||
|---|---|---|---|
| PRE | POST | 2016 | 2017 |
| Bushels per acre | |||
| Nontreated control | 33 g | 8 e | |
| Trivence | _____ | 54 def | 19 cd |
| Marvel | 56 bcdef | 26 bc | |
| Marvel + Warrant | 62 abc | 42 a | |
| Optil PRO | _____ | 50 f | 17 d |
| Cobra | 59 bcde | 27 b | |
| Cobra + Zidua | 67 a | 37 a | |
| Valor XLT | _____ | 56 cdef | 14 de |
| Ultra Blazer | 59 bcde | 25 bc | |
| Ultra Blazer + Outlook | 60 abcd | 29 b | |
| Fierce | _____ | 53 ef | 25 bc |
| Cadet | 57 bcdef | 28 b | |
| Cadet + Prefix | 64 ab | 40 a | |
| Authority MTZ | _____ | 52 ef | 14 de |
| First Rate | 59 bcde | 19 cd | |
| First Rate + Anthem Maxx | 58 bcdef | 27 b | |
| P-value | < 0.001 | < 0.001 | |
| Contrastsd | |||
| PRE-only vs. PRE fb POST | 53 vs. 58** | 18 vs. 25** | |
| PRE fb POST vs. PRE fb POST-WR | 58 vs. 62* | 25 vs. 35** | |
a Abbreviation: DAPRE, days after PRE herbicide application; POST-WR, POST with residual.
b Means presented within each column with no common letter(s) are significantly different according to Fisher’s protected LSD where α = 0.05.
c Year-by-treatment interaction was significant for soybean yield; therefore, data from both years are presented separately.
d a priori orthogonal contrasts; ** = significant (P < 0.01), and * = significant (P < 0.05).
Reference: Sarangi D, Jhala AJ (2018) A statewide survey of stakeholders to access the problem weeds and weed management practices in Nebraska. Weed Technology 32:642-655
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