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Effect of row spacing and herbicide programs for control of glyphosate-resistant Palmer amaranth (Amaranthus palmeri) in dicamba/glyphosate-resistant soybean

Published online by Cambridge University Press:  11 May 2021

Shawn T. McDonald
Affiliation:
Graduate Student, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE, USA
Adam Striegel
Affiliation:
Graduate Student, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE, USA
Parminder S. Chahal
Affiliation:
Field Development Representative, FMC, Lincoln, NE, USA
Prashant Jha
Affiliation:
Associate Professor, Department of Agronomy, Iowa State University, Ames, IA, USA
Jennifer M. Rees
Affiliation:
Extension Educator, University of Nebraska–Lincoln, York, NE, USA
Christopher A. Proctor
Affiliation:
Associate Extension Educator, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE, USA
Amit J. Jhala*
Affiliation:
Associate Professor, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE, USA
*
Author for correspondence: Amit J. Jhala, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, 279 Plant Science Hall, P.O. Box 830915, Lincoln, NE68583 Email: [email protected]
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Abstract

Glyphosate-resistant (GR) Palmer amaranth is one of the most difficult to control weeds in soybean production fields in Nebraska and the United States. An integrated approach is required for effective management of GR Palmer amaranth. Cultural practices such as narrow row spacing might augment herbicide efficacy for management of GR Palmer amaranth. The objectives of this study were to evaluate the effect of row spacing and herbicide programs for management of GR Palmer amaranth in dicamba/glyphosate-resistant (DGR) soybean. Field experiments were conducted in a grower’s field with a uniform population of GR Palmer amaranth near Carleton, Nebraska, in 2018 and 2019. Year-by-herbicide program-by-row spacing interactions were significant for all variables; therefore, data were analyzed by year. Herbicides applied PRE controlled GR Palmer amaranth ≥95% in both years 14 d after PRE (DAPRE). Across soybean row-spacing, most PRE followed by (fb) early-POST (EPOST) herbicide programs provided 84% to 97% control of Palmer amaranth compared with most EPOST fb late-post (LPOST) programs, excluding dicamba in single and sequential applications (82% to 95% control). Mixing microencapsulated acetochlor with a POST herbicide in PRE fb EPOST herbicide programs controlled Palmer amaranth ≥93% 14 d after EPOST and ≥96% 21 d after LPOST with no effect on Palmer amaranth density. Interaction of herbicide program-by-row spacing on Palmer amaranth control was not significant; however, biomass reduction was significant at soybean harvest in 2019. The herbicide programs evaluated in this study caused no soybean injury. Due to drought conditions during a majority of the 2018 growing season, soybean yield in 2018 was reduced compared with 2019.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

Native to the American Southwest, Palmer amaranth has spread across the continental United States since the beginning of the 20th century due to seed and equipment transportation and agricultural expansion (Sauer Reference Sauer1957; Ward et al. Reference Ward, Webster and Steckel2013). Historically, Palmer amaranth was not a management concern in Nebraska due to its limited geographical distribution; however, the prevalence of Palmer amaranth has increased since the previous decade, with confirmed populations in most Nebraska counties. A survey conducted in Nebraska reported Palmer amaranth as the fourth most troublesome weed to manage in agronomic crops in the Panhandle and West Central regions of Nebraska and sixth most troublesome weed across the state (Sarangi and Jhala Reference Sarangi and Jhala2018). Reports from this survey are similar to trends in the southeastern United States, where herbicide-resistant (HR), particularly glyphosate-resistant (GR), Palmer amaranth has progressively become a troublesome weed to manage in cotton (Gossypium hirsutum L.), corn (Zea mays L.), and soybean production fields (Webster and Nichols Reference Webster and Nichols2012).

Palmer amaranth is a prolific seed producer despite competition with agronomic crops (Burke et al. Reference Burke, Schroeder, Thomas and Wilcut2007; Guo and Al-Khatib Reference Guo and Al-Khatib2003; Massinga et al. Reference Massinga, Currie, Horak and Boyer2001), with female plants producing ≥200,000 seeds per plant (Keeley et al. Reference Keeley, Carter and Thullen1987; Scott and Smith Reference Scott and Smith2011; Sellers et al. Reference Sellers, Smeda, Johnson, Kendig and Ellersieck2003). Palmer amaranth has the potential to produce high numbers of seed. Keeley et al. (Reference Keeley, Carter and Thullen1987) reported that Palmer amaranth could produce 200,000 to 600,000 seeds per plant, whereas Scott and Smith (Reference Scott and Smith2011) reported seed production from 150,000 to 200,000 seeds per plant when Palmer amaranth was grown under competition with cotton or soybean. However, Scott and Smith (Reference Scott and Smith2011) indicated that seed production of Palmer amaranth grown without competition can exceed 1.5 million seeds per plant. Like waterhemp (Amaranthus tuberculatus Sauer), Palmer amaranth has an extended emergence period (from May to September) in the southeastern United States (Jha et al. Reference Jha, Norsworthy, Bridges and Riley2008), and from May to August in the midwestern United States (Spaunhorst et al. Reference Spaunhorst, Siefert-Higgins and Bradley2014). In addition, Palmer amaranth is a dioecious species primarily pollinated by wind (Franssen et al. Reference Franssen, Skinner, Al-Khatib, Horak and Kulakow2001; Ward et al. Reference Ward, Webster and Steckel2013) that can transfer herbicide resistance alleles via pollen-mediated gene flow (Jhala et al. Reference Jhala, Norsworthy, Ganie, Sosnoskie, Beckie, Mallory-Smith, Liu, Wei, Wang and Stoltenberg2021).

Glyphosate, a broad-spectrum systemic herbicide, is the most widely used agricultural pesticide globally (Benbrook Reference Benbrook2016). An estimated 8.6 billion kg of glyphosate was applied worldwide between 1974 and 2014, with the United States accounting for 19%, or 1.6 billion kg, of global usage (Benbrook Reference Benbrook2016). Glyphosate use in the United States was estimated at 18 million kg per year in 1996, increasing to an estimated 125 million kg in 2013 (USGS 2020). The popularity of glyphosate can be attributed in large part to the widespread adoption of GR crops, low cost, broad spectrum of weed control, and flexibility with crop rotation without carryover injury (Woodburn Reference Woodburn2000). Glyphosate was ranked as the most commonly used herbicide in GR corn-soybean cropping systems in Nebraska in a survey conducted in 2015 (Sarangi and Jhala Reference Sarangi and Jhala2018).

Increased reliance on herbicides resulting from the adoption of reduced/no-tillage cropping systems and continuous use of single site-of-action herbicides has led to the evolution of herbicide-resistant weeds (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017, Reference Chahal, Ganie and Jhala2018). As of 2020, a total of 262 weeds have evolved resistance to 23 of the 26 available herbicide sites of action (Heap Reference Heap2020). In the United States, continued use of glyphosate in agronomic cropping systems has led to the evolution of resistance to the 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) pathway in several weeds, including Palmer amaranth (Gaines et al. Reference Gaines, Shaner, Ward, Leach, Preston and Westra2011). The first instance of GR Palmer amaranth was confirmed in Georgia in 2004 (Culpepper et al. Reference Culpepper, Grey, Vencill, Kichler, Webster, Brown, York, Davis and Hanna2006). Since then, GR Palmer amaranth has been confirmed in 39 states (Heap Reference Heap2020), including Nebraska (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017; Vieira et al. Reference Vieira, Samuelson, Alves, Gaines and Werle2018). Palmer amaranth biotypes resistant to synthetic auxin growth regulators, acetolactate synthase (ALS)-, photosystem II (PS II)-, hydroxyphenylpyruvate dioxygenase (HPPD)-, microtubule-, long chain fatty acid-, and protoporphyrinogen oxidase (PPO)-inhibiting herbicides have been reported (Heap Reference Heap2020). A population of dicamba-resistant Palmer amaranth was identified in Tennessee in 2020 (Steckel Reference Steckel2020). Multiple herbicide-resistant Palmer amaranth populations have been reported in multiple states; for example, Schwartz-Lazaro et al. (Reference Schwartz-Lazaro, Norsworthy, Scott and Barber2017) confirmed a Palmer amaranth population resistant to glyphosate, ALS-, PPO-, and microtubule-inhibiting herbicides in Arkansas. Jhala et al. (Reference Jhala, Sandell, Rana, Kruger and Knezevic2014) reported atrazine and HPPD-inhibiting herbicide resistant Palmer amaranth in Nebraska. Kumar et al. (Reference Kumar, Liu, Boyer and Stahlman2019) confirmed Palmer amaranth resistant to atrazine, chlorsulfuron, 2,4-D, glyphosate, and mesotrione in Kansas.

While herbicides are currently the primary tool for weed control in agronomic crops in the United States, integration of nonchemical control methods (i.e., cultural, mechanical, and biological) could provide enhanced weed control. Previous studies have demonstrated the benefits of integrating cultural control methods such as tillage, crop rotation, crop density, row spacing, ground cover, and cover crops with herbicides for control of GR horseweed (Conyza canadensis L.), burclover (Medicago polymorpha L.), common lambsquarters (Chenopodium album L.), littleseed canarygrass (Phalaris minor Retz.), scarlet pimpernel (Anagallis arvensis L.), toothed dock (Rumex dentatus L.), and GR giant ragweed (Ambrosia trifida L. Bhullar et al. Reference Bhullar, Kaur, Kaur and Jhala2015; Chahal and Jhala Reference Chahal and Jhala2019; Ganie et al. Reference Ganie, Sandell, Jugulam, Kruger, Marx and Jhala2016). Narrow row spacing has been shown previously to enhance weed control and reduce weed seed production in GR soybean, glufosinate-resistant soybean, and sweet potato (Bell et al. Reference Bell, Norsworthy, Scott and Popp2015; Meyers et al. Reference Meyers, Jennings, Schultheis and Monks2010; Whitaker et al. Reference Whitaker, York, Jordan and Culpepper2010).

The adoption of dicamba/glyphosate-resistant (DGR) soybean has been high since its commercialization, with Beckie et al. (Reference Beckie, Ashworth and Flower2019) reporting >50% market share in the United States by 2019. This trend corresponds with survey results that reported that DGR soybean adoption increased from 20% in 2017 to almost 80% in 2019 in Nebraska (Chahal and Jhala Reference Chahal and Jhala2019; Werle et al. Reference Werle, Oliveira, Jhala, Proctor, Rees and Klein2018). Given the continued spread of HR weeds such as GR Palmer amaranth, this adoption trend is indicative of producers’ search for alternative weed management options in soybean. Due to the lack of scientific literature on integration of narrow row spacing with dicamba-based herbicide programs for control of GR Palmer amaranth in DGR soybean, the objectives of this study were to determine the effects of soybean row spacing (38 or 76 cm) and herbicide programs for GR Palmer amaranth control, density, and biomass as well as soybean injury and yield in DGR soybean in a rainfed grower’s field in Nebraska.

Materials and Methods

Study Site and Experimental Design

Field experiments were conducted during the summer of 2018 and 2019 in a grower’s rainfed field in Thayer County, Carleton, NE (40.30oN, 97.67oW). The field was naturally infested with Palmer amaranth with 37-fold to 40-fold resistance to glyphosate (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017). The soil texture at the research site was Crete silt loam (montmorillonitic, mesic, Pachic Argiustolls) with a pH of 6.0, 19% sand, 63% silt, 18% clay, and 2.6% organic matter content. Palmer amaranth was the primary weed in the field with sporadic presence of horseweed, green foxtail (Setaria viridis P. Beauv.), and giant foxtail (S. faberi Herrm.).

The producer’s field had been in a GR corn-soybean rotation with reliance on glyphosate for weed control in a no-till production system for the previous 10 yr. Corn residue from the previous cropping season was retained and the study was conducted using no-till practices. Paraquat (Gramoxone® SL; Syngenta Crop Protection, Greensboro, NC) at 840 g ai ha–1 plus 2,4-D ester (Weedone® LV6; Nufarm Inc., Burr Ridge, IL) at 386 g ae ha–1 plus a nonionic surfactant (Induce®; Helena Chemical, Collierville, TN) at 0.25% vol/vol was applied 2 wk before soybean planting with a tractor-mounted sprayer calibrated to deliver 140 L ha–1 at 276 kPa for control of winter annual weeds. Dicamba/glyphosate-resistant soybean (Northern King NK S29K3X) was planted on May 10, 2018, and May 15, 2019 at 346,000 seeds ha–1 at a depth of 3.0 cm.

Treatments were arranged in a randomized split-block design with four replications (Federer and King Reference Federer and King2006). Herbicide programs were assigned as the whole plot factor (Table 1) in a randomized complete block, whereas row spacing (38 or 76 cm) was assigned as the subplot factor, which resulted in nonstandard incomplete “column” blocks, each containing 15 herbicide programs across the four replications. An incomplete blocking factor was added to simplify the field operation of planting soybean in 38-cm and 76-cm row spacing and reduce field traffic to avoid soil compaction. Plots were 3 m wide by 9 m long with four soybean rows spaced 76 cm apart or six soybean rows spaced 38 cm apart. In total, 15 herbicide programs were evaluated: two early-POST (EPOST), four EPOST followed by (fb) late-POST (LPOST), four PRE fb EPOST, four PRE fb EPOST plus a residual herbicide (RH), and a nontreated control (Table 1). PRE herbicides were applied on the same day after planting DGR soybean, and EPOST herbicides were applied on June 18, 2018, and June 25, 2019, when soybean was at the V3 to V4 growth stage and Palmer amaranth was 7.5 to 10.5 cm tall. LPOST herbicides were applied on July 6, 2018, and July 2, 2019, when soybean was at the R1 growth stage. The PRE, EPOST, and LPOST herbicides were applied using a handheld CO2 pressurized backpack sprayer fitted with an AIXR 110015 flat-fan or TTI 11005 flat-angle nozzles (TeeJet®, Spraying Systems Co., Wheaton, IL) based on label requirements and calibrated to deliver 140 L ha–1 at 276 kPa.

Table 1. Herbicides and application timings, rates, and products used for control of glyphosate-resistant Palmer amaranth in dicamba/glyphosate-resistant soybean in field experiments conducted near Carleton, NE, in 2018 and 2019.

a Abbreviations: ai, active ingredient; ae, acid equivalent; AMS, ammonium sulfate (N-Pak AMS Liquid, Winfield United, LLC., St. Paul, MN 55164); DRA, drift reducing agent (Intact, Precision Laboratories, Waukegan, IL 60085); EPOST, early POST-emergence; fb, followed by; LPOST, late POST-emergence; NIS, nonionic surfactant (Induce, Helena Chemical, Collierville, TN 38017); RH, residual herbicide; WC, water conditioner (Class Act Ridion, Winfield United, Arden Hills, MN, 55126).

b Bayer CropScience, Research Triangle Park, NC; BASF Corporation, Research Triangle Park, NC; Syngenta Crop Protection, LLC., Greensboro, NC; Valent USA Corporation, Walnut Creek, CA.

c AMS at 3% vol/vol, DRA at 0.5% vol/vol, NIS at 0.25% and WC at 1% vol/vol were mixed with herbicide treatments based on label recommendations.

Data Collection

Palmer amaranth control from PRE-applied herbicides was visually assessed 14 and 28 d after PRE (DAPRE) herbicide applications using a scale of 0% to 100%, with 0% representing no control and 100% representing complete control. Likewise, Palmer amaranth control from POST herbicides was visually assessed at 14 and 21 d after early-POST (DAEPOST) applications, 21 d after late-POST (DALPOST) applications, and prior to soybean harvest using the same scale at which PRE-applied herbicides were evaluated. Palmer amaranth density was recorded 14 DAPRE, 14 DAEPOST, and 14 DALPOST by counting Palmer amaranth plants in two 0.5-m2 quadrats placed randomly between the two or four center soybean rows (76- or 38-cm row spacing, respectively) in each plot and converting to plants per square meter. Soybean injury was visually assessed at 14 DAPRE, 14 DAEPOST, and 14 DALPOST on a scale of 0% to 100%, with 0% representing no injury and 100% representing complete plant death. Aboveground biomass of Palmer amaranth was collected 14 DAEPOST and 21 DALPOST. Biomass samples were oven-dried at 65 C for 14 d, with Palmer amaranth aboveground biomass data converted into percent biomass reduction compared with the nontreated control using the following equation (Wortman Reference Wortman2014):

Aboveground biomass reduction (%) = [(CB)/C] × 100

where C is equal to the aboveground biomass of the nontreated control plot and B is equal to the biomass of an individual treated plot. Soybean yield was taken from the center two or four rows in each plot (for 76- and 38-cm row spacing, respectively) using a plot combine (Gleaner K2; AGCO, Duluth, GA) and adjusted to 13% moisture content.

Statistical Analysis

Statistical analysis was performed using R statistical software version 4.0.3 (R Core Team 2018) using the glmmTMB package (Brooks et al. Reference Brooks, Kristensen, van Benthem, Magnusson, Berg, Nielsen, Skaug, Mächler and Bolker2017) and lme4 package (Bates et al. Reference Bates, Mäechler, Bolker, Walker, Haubo, Christensen, Singmann, Dai, Scheipl, Grothendieck, Green and Fox2015), with subsequent contrast analysis preformed using the gmodels package (Warnes et al. Reference Warnes, Bolker and Lumley2018). Year-by-treatment and year-by-treatment-by-row spacing interactions were evaluated, and if significant, data were analyzed separately by year. In the models separated by year, the interaction of herbicide treatment and row spacing were considered fixed effects, whereas the interaction of replication by herbicide treatment, column, and column by row spacing were considered random effects.

Normality assumptions were tested for each variable using Shapiro-Wilk tests and Normal Q-Q plots. Total aboveground Palmer amaranth biomass reduction and Palmer amaranth control ratings were log(x+1) or logit-transformed and fit to generalized linear mixed-effect models using glmmTMB functions with gaussian (link = “identity”) and beta (link = “logit”) error distributions, respectively (Stroup Reference Stroup2015). Likewise, soybean yield and weed density data were log(x+1) or square root transformed and fit to linear mixed-effect models using the lmer function (Kniss and Streibig Reference Kniss and Streibig2018). Selection for final glmmTMB models was based on model dispersion parameter estimates and Akaike information criterion (AIC) values, with log(x+1) or logit transformation with beta and gaussian error distributions selected for all response variables, respectively. Likewise, final lmer models were selected based on restricted maximum likelihood (REML) criterion at convergence values and AIC values. Prior to conducting ANOVA, variance assumptions were tested for each variable at α = 0.05 using Bartlett and Fligner-Killen tests (Kniss and Streibig Reference Kniss and Streibig2018). Variables that failed variance assumptions were subsequently assessed for outliers and heterogeneity of variance by plotting residual values (Knezevic et al. Reference Knezevic, Evans and Mainz2003; Ritz et al. Reference Ritz, Kniss and Streibig2015).

The ANOVA was performed using the car package (Fox and Weisberg Reference Fox and Weisberg2019). For lmer models, ANOVA was conducted with Type III Wald F-tests, whereas glmmTMB models used Type III Wald chi-square tests. After conducting ANOVA, treatment estimated marginal means were separated using the emmeans package (Lenth Reference Lenth2019) and multcomp package (Hothorn et al. Reference Hothorn, Bretz and Westfall2008). Estimated marginal means included post hoc Tukey P-value adjustments and Sidak method confidence-level adjustments, with compact letter display generated via the multcomp:cld function. A priori contrasts were performed using the gmodels package (Warnes et al. Reference Warnes, Bolker and Lumley2018) to compare EPOST, EPOST fb LPOST, and PRE fb EPOST herbicide programs. In the first set of a priori contrasts, PRE fb EPOST programs were pooled together regardless of the inclusion of a RH at EPOST. Following these sets of contrasts, PRE fb EPOST herbicide programs were further separated into PRE fb EPOST, and PRE fb EPOST plus RH to evaluate the addition of acetochlor as an overlapping residual herbicide. Following treatment means separation and contrast analysis, data were back-transformed for the presentation of results.

Results and Discussion

Year-by-herbicide program-by-row spacing interactions were significant for all experimental variables; therefore, data were separated and presented by year.

Temperature and Precipitation

Growing conditions differed between the 2018 and 2019 growing seasons (Figure 1). In both years, field experiments were conducted under rainfed conditions. During 2018, cumulative precipitation received was below the 30-yr average (517 mm) for most of the growing season. In contrast, during 2019, cumulative precipitation received during the growing season exceeded the 30-yr average by 221 mm. Average daily temperatures in 2018 exceeded the 30-yr average during the early growing season, whereas they closely resembled the 30-yr average in 2019 (Figure 1). Herbicide programs evaluated in this study displayed excellent safety in DGR soybean, with no observable injury across both years (data not shown).

Figure 1. Average daily air temperature (ºC) and total cumulative precipitation (mm) received during the 2018 and 2019 growing seasons compared to the 30-year average for dryland field experiments conducted to determine the effect of row spacing and herbicide programs for control of glyphosate-resistant Palmer amaranth in dicamba/glyphosate-resistant soybean near Carleton, Nebraska, in 2018 and 2019.

Palmer Amaranth Control

Herbicides applied PRE controlled GR Palmer amaranth ≥95% in both years 14 DAPRE (Table 2). The PRE herbicides controlled Palmer amaranth 91% to 96% in 2018, whereas in 2019, flumioxazin/metribuzin/pyroxasulfone and imazethapyr/pyroxasulfone/saflufenacil provided 95% and 93% control, respectively, at 21 DAPRE. In 2019, dicamba plus chlorimuron/flumioxazin applied PRE controlled Palmer amaranth 80% compared to 45% control with dicamba (Table 2). Reduced control of Palmer amaranth with dicamba applied alone in 2019 can be attributed primarily to the shorter residual control by dicamba compared to other PRE herbicide programs evaluated as observed by Hedges et al. (Reference Hedges, Soltani, Hooker, Robinson and Sikkema2019). Efficacy of premixed and tank-mixed PRE herbicides with multiple effective sites of action on Palmer amaranth control were previously evaluated in soybean fields in Nebraska, with Striegel et al. (Reference Striegel, Eskridge, Lawrence, Knezevic, Kruger, Proctor, Hein and Jhala2020) and Shyam et al. (Reference Shyam, Chahal, Jhala and Jugulam2021) reporting 93% to 99% control 14 and 28 DAPRE. Results from the current study are similar to those reported by Meyer et al. (Reference Meyer, Norsworthy, Young, Steckel, Bradley, Johnson, Loux, Davis, Kruger, Bararpour, Ikley, Spaunhorst and Butts2015), when flumioxazin/pyroxasulfone, metribuzin, dicamba, S-metolachlor, S-metolachlor/fomesafen, acetochlor, isoxaflutole, and S-metolachlor/mesotrione applied PRE provided 95% to 99% control of Palmer amaranth 21 DAPRE in field experiments conducted in Arkansas, Illinois, Indiana, Missouri, Nebraska, and Tennessee.

Table 2. Effect of row spacing and herbicide programs on control of glyphosate-resistant Palmer amaranth in dicamba/glyphosate-resistant soybean 14 and 21 DAPRE in rainfed field experiments conducted near Carleton, NE, in 2018 and 2019.

a Abbreviations: ai, active ingredient; ae, acid equivalent; DAPRE, days after pre-emergence herbicide; PRE, pre-emergence herbicide; RH, residual herbicide.

b PRE fb EPOST and PRE fb EPOST + RH treatments were combined (n = 8) for analysis of 14 and 28 DAPRE control.

c Data for each year were logit transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

d Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

At 14 DAEPOST, the interaction of herbicide program-by-row spacing and the main effect of row spacing for Palmer amaranth control were not significant for either year. For both years, EPOST and EPOST fb LPOST herbicide programs provided reduced control of Palmer amaranth compared with PRE fb EPOST application of dicamba or dicamba plus acetochlor. Imazethapyr applied EPOST provided 15% and 4% Palmer amaranth control in 2018 and 2019, respectively. Likewise, EPOST or EPOST fb LPOST applications of glyphosate provided 10% to 30% control across both years. Reduced Palmer amaranth control with imazethapyr and glyphosate observed in this study can be attributed primarily to the prevalence of ALS-inhibitor-resistant and GR Palmer amaranth biotypes present at the study location (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017). In EPOST and EPOST fb LPOST herbicide programs where dicamba was applied, Palmer amaranth control from EPOST programs varied from 36% to 68% in 2018 and 85% to 89% in 2019 (Table 3). A priori contrasts comparing the main effect of herbicides on Palmer amaranth control were significant (P < 0.05) 14 DAEPOST for both years, with PRE fb EPOST herbicide programs providing 90% and 99% Palmer amaranth control in 2018 and 2019, respectively. The addition of acetochlor with EPOST herbicides increased Palmer amaranth control 14 DAEPOST in 2018 and 2019 (88% vs. 93% and 83% vs. 94%, respectively).

Table 3. Control of glyphosate-resistant Palmer amaranth at 14 and 21 DAEPOST and 21 DALPOST in dryland field experiments conducted near Carleton, NE to determine the effect of row spacing and herbicide programs in dicamba/glyphosate-resistant soybean in 2018 and 2019.

a Abbreviations: DAEPOST, days after early-POST emergence; DALPOST, days after late-POST emergence; DAPRE, days after pre-emergence; EPOST, early-POST emergence; fb, followed by; LPOST, late-POST emergence; RH, residual herbicide.

b Data for each year were logit transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

c Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

d A priori contrasts; * = significant (P < 0.05); **= significant (P < 0.01); ***= significant (P < 0.001); NS, nonsignificant (P ≥ 0.05)

At 21 DAEPOST, PRE fb EPOST and PRE fb EPOST + RH (acetochlor) programs controlled Palmer amaranth 84% to 97% in both years, with comparable control also provided by most EPOST or EPOST fb LPOST dicamba applications (Table 3). Conversely, glyphosate provided 36% to 43% control in 2018 and 7% to 8% control in 2019. This indicates the level of glyphosate resistance and demonstrates that even two applications of glyphosate could not provide >45% control. Imazethapyr applied EPOST controlled Palmer amaranth by 58% in 2018 and by 3% in 2019, whereas mixing fomesafen/S-metolachlor with imazethapyr improved control to 75% and 61% 21 DAEPOST in 2018 and 2019, respectively (Table 3). A priori contrasts comparing the main effects of herbicide programs on Palmer amaranth control were significant (P < 0.001) 21 DAEPOST, with PRE fb EPOST and PRE fb EPOST + RH providing the highest Palmer amaranth control. Averaged across PRE herbicides, mixing acetochlor with dicamba applied EPOST increased Palmer amaranth control 21 DAEPOST in 2018 (97%) compared to dicamba alone (92%), but not in 2019 (Table 3).

At 21 DALPOST, most PRE fb EPOST and PRE fb EPOST + RH programs continued to provide 91% to 99% Palmer amaranth control in 2018, with the exception of dicamba PRE fb dicamba EPOST (84%), results for which were similar to those of EPOST-only programs (82%). In contrast, dicamba applied EPOST fb LPOST controlled Palmer amaranth by 91%, similar to that controlled by PRE fb EPOST programs. These results were similar at 21 DALPOST in 2019, with PRE fb EPOST, PRE fb EPOST + RH, and stand-alone applications of dicamba applied EPOST or EPOST fb LPOST providing 85% to 95% control of Palmer amaranth. Dicamba applied LPOST following imazethapyr or imazethapyr plus fomesafen/S-metolachlor applied EPOST controlled Palmer amaranth by 58% to 85%.

A priori contrasts comparing the main effects of herbicide programs on Palmer amaranth control were significant 21 DALPOST with PRE fb EPOST herbicide programs providing ≥92% Palmer amaranth control. Tank-mixing acetochlor with POST herbicides increased Palmer amaranth control 21 DALPOST (Table 3). In 2018, the interaction of herbicide program by row spacing was significant (P < 0.001) for Palmer amaranth control 21 DALPOST, although comparisons of estimated marginal means across row spacing was only significant for EPOST applications of glyphosate, which provided 53% and 26% Palmer amaranth control in 38- and 76-cm row spacing, respectively (Table 4). In both years, contrasts comparing the main effects of herbicide programs on Palmer amaranth control were significant 21 DALPOST, with PRE fb EPOST herbicide programs providing 92% and 88% control in 2018 and 2019, respectively. Mixing acetochlor with POST herbicides increased Palmer amaranth control 21 DALPOST (Table 3). The increased Palmer amaranth control via the inclusion of acetochlor as an overlapping residual herbicide is similar to results reported by Sarangi and Jhala (Reference Sarangi and Jhala2019) in which overlapping residual herbicides increased Palmer amaranth control and biomass reductions in conventional soybean 28 DAPOST in a field study in Nebraska.

Table 4. Interaction of herbicide programs and row spacing (38 cm or 76 cm) for control of glyphosate-resistant Palmer amaranth at 21 DAEPOST and 21 DALPOST and biomass reduction at pre-harvest in rainfed field experiments conducted near Carleton, NE, in dicamba/glyphosate-resistant soybean in 2018 and 2019.

a Abbreviations: GR, glyphosate-resistant; DGR, dicamba/glyphosate-resistant; DAEPOST, days after early-POST emergence herbicide; DALPOST, days after late-POST emergence herbicide; DAPRE, days after pre-emergence herbicide; EPOST, early-POST emergence herbicide; fb, followed by; LPOST, late-POST emergence herbicide; PRE, pre-emergence herbicide; RH, residual herbicide.

b Data for each year were logit transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

c Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

Prior to soybean harvest, most PRE fb EPOST and PRE fb EPOST + RH programs controlled GR Palmer amaranth by 91% to 99%, with the exception of dicamba fb dicamba in 2018, which provided 76% control (Table 5). These results are similar to those reported by Bell et al. (Reference Bell, Norsworthy, Scott and Popp2015) in a 2-yr study in which herbicide programs receiving PRE herbicides controlled Palmer amaranth by ≥95% regardless of row spacing when evaluated prior to harvest. The EPOST and EPOST fb LPOST applications of dicamba provided similar control to PRE fb EPOST herbicide programs, with the exception of dicamba applied EPOST in 2018 (72%). As observed at 21 DALPOST, imazethapyr fb dicamba and imazethapyr mixed with fomesafen/S-metolachlor fb dicamba provided 60% to 78% Palmer amaranth control. A priori contrasts comparing the main effects of herbicide programs on Palmer amaranth control were significant for preharvest Palmer amaranth control with PRE fb EPOST herbicide programs providing 92% to 99% Palmer amaranth control. Mixing acetochlor with EPOST herbicide increased Palmer amaranth control at preharvest in 2018, but not in 2019 (Table 5). While the effect of acetochlor applied POST in soybean is well documented (Bell et al. Reference Bell, Norsworthy, Scott and Popp2015; Manuchehri et al. Reference Manuchehri, Dotray and Keeling2017; Sarangi and Jhala Reference Sarangi and Jhala2018), the effect of including acetochlor with dicamba in DGR soybean applied POST for Palmer amaranth control is limited. The inconsistency of preharvest Palmer amaranth control with acetochlor has been reported elsewhere. For example, Spaunhorst et al. (Reference Spaunhorst, Siefert-Higgins and Bradley2014) reported that the inclusion of acetochlor applied EPOST or LPOST did not provide additional control of waterhemp compared to programs without acetochlor in DGR soybean in Missouri. Likewise, including acetochlor in an overlapping residual herbicide program did not increase Palmer amaranth control compared to programs lacking acetochlor in cotton (Manuchehri et al. Reference Manuchehri, Dotray and Keeling2017). In contrast, research conducted in Nebraska with multiple HR Palmer amaranth in corn has indicated that acetochlor applied POST in a PRE fb POST herbicide program was an effective management strategy (Chahal et al. Reference Chahal, Ganie and Jhala2018). An important distinction to note is that the inclusion of acetochlor with POST herbicides did not result in reduced Palmer amaranth control (via antagonistic effects) compared to corresponding programs that did not include acetochlor.

Table 5. Pre-harvest control of glyphosate-resistant Palmer amaranth and soybean yield in rainfed field experiments conducted near Carleton, NE to determine the effect of row spacing and herbicide program in dicamba/glyphosate-resistant soybean in 2018 and 2019.

a Abbreviations: EPOST, early-POST emergence; fb, followed by; LPOST, late-POST emergence; RH, residual herbicide; SEM, standard error of the mean.

b Data for each year were log or logit transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

c Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

d A priori contrasts; * = significant (P < 0.05); **= significant (P < 0.01); ***= significant (P < 0.001); NS, nonsignificant (P ≥ 0.05).

Palmer Amaranth Biomass Reduction

The main effect of row spacing and the interaction of herbicide-by-row spacing were not significant 14 DAEPOST in 2018 (Table 6). The PRE fb EPOST and PRE fb EPOST plus RH programs provided the highest reduction of Palmer amaranth biomass (91% to 100%) compared to EPOST (23% to 78%) and EPOST fb LPOST (22% to 68%) 14 DAEPOST (Table 6). A priori contrasts in 2018 comparing the main effect of herbicide programs on Palmer amaranth biomass reduction were significant, with PRE fb EPOST programs providing the greatest reduction of Palmer amaranth biomass. The addition of acetochlor as an RH was not significant 14 DAEPOST in 2018 (Table 6).

Table 6. Effect of row spacing and herbicide programs on glyphosate-resistant Palmer amaranth biomass reduction at 14 DAEPOST, 14 DALPOST, and pre-harvest in rainfed field experiments conducted near Carleton, NE in dicamba/glyphosate-resistant soybean in 2018 and 2019.

a Abbreviations: DAEPOST, days after early-POST emergence; DALPOST, days after late-POST emergence; EPOST, early-POST emergence; fb, followed by; LPOST, late-POST emergence; RH, residual herbicide.

b Data for each year were logit transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

c Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

d A priori contrasts; * = significant (P < 0.05); **= significant (P < 0.01); ***= significant (P < 0.001); NS, nonsignificant (P ≥ 0.05).

A priori contrasts in 2019 comparing the main effect of herbicide program on Palmer amaranth biomass reduction were significant 14 DAEPOST and 14 DALPOST, with PRE fb EPOST programs providing 97% and 90% biomass reductions, respectively. The addition of acetochlor as an RH was significant 14 DAEPOST in 2019 (99% vs. 94% biomass reduction), but not 14 DALPOST (P < 0.05; Table 6). Acetochlor has been previously shown to provide >80% control of Palmer amaranth up to 50 d after application (Cahoon et al. Reference Cahoon, York, Jordan, Everman, Seagroves, Braswell and Jennings2015), while mixing acetochlor with glufosinate has been shown to provide ≥93% biomass reduction of GR common ragweed (Ambrosia artemisiifolia L.) in glufosinate-resistant soybean (Barnes et al. Reference Barnes, Knezevic, Sikkema, Lindquist and Jhala2017) and ≥84% control applied alone or tank-mixed with fluometuron, diuron, fomesafen, or diuron/fomesafen (Cahoon et al. Reference Cahoon, York, Jordan, Everman, Seagroves, Braswell and Jennings2015).

Prior to harvest in 2019 (e.g., 88 DALPOST), PRE fb EPOST and PRE fb EPOST plus RH programs reduced Palmer amaranth biomass by 98% to 100%. The EPOST fb LPOST programs, excluding glyphosate fb glyphosate (62%), reduced Palmer amaranth biomass 100%, whereas glyphosate and dicamba applied EPOST reduced Palmer amaranth biomass only 2% and 68%, respectively (Table 6). A priori contrasts comparing the main effects of herbicide program for Palmer amaranth biomass reduction were significant, with PRE fb EPOST and EPOST fb LPOST programs providing similar reductions of Palmer amaranth biomass (Table 6). The interaction of herbicide program by row spacing on Palmer amaranth biomass reduction was significant (P = 0.026) at preharvest in 2019, with most herbicide programs providing similar biomass reductions with the exception of dicamba applied EPOST (97% and 40% biomass reductions for 38-cm and 76-cm row spacings, respectively) and glyphosate applied EPOST fb LPOST (76% and 48% biomass reductions for 38-cm and 76-cm row spacing, respectively; Table 4). The effect of row spacing on Palmer amaranth biomass reduction in herbicide programs consisting of dicamba applied EPOST and glyphosate applied EPOST fb LPOST can be partially attributed to the effects that narrower row spacing has on achieving canopy closure more quickly compared to wider row spacing. With rapid canopy closure, late-emerging Palmer amaranth growth is suppressed, limiting biomass and seed production (Buehring et al. Reference Buehring, Nice and Shaw2002; Jha and Norsworthy Reference Jha and Norsworthy2009; Norsworthy et al. Reference Norsworthy, Jha and Bridges2007).

Palmer Amaranth Density

Palmer amaranth density was higher in EPOST and EPOST fb LPOST herbicide programs compared to programs containing PRE herbicides 14 DAEPOST in both years (Table 7). However, the interaction of herbicide by row spacing was significant 14 DAEPOST (P = 0.028 and P = 0.04, respectively), although after adjusting for multiple comparisons, estimated marginal mean groupings were similar for herbicide programs and row spacing (Table 8). This is likely attributed to the large variance in Palmer amaranth densities across herbicide programs and row spacings, or the conservative nature of post hoc Tukey P-value adjustments and Sidak method confidence-level adjustments used during estimated marginal mean separation. For the analysis of main effects, a priori contrasts comparing Palmer amaranth density 14 DAEPOST for both years were significant with reduced Palmer amaranth density in PRE fb EPOST herbicide programs compared to EPOST and EPOST fb LPOST herbicide programs. The addition of acetochlor with a POST herbicide did not reduce Palmer amaranth density in PRE fb EPOST herbicide programs, indicating that an RH at EPOST is not needed in every field and that careful herbicide selection is necessary based on weed density and moisture availability to avoid extra cost (Table 7).

Table 7. Effect of row spacing and herbicide programs on glyphosate-resistant Palmer amaranth density at 14 DAEPOST and 14 DALPOST in rainfed field experiments conducted near Carleton, NE in dicamba/glyphosate-resistant soybean in 2018 and 2019.

a Abbreviations: DAEPOST, days after early-POST emergence; DALPOST, days after late-POST emergence; EPOST, early-POST emergence; fb, followed by; LPOST, late-POST emergence; RH, residual herbicide.

b Data for each year were square root or log transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

c Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

d A priori contrasts; * = significant (P < 0.05); **= significant (P < 0.01); ***= significant (P < 0.001); NS, nonsignificant (P ≥ 0.05).

Table 8. Interaction of herbicide programs and row spacing for glyphosate-resistant Palmer amaranth density at 14 DAEPOST in rainfed field experiments conducted near Carleton, NE in dicamba/glyphosate-resistant soybean in 2018 and 2019.

a Abbreviations: DAEPOST, days after early-POST emergence; DALPOST, days after late-POST emergence; EPOST, early-POST emergence; fb, followed by; LPOST, late-POST emergence; RH, residual herbicide.

b Data for each year were logit transformed before analysis; however back-transformed values are presented based on interpretations of transformed data.

c Means presented within the same column with no common letters are significantly different according to estimated marginal means with Sidak confidence-level adjustments and Tukey P-value adjustments.

At 14 DALPOST in 2019 (e.g., 36 DAEPOST), density of Palmer amaranth was not significant by herbicide or herbicide-by-row spacings. Row spacing was significant (P = 0.002), with 1.0 Palmer amaranth plant per square meter in 38-cm row spacing compared with 15 Palmer amaranth plants in 76-cm row spacing across the herbicide programs evaluated. Mixing acetochlor did not reduce Palmer amaranth density compared to PRE fb EPOST herbicide programs without acetochlor (Table 7). Inclusively, findings from the current study at 14 DALPOST are similar to the results reported by Spaunhorst et al. (Reference Spaunhorst, Siefert-Higgins and Bradley2014) that acetochlor with EPOST or LPOST herbicides did not reduce waterhemp density in DGR soybean in Missouri compared to EPOST and LPOST herbicides that did not include acetochlor.

Soybean Yield

Due to drought conditions during a majority of the growing season in 2018, soybean yield was reduced compared with 2019 (Figure 1; Table 5). In 2018, the main effect of herbicide program was significant for soybean yield, whereas row spacing and the interaction effect of herbicide-by-row spacing were not significant. Yield was consistently higher in PRE fb EPOST (695 kg ha–1) and PRE fb EPOST plus RH programs (925 kg ha–1) compared to most EPOST and EPOST fb LPOST herbicide programs with the exception of dicamba applied EPOST (655 ± 55 kg ha–1) and dicamba applied EPOST fb LPOST (564 ± 75 kg ha–1). A priori contrasts comparing soybean yield in 2018 were significant, with the highest yield occurring in treatments that received PRE fb EPOST herbicides, which is consistent with literature indicating the economic importance of PRE fb POST herbicide programs (Barnes et al. Reference Barnes, Knezevic, Sikkema, Lindquist and Jhala2017; Rosenbaum et al. Reference Rosenbaum, Massey and Bradley2013) as well as multiple applications to control Palmer amaranth (Cahoon et al. Reference Cahoon, York, Jordan, Everman, Seagroves, Braswell and Jennings2015).

The main effects of row spacing and herbicide programs were significant for soybean yield, with 4,607 ± 238 and 3,930 ± 203 kg ha–1 in 38-cm and 76-cm row spacing, respectively, in 2019 (Table 5). Across row spacings, soybean yield was similar for most herbicide programs, excluding glyphosate applied EPOST (3,176 ± 269 kg ha–1). Wax and Pendleton (Reference Wax and Pendleton1968) reported soybean yield increases of 10%, 18%, and 20% in 76-cm, 50-cm, and 25-cm row spacing compared with 101-cm row spacing in field experiments conducted in Illinois. A priori contrasts comparing soybean yield in 2019 were significant with the highest yield in PRE fb EPOST or EPOST fb LPOST herbicide programs, indicating the importance of using PRE herbicide programs in DGR soybean; however, mixing acetochlor with POST herbicides did not result in increased soybean yield (Table 5). While soybean grain yield reduction of up to 79% due to Palmer amaranth interference has previously been reported (Bensch et al. Reference Bensch, Horak and Peterson2003; Klingaman and Oliver Reference Klingaman and Oliver1994; Monks and Oliver Reference Monks and Oliver1988), the control of Palmer amaranth provided by most of the herbicide programs in this research was substantial enough to avoid the yield reductions that occurred to the nontreated control (2,284 kg ± 199 kg ha–1).

Practical Implications

Results of this study indicate that herbicide programs and their subsequent application timing had a greater impact on control of GR Palmer amaranth than row spacing in DGR soybean. Although significantly higher reductions to Palmer amaranth biomass occurred preharvest in 38-cm row spacings compared to 76-cm row spacings in EPOST applications of dicamba and EPOST fb LPOST programs of glyphosate, other inconsistent results in this research pertaining to Palmer amaranth density/main effects of row spacing along with other variable results reported in the literature suggests additional research may be needed. Results from this research indicate that the use of PRE fb POST herbicide programs in DGR soybean provide higher levels of Palmer amaranth control than PRE-only herbicide programs, and also that dicamba applied POST provides effective control of GR Palmer amaranth. The efficacy of acetochlor applied EPOST on Palmer amaranth control, density, and biomass reduction varied across site-years and evaluation periods.

The importance of herbicide programs that use multiple sites of action is reaffirmed through this research. For example, EPOST applications of dicamba provided 68% GR Palmer amaranth biomass reduction at preharvest when averaged across row spacings, which was a stark contrast compared to the 98% to 100% biomass reductions that occurred in PRE fb EPOST and PRE fb EPOST plus RH programs. These results are similar to the findings reported by Cahoon et al. (Reference Cahoon, York, Jordan, Everman, Seagroves, Braswell and Jennings2015) in DGR cotton that sequential applications of dicamba were more effective than a single application; however, selection pressure on Palmer amaranth and other weeds should be considered when using sequential applications of the same herbicide, and such sequential applications should be avoided if other options are available, especially considering the recent confirmation of dicamba-resistant Palmer amaranth in Tennessee (Steckel Reference Steckel2020).

Acknowledgments

We thank Irvin Schleufer, José De Sanctis, Jasmine Mausbach, Will Neels, Adam Leise, and Jared Stander for their help. This project was partially supported by Nebraska Soybean Board, Bayer Crop Science, Nebraska Agricultural Experiment Station with funding from the Hatch Act through the U.S. Department of Agriculture–National Institute of Food and Agriculture (USDA-NIFA) Project No. NEB-22-396. This project was also supported by the USDA-NIFA Nebraska Extension Implementation Program. No conflicts of interest have been declared.

Footnotes

Associate Editor: Kevin Bradley, University of Missouri

References

Barnes, ER, Knezevic, SZ, Sikkema, PH, Lindquist, JL, Jhala, AJ (2017) Control of glyphosate-resistant common ragweed (Ambrosia artemisiifolia L.) in glufosinate-resistant soybean [Glycine max (L.) merr]. Front Plant Sci 8:1455 https://doi.org/10.3389/fpls.2017.01455 CrossRefGoogle Scholar
Bates, D, Mäechler, M, Bolker, B, Walker, S, Haubo, R, Christensen, B, Singmann, H, Dai, B, Scheipl, F, Grothendieck, G, Green, P, Fox, J (2015) lme4: linear mixed-effects models using “Eigen” and S4. https://cran.r-project.org/package=lme4. Accessed: October 1, 2020Google Scholar
Beckie, HJ, Ashworth, MB, Flower, KC (2019) Herbicide resistance management: Recent developments and trends. Plants 8:161 https://doi.org/10.3390/plants8060161 Accessed: March 1, 2021CrossRefGoogle ScholarPubMed
Bell, HD, Norsworthy, JK, Scott, RC, Popp, M (2015) Effect of row spacing, seeding rate, and herbicide program in glufosinate-resistant soybean on Palmer amaranth management. Weed Technol 29:390404 CrossRefGoogle Scholar
Benbrook, CM (2016) Trends in glyphosate herbicide use in the United States and globally. Environ Sci Eur 28:115 CrossRefGoogle ScholarPubMed
Bensch, CN, Horak, MJ, Peterson, D (2003) Interference of redroot pigweed (Amaranthus retroflexus), Palmer amaranth (A. palmeri), and common waterhemp (A. rudis) in soybean. Weed Sci 51:3743 CrossRefGoogle Scholar
Bhullar, MS, Kaur, G, Kaur, M, Jhala, AJ (2015) Integrated weed management in potato using atrazine and straw mulch. HortTechnol 25:335339 CrossRefGoogle Scholar
Brooks, ME, Kristensen, K, van Benthem, KJ, Magnusson, A, Berg, CW, Nielsen, A, Skaug, HJ, Mächler, M, Bolker, BM (2017) glmmTMB balances speed and flexibility among packages for zero-inflated generalized linear mixed modeling. R Journal 9:378400 CrossRefGoogle Scholar
Buehring, NW, Nice, GRW, Shaw, DR (2002) Sicklepod (Senna obtusifolia) control and soybean (Glycine max) response to soybean row spacing and population in three weed management systems. Weed Technol 16:131141 CrossRefGoogle Scholar
Burke, IC, Schroeder, M, Thomas, WE, Wilcut, JW (2007) Palmer amaranth interference and seed production in peanut. Weed Technol 21:367371 CrossRefGoogle Scholar
Cahoon, CW, York, AC, Jordan, DL, Everman, WJ, Seagroves, RW, Braswell, LR, Jennings, KM (2015) Weed control in cotton by combinations of microencapsulated acetochlor and various residual herbicides applied preemergence. Weed Technol 29:740750 CrossRefGoogle Scholar
Chahal, PS, Ganie, ZA, Jhala, AJ (2018) Overlapping residual herbicides for control of photosystem (PS) II- and 4-hydroxyphenylpyruvate dioxygenase (HPPD)-inhibitor-resistant Palmer amaranth (Amaranthus palmeri S. Watson) in glyphosate-resistant maize. Front Plant Sci 8:2231 CrossRefGoogle Scholar
Chahal, PS, Jhala, AJ (2019) Integrated management of glyphosate-resistant horseweed (Erigeron canadensis) with tillage and herbicides in soybean. Weed Technol 33:859866 CrossRefGoogle Scholar
Chahal, PS, Varanasi, VK, Jugulam, M, Jhala, AJ (2017) Glyphosate-resistant Palmer amaranth (Amaranthus palmeri) in Nebraska: confirmation, EPSPS gene amplification, and pesponse to POST corn and soybean herbicides. Weed Technol 31:8093 CrossRefGoogle Scholar
Culpepper, AS, Grey, TL, Vencill, WK, Kichler, JM, Webster, TM, Brown, SM, York, AC, Davis, JW, Hanna, WW (2006) Glyphosate-resistant Palmer amaranth (Amaranthus palmeri) confirmed in Georgia. Weed Sci 54:620626 CrossRefGoogle Scholar
Federer, WT, King, F (2006) Variations on split plot and split block experiment designs. Hoboken, NJ: John Wiley & Sons, Inc. 270 p Google Scholar
Fox, J, Weisberg, S (2019) CAR - An R companion to applied regression. Thousand Oaks CA: Sage. 2016 p Google Scholar
Franssen, AS, Skinner, DZ, Al-Khatib, K, Horak, MJ, Kulakow, PA (2001) Interspecific hybridization and gene flow of ALS resistance in Amaranthus species. Weed Sci 49:598606 CrossRefGoogle Scholar
Gaines, TA, Shaner, DL, Ward, SM, Leach, JE, Preston, C, Westra, P (2011) Mechanism of resistance of evolved glyphosate-resistant Palmer amaranth (Amaranthus palmeri). J Agric Food Chem 59:58865889 CrossRefGoogle Scholar
Ganie, ZA, Sandell, LD, Jugulam, M, Kruger, GR, Marx, DB, Jhala, AJ (2016) Integrated management of glyphosate-resistant giant ragweed (Ambrosia trifida) with tillage and herbicides in soybean. Weed Technol 30:4556 CrossRefGoogle Scholar
Guo, P, Al-Khatib, K (2003) Temperature effects on germination and growth of redroot pigweed (Amaranthus retroflexus), Palmer amaranth (A. palmeri), and common waterhemp (A. rudis). Weed Sci 51:869875 CrossRefGoogle Scholar
Heap, I (2020) International survey of herbicide resistant weeds. http://www.weedscience.org. Accessed: May 2, 2020Google Scholar
Hedges, BK, Soltani, N, Hooker, DC, Robinson, DE, Sikkema, PH (2019) Control of glyphosate-resistant waterhemp with preemergence herbicides in glyphosate- and dicamba-resistant soybean. Can J Plant Sci 99:3439 CrossRefGoogle Scholar
Hothorn, T, Bretz, F, Westfall, P (2008) Simultaneous inference in general parametric models. Technical Report Number 019. Munich: University of Munich Department of StatisticsCrossRefGoogle Scholar
Jha, P, Norsworthy, JK (2009) Soybean canopy and tillage effects on emergence of Palmer amaranth (Amaranthus palmeri) from a natural seed bank. Weed Sci 57:644651 CrossRefGoogle Scholar
Jha, P, Norsworthy, JK, Bridges, W, Riley, MB (2008) Influence of glyphosate timing and row width on Palmer amaranth (Amaranthus palmeri) and pusley (Richardia spp.) demographics in glyphosate-resistant soybean. Weed Sci 56:408415 CrossRefGoogle Scholar
Jhala, AJ, Norsworthy, JK, Ganie, ZA, Sosnoskie, LM, Beckie, HJ, Mallory-Smith, CA, Liu, J, Wei, W, Wang, J, Stoltenberg, DE (2021) Pollen-mediated gene flow and transfer of resistance alleles from herbicide-resistant broadleaf weeds. Weed Technol:35:173187 CrossRefGoogle Scholar
Jhala, AJ, Sandell, LD, Rana, N, Kruger, GR, Knezevic, SZ (2014) Confirmation and control of triazine and 4-hydroxyphenylpyruvate dioxygenase-inhibiting herbicide-resistant Palmer amaranth (Amaranthus palmeri) in Nebraska. Weed Technol 28:2838 CrossRefGoogle Scholar
Keeley, PE, Carter, CH, Thullen, RJ (1987) Influence of planting date on growth of Palmer amaranth (Amaranthus palmeri). Weed Sci 35:199204 CrossRefGoogle Scholar
Klingaman, TE, Oliver, LR (1994) Palmer amaranth (Amaranthus palmeri) interference in soybeans (Glycine max). Weed Sci 42:523527 CrossRefGoogle Scholar
Knezevic, SZ, Evans, SP, Mainz, M (2003) Row spacing influences the critical timing for weed removal in soybean (Glycine max) Weed Technol 17:666673 CrossRefGoogle Scholar
Kniss, AR, Streibig, JC (2018) Statistical analysis of agricultural experiments using R. https://rstats4ag.org/. Accessed: September 23, 2020Google Scholar
Kumar, V, Liu, R, Boyer, G, Stahlman, PW (2019) Confirmation of 2,4-D resistance and identification of multiple resistance in a Kansas Palmer amaranth (Amaranthus palmeri) population. Pest Manag Sci 75:29252933 CrossRefGoogle Scholar
Lenth, R (2019) emmeans: Estimated marginal neans, aka least-squares means. https://cran.r-project.org/package=emmeans. Accessed: September 30, 2020Google Scholar
Manuchehri, MR, Dotray, PA, Keeling, JW (2017) Enlist weed control systems for palmer amaranth (Amaranthus palmeri) management in Texas high plains cotton. Weed Technol 31:793798 CrossRefGoogle Scholar
Massinga, RA, Currie, RS, Horak, MJ, Boyer, J (2001) Interference of Palmer amaranth in corn. Weed Sci 49:202208 CrossRefGoogle Scholar
Meyer, CJ, Norsworthy, JK, Young, BG, Steckel, LE, Bradley, KW, Johnson, WG, Loux, MM, Davis, VM, Kruger, GR, Bararpour, MT, Ikley, JT, Spaunhorst, DJ, Butts, TR (2015) Herbicide program approaches for managing glyphosate-resistant Palmer amaranth (Amaranthus palmeri) and waterhemp (Amaranthus tuberculatus and Amaranthus rudis) in future soybean-trait technologies. Weed Technol 29:716729 CrossRefGoogle Scholar
Meyers, SL, Jennings, KM, Schultheis, JR, Monks, DW (2010) Interference of Palmer amaranth (Amaranthus palmeri) in sweetpotato. Weed Sci 58:199203 CrossRefGoogle Scholar
Monks, DW, Oliver, LR (1988) Interactions between soybean (Glycine max) cultivars and selected weeds. Weed Sci 36:770774 CrossRefGoogle Scholar
Norsworthy, JK, Jha, P, Bridges, W (2007) Sicklepod (Senna obtusifolia) survival and fecundity in wide- and narrow-row glyphosate-resistant soybean. Weed Sci 55:252259 CrossRefGoogle Scholar
R Core Team (2018) R: A language and environment for statistical computing. Vienna, Austria: R foundation for statistical computing. https://www.r-project.org/. Accessed: September 23, 2020Google Scholar
Ritz, C, Kniss, AR, Streibig, JC (2015) Research methods in weed science: Statistics. Weed Sci 63:166187 Google Scholar
Rosenbaum, KK, Massey, RE, Bradley, KW (2013) Comparison of weed control, yield, and net income in conventional, glyphosate-resistant, and glufosinate-resistant soybean. Crop Management 12:19 https://doi.org/10.1094/CM-2013-0028-RS CrossRefGoogle Scholar
Sarangi, D, Jhala, AJ (2018) A statewide survey of stakeholders to assess the problem weeds and weed management practices in Nebraska. Weed Technol 32:642655 CrossRefGoogle Scholar
Sarangi, D, Jhala, AJ (2019) Palmer amaranth (Amaranthus palmeri) and velvetleaf (Abutilon theophrasti) control in no-tillage conventional (non–genetically engineered) soybean using overlapping residual herbicide programs. Weed Technol 33:95105 CrossRefGoogle Scholar
Sauer, J (1957) Recent migration and evolution of the dioecious amaranths. Evolution 11:1131 CrossRefGoogle Scholar
Schwartz-Lazaro, LM, Norsworthy, JK, Scott, RC, Barber, LT (2017) Resistance of two Arkansas Palmer amaranth populations to multiple herbicide sites of action. Crop Prot 96:158163 CrossRefGoogle Scholar
Scott, B, Smith, K (2011) Prevention and control of glyphosate-resistant pigweed in soybean and cotton. Little Rock: University of Arkansas, Division of Agriculture. https://www.uaex.edu/publications/pdf/FSA-2152.pdf. Accessed: February 28, 2021Google Scholar
Shyam, C, Chahal, PS, Jhala, AJ, Jugulam, M (2021) Management of glyphosate-resistant Palmer amaranth (Amaranthus palmeri) in 2,4-D choline, glufosinate, and glyphosate-resistant soybean. Weed Technol 35:136143 CrossRefGoogle Scholar
Sellers, BA, Smeda, RJ, Johnson, WG, Kendig, JA, Ellersieck, MR (2003) Comparative growth of six Amaranthus species in Missouri. Weed Sci 51:329333 CrossRefGoogle Scholar
Spaunhorst, DJ, Siefert-Higgins, S, Bradley, KW (2014) Glyphosate-resistant giant ragweed (Ambrosia trifida) and waterhemp (Amaranthus rudis) management in dicamba-resistant soybean (Glycine max). Weed Technol 28:131141 CrossRefGoogle Scholar
Steckel, L (2020) Dicamba-resistant Amaranth in Tennessee: Stewardship even more important. University of Tennessee Crops News. https://news.utcrops.com/2020/07/dicamba-resistant-palmer-amaranth-in-tennessee-stewardship-even-more-important/. Assessed: February 21, 2021Google Scholar
Striegel, A, Eskridge, KM, Lawrence, NC, Knezevic, SZ, Kruger, GR, Proctor, CA, Hein, GL, Jhala, AJ (2020) Economics of herbicide programs for weed control in conventional, glufosinate, and dicamba/glyphosate-resistant soybean across Nebraska. Agron J 112:51585179 CrossRefGoogle Scholar
Stroup, WW (2015) Rethinking the analysis of non-normal data in plant and soil science. Agron J 107:811827 CrossRefGoogle Scholar
[USGS] United States Geological Survey (2020) Estimated agricultural use for glyphosate. http://water.usgs.gov/nawqa/pnsp/usage/maps/show_map.php?year=1996&map=GLYPHOSA%0ATE&hilo=L. Accessed: May 2, 2020Google Scholar
Vieira, BC, Samuelson, SL, Alves, GS, Gaines, TA, Werle, R (2018) Distribution of glyphosate-resistant Amaranthus spp. in Nebraska. Pest Manag Sci 74:23162324 CrossRefGoogle ScholarPubMed
Ward, SM, Webster, TM, Steckel, LE (2013) Palmer amaranth (Amaranthus palmeri): A review. Weed Technol 27:1227 CrossRefGoogle Scholar
Warnes, G, Bolker, B, Lumley, T (2018) gmodels: Various R programming tools for model fitting. https://cran.r-project.org/package=gmodels. Accessed: September 30, 2020Google Scholar
Wax, LM, Pendleton, JW (1968) Effect of row spacing on weed control in soybeans. Weed Sci 16:462465 CrossRefGoogle Scholar
Webster, TM, Nichols, RL (2012) Changes in the prevalence of weed species in the major agronomic crops of the southern United States: 1994/1995 to 2008/2009. Weed Sci 60:145157 CrossRefGoogle Scholar
Werle, R, Oliveira, MC, Jhala, AJ, Proctor, CA, Rees, J, Klein, R (2018) Survey of Nebraska farmers’ adoption of dicamba-resistant soybean technology and dicamba off-target movement. Weed Technol 32:754761 CrossRefGoogle Scholar
Whitaker, JR, York, AC, Jordan, DL, Culpepper, AS (2010) Palmer amaranth (Amaranthus palmeri) control in soybean with glyphosate and conventional herbicide systems. Weed Technol 24:403410 CrossRefGoogle Scholar
Woodburn, AT (2000) Glyphosate: production, pricing and use worldwide. Pest Manag Sci 56:309312 3.0.CO;2-C>CrossRefGoogle Scholar
Wortman, SE (2014) Integrating weed and vegetable crop management with multifunctional air-propelled abrasive grits. Weed Technol 28:243252 CrossRefGoogle Scholar
Figure 0

Table 1. Herbicides and application timings, rates, and products used for control of glyphosate-resistant Palmer amaranth in dicamba/glyphosate-resistant soybean in field experiments conducted near Carleton, NE, in 2018 and 2019.

Figure 1

Figure 1. Average daily air temperature (ºC) and total cumulative precipitation (mm) received during the 2018 and 2019 growing seasons compared to the 30-year average for dryland field experiments conducted to determine the effect of row spacing and herbicide programs for control of glyphosate-resistant Palmer amaranth in dicamba/glyphosate-resistant soybean near Carleton, Nebraska, in 2018 and 2019.

Figure 2

Table 2. Effect of row spacing and herbicide programs on control of glyphosate-resistant Palmer amaranth in dicamba/glyphosate-resistant soybean 14 and 21 DAPRE in rainfed field experiments conducted near Carleton, NE, in 2018 and 2019.

Figure 3

Table 3. Control of glyphosate-resistant Palmer amaranth at 14 and 21 DAEPOST and 21 DALPOST in dryland field experiments conducted near Carleton, NE to determine the effect of row spacing and herbicide programs in dicamba/glyphosate-resistant soybean in 2018 and 2019.

Figure 4

Table 4. Interaction of herbicide programs and row spacing (38 cm or 76 cm) for control of glyphosate-resistant Palmer amaranth at 21 DAEPOST and 21 DALPOST and biomass reduction at pre-harvest in rainfed field experiments conducted near Carleton, NE, in dicamba/glyphosate-resistant soybean in 2018 and 2019.

Figure 5

Table 5. Pre-harvest control of glyphosate-resistant Palmer amaranth and soybean yield in rainfed field experiments conducted near Carleton, NE to determine the effect of row spacing and herbicide program in dicamba/glyphosate-resistant soybean in 2018 and 2019.

Figure 6

Table 6. Effect of row spacing and herbicide programs on glyphosate-resistant Palmer amaranth biomass reduction at 14 DAEPOST, 14 DALPOST, and pre-harvest in rainfed field experiments conducted near Carleton, NE in dicamba/glyphosate-resistant soybean in 2018 and 2019.

Figure 7

Table 7. Effect of row spacing and herbicide programs on glyphosate-resistant Palmer amaranth density at 14 DAEPOST and 14 DALPOST in rainfed field experiments conducted near Carleton, NE in dicamba/glyphosate-resistant soybean in 2018 and 2019.

Figure 8

Table 8. Interaction of herbicide programs and row spacing for glyphosate-resistant Palmer amaranth density at 14 DAEPOST in rainfed field experiments conducted near Carleton, NE in dicamba/glyphosate-resistant soybean in 2018 and 2019.