Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-27T12:02:19.745Z Has data issue: false hasContentIssue false

Biologically effective dose of diflufenican applied preemergence for the control of multiple herbicide–resistant waterhemp in corn

Published online by Cambridge University Press:  03 June 2024

Nader Soltani*
Affiliation:
Adjunct Professor, University of Guelph, Ridgetown, ON, Canada
Christian Willemse
Affiliation:
Former Graduate Student, University of Guelph, Ridgetown, ON, Canada
Peter H. Sikkema
Affiliation:
Adjunct Professor, University of Guelph, Ridgetown, ON, Canada
*
Corresponding author: Nader Soltani; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Waterhemp is a dioecious species with wide genetic diversity which has enabled it to evolve resistance to several commonly used herbicide groups in North America. Five field trials were established in Ontario to ascertain the biologically effective doses of diflufenican, a new Group 12 herbicide applied preemergence for control of multiple herbicide–resistant (MHR) waterhemp in corn. Based on regression analysis, the predicted diflufenican doses to elicit 50%, 80%, and 95% MHR waterhemp control were 99, 225, and 417 g ai ha−1, respectively, at 2 wk after application (WAA); 73, 169, and 314 g ai ha−1, respectively, at 4 WAA; and 76, 215, and — (meaning the effective dose was beyond the set of doses in this study) g ai ha−1, respectively, at 8 WAA. The predicted diflufenican doses that would cause a 50%, 80%, and 95% decreases in MHR waterhemp density were 42, 123, and — g ai ha−1; and MHR waterhemp biomass were 72, 167, and 310 g ai ha−1, respectively, at 8 WAA. Diflufenican applied preemergence at 150 g ai ha−1 controlled MHR waterhemp by 64%, 79%, and 73% at 2, 4, and 8 WAA, respectively. Isoxaflutole + atrazine applied preemergence at 105 + 1,060 g ai ha−1 controlled MHR waterhemp by 98%, 98%, and 97% at 2, 4, and 8 WAA, respectively; and S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence at 1,259/140/35/588 g ai ha−1 controlled MHR waterhemp by 100%, 100%, and 99% at 2, 4, and 8 WAA, respectively. Diflufenican applied preemergence reduced MHR waterhemp density and biomass by 83%; in contrast, isoxaflutole + atrazine and S-metolachlor/mesotrione/bicyclopyrone/atrazine reduced MHR waterhemp density and biomass by 99%. All treatments evaluated caused either no, or minimal, corn injury and resulted in corn yield that was similar with the weed-free control. Results indicate that diflufenican applied alone preemergence does not provide superior MHR waterhemp control over the commonly used herbicides isoxaflutole + atrazine or S-metolachlor/mesotrione/bicyclopyrone/atrazine; however, there is potential for using diflufenican as part of an integrated weed management strategy for the control of MHR waterhemp control in corn.

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, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

Corn is an important agricultural product in Canada and contributes substantially to the nation’s economy. Canada ranks 11th in global corn production, with nearly 1.5 billion kg of grain corn produced annually (Statista 2024). Nearly 65% of Canadian grain corn is produced in Ontario (OMAFRA 2023). In 2022, Ontario corn growers seeded approximately 1 million ha and produced approximately 9.4 billion kg of grain corn with farm cash receipts of nearly Can$2 billion (OMAFRA 2024). In 2022, the amount of corn exported to other markets (mainly Ireland, Spain, and other European countries) amounted to nearly 1 billion kg, valued at Can$375 million (McCulloch Reference McCulloch2023). The continuous increase in corn consumption globally necessitates improving corn productivity so that supply meets demand. One of the most impeding factors in corn productivity is yield loss due to weed interference, especially recently confirmed multiple herbicide–resistant (MHR) weed biotypes such as waterhemp.

Waterhemp is a dioecious weed with wide genetic diversity that has enabled it to evolve resistance to several herbicide groups (groups 2, 4, 5, 9, 14, 15, and 27 as categorized by the Weed Science Society of America [WSSA]) (Bell and Tranel Reference Bell and Tranel2010; Cordes et al. Reference Cordes, Johnson, Scharf and Smeda2004; Heap Reference Heap2024). A recent WSSA survey has placed waterhemp among the most problematic weed species in the United States (Van Wychen Reference Van Wychen2016). Waterhemp biotypes in Ontario have evolved resistance to herbicides in WSSA groups 2, 5, 9, 14, and/or 27 (Benoit et al. Reference Benoit, Hedges, Schryver, Soltani, Hooker, Robinson, Laforest, Soufiane, Tranel, Giacomini and Sikkema2019a; Heap Reference Heap2024; Symington et al. Reference Symington, Soltani and Sikkema2022). MHR waterhemp has been found in 17 Ontario counties spanning more than 800 km across the southern portion of the province (Soltani et al. Reference Soltani, Geddes, Laforest, Dille and Sikkema2022). A recent metadata analysis has estimated that MHR waterhemp exists in 1% of field crop hectares in Ontario. If left uncontrolled MHR waterhemp caused an average of 19% reduction in corn yield with a farm cash receipts value of Can$3.1 million annually (Soltani et al. Reference Soltani, Geddes, Laforest, Dille and Sikkema2022). Steckel and Sprague (Reference Steckel and Sprague2004) observed as much as 74% corn yield loss from waterhemp interference. No new herbicide mode of action has been commercialized in Canada for use on corn in more than two decades. Corn producers need new herbicide modes of action to control yield-robbing weed species such as MHR waterhemp.

Diflufenican (C19H11F5N2O2) is a WSSA Group 12 selective contact and residual herbicide from the phenyl ether chemical family. In Europe, diflufenican has been commercialized for weed management in cereals and lentils for several years (Effertz Reference Effertz2021). Diflufenican was just registered for use in February 2024 by Canada’s Pest Management Regulatory Agency and is pending approval from the U.S. Environmental Protection Agency for use on soybean and corn (Effertz Reference Effertz2021). Diflufenican, combined with other herbicides, can contribute to the control of two important weed species in North America: MHR waterhemp and MHR Palmer amaranth (Effertz Reference Effertz2021). No other herbicide from WSSA Group 12 has been marketed for weed management in corn and soybean in North America (Effertz Reference Effertz2021). Diflufenican can be applied preemergence to control MHR waterhemp (Effertz Reference Effertz2021; Haynes and Kirkwood Reference Haynes and Kirkwood1992; Tejada Reference Tejada2009). It is primarily absorbed by the shoots of seedlings and has limited translocation within plants (Ashton et al. Reference Ashton, Abulnaja, Pallett, Cole and Harwood1994; Conte et al. Reference Conte, Morali, Galli, Imbroglini and Leake1998; Haynes and Kirkwood Reference Haynes and Kirkwood1992). Diflufenican disrupts the biosynthesis of carotenoids, a crucial pigment for photosynthesis, and the protection of plants from harmful high-energy light (Miras-Moreno et al. Reference Miras-Moreno, Pedreño, Fraser, Sabater-Jara and Almagro2019). In the absence of carotenoids, susceptible plants cannot shield their cells from harmful high-light energy, leading to growth cessation and total necrosis of plants within days (Haynes and Kirkwood Reference Haynes and Kirkwood1992). Diflufenican has low water solubility and low volatility, low toxicity to honeybees and mammals if ingested, does not persist in the soil, and has a relatively favorable environmental profile (Ashton et al. Reference Ashton, Abulnaja, Pallett, Cole and Harwood1994; Bending et al. Reference Bending, Lincoln and Edmondson2006).

Waterhemp has not evolved resistance to herbicides from Group 12; therefore, diflufenican offers a new mode of action for the control of MHR waterhemp in corn and can be an ideal herbicide partner with other available herbicides to diversify modes of action and minimize selection pressure for the evolution of additional herbicide-resistant weed biotypes. The biologically effective dose of diflufenican for MHR waterhemp control in corn has not been assessed under Ontario environmental conditions. Additionally, there has been little research to compare the efficacy of diflufenican compared to herbicides currently used on corn for the control of MHR waterhemp, including isoxaflutole + atrazine and S-metolachlor/mesotrione/bicyclopyrone/atrazine.

This research was conducted to determine the biologically effective dose of diflufenican applied preemergence for control of MHR waterhemp in corn and to compare the control of MHR waterhemp with diflufenican to isoxaflutole + atrazine and S-metolachlor/mesotrione/bicyclopyrone/atrazine.

Materials and Methods

Five field trials were carried out in 2017 and 2018 in growers’ fields with naturally occurring MHR waterhemp in southwestern Ontario, Canada. In 2017, two trials were conducted on Walpole Island, ON, and one near Cottam, ON; and in 2018, one trial was conducted on Walpole Island, ON, and one near Cottam, ON.

Field trials were set up as a randomized complete block design with four replicates. Experiment treatments included a weedy control, weed-free control, diflufenican applied preemergence at 60, 90, 120, 150, 180, and 210 g ai ha−1; isoxaflutole + atrazine applied preemergence at 105 + 1,060 g ai ha−1, and S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence at 1,259/140/35/588 g ai ha−1. Plots were 8 m long and 3 m wide and consisted of four rows (0.75 m apart) of glyphosate/glufosinate-resistant corn (DKC45-65RIB®/DKC42-60RIB®; Bayer Cropscience, Mississauga, ON) seeded at a rate of approximately 80,000 seeds ha−1.

Treatments were applied preemergence with a CO2-pressurized backpack sprayer adjusted to deliver 200 L ha−1 at 240 kPa. The spray boom was 1.5 m long and had four nozzles (ULD120-02; Pentair Hypro, New Brighton, MN) spaced 50 cm apart, producing a spray width of 2 m.

Corn injury evaluations were completed at 1, 2, 4, and 8 wk after emergence, and MHR waterhemp control evaluations were completed at 2, 4, and 8 wk after application (WAA) on a scale of 0% (no corn injury/waterhemp control) to 100% (corn/waterhemp death). The MHR waterhemp density and aboveground biomass were determined at 8 WAA by clipping all waterhemp plants within two 0.25-m2 randomly placed quadrats in each plot. Aboveground dry biomass was then determined by oven-drying clipped waterhemp plants at 65 C to constant moisture. At corn harvest maturity, the two middle rows of each plot were harvested with a small-plot research combine; corn grain moisture content and mass were recorded. Corn yield was adjusted to 15.5% moisture.

Non-Linear Regression Analysis

Waterhemp control, density, and biomass data were regressed against the dose of diflufenican using the NLIN procedure with SAS software (SAS Institute Inc., Cary, NC). An exponential to maximum model (Equation 1) was used to model waterhemp control at 2, 4, and 8 WAA against the dose of diflufenican from 0 to 210 g ha−1. Similarly, waterhemp density and biomass were regressed against diflufenican dose using an inverse exponential model (Equation 2).

Exponential to maximum:

([1]) $$y = a - b{e^{\left( { - c{\rm{*}}dose} \right)}}$$

where y = response parameter, a = upper asymptote, b = magnitude, and c = slope.

Inverse exponential:

([2]) $$y = a + b{e^{\left( { - c{\rm{*}}dose} \right)}}$$

where y = response parameter, a = lower asymptote, b = change in Y from intercept to a, and c = slope.

Parameters generated from each regression analysis were used to calculate the expected dose (EDn) of diflufenican for 50%, 80%, and 95% waterhemp control, and a 50%, 80%, and 95% reduction in waterhemp plant density and biomass. Diflufenican dose was reported as — when it could not be calculated by the model.

Model Goodness of Fit

Model efficiency (ME; Equation 3) and root mean square error (RMSE; Equation 4) were calculated to determine goodness of fit for each regression model as suggested by Soltani et al. (Reference Soltani, Oliveira, Alves, Werle, Norsworthy, Sprague, Young, Reynolds, Brown and Sikkema2020):

([3]) $$ME = 1 - \left[ {{{\mathop \sum \nolimits_{i = 1}^n {{\left( {Oi - Pi} \right)}^2}}} \over {{\mathop \sum \nolimits_{i = 1}^n {{\left( {Oi - i} \right)}^2}}}} \right]$$
([4]) $$RMSE = {\rm{\;}}\sqrt {{{RSS}} \over {{\left( {n - p - 1} \right)}}} $$

where Oi is the observed, Pi is the predicted, Oi is the mean observed value, RSS is the residual sum of squares, n is the number of data points, and p is the number of parameters. Model efficiency ranges from negative infinity (−∞) to 1; values closer to 1 signify better goodness of fit.

Least-Square Means Comparisons

Data were analyzed with SAS software using the GLIMMIX procedure. Variances were partitioned into the fixed effect of herbicide treatment and the random effects of environment (location-year combinations), block nested within environment, and the environment-by-treatment interaction. Waterhemp control at 2, 4, and 8 WAA were arcsine square root–transformed prior to analysis using a normal distribution with identity link; nontransformed means were presented based on the interpretation of transformed data. Waterhemp density and biomass were analyzed using the log-normal distribution with identity link. The Pearson chi-square/degrees of freedom ratio and Shapiro-Wilk statistic were used to determine model fitness for each parameter and eliminate potential overdispersion. Studentized residual plots and normal probability plots were used to confirm the homogeneity of variance and the assumptions of normality, respectively. Means were separated using Tukey’s least significant difference at an alpha level of 0.05. Data analyzed using a log-normal distribution were back-transformed using the omega method.

Results and Discussion

Corn injury was minimal and environment-specific; therefore, regression equations were not generated for injury data.

Table 1. Regression parameters and the predicted doses of diflufenican for 50%, 80%, and 95% control of multiple herbicide–resistant waterhemp at 2, 4, and 8 wk after application; and reductions of 50%, 80%, and 95% in density and biomass at 8 wk after application from five field trials in 2017 and 2018. a

a Abbreviations: EDn, effective dose to elicit response level n; WAA, weeks after application. –,.

b Regression parameter values in parentheses indicate ±SE.

c Regression parameters: y = a − b(e −c*dose), where a is the upper asymptote, b is the magnitude, and c is the slope.

d Regression parameters: y = a + b(e −c*dose), where a is the lower asymptote, b is the change in y from the intercept to a, and c is the slope.

e A dash (—) indicates the effective dose could not be estimated by the model or was beyond the set of doses in this study.

Table 2. Multiple herbicide–resistant waterhemp control 2, 4, and 8 wk after application; density and biomass at 8 wk after application; and corn yield provided by diflufenican and industry-standard herbicides applied preemergence from five field trials in 2017 and 2018. a, b

a Abbreviations: WAA; weeks after application.

b Means followed by the same letter within a column are not significantly different according to Tukey’s LSD test (P > 0.05).

Biologically Effective Doses of Diflufenican Applied Preemergence for MHR Waterhemp Control

The predicted diflufenican doses to elicit 50%, 80%, and 95% control of MHR waterhemp were 99, 225, and 417 g ai ha−1 at 2 WAA; 73, 169, and 314 g ai ha−1 at 4 WAA; and 76, 215, and — (the effective dose was beyond the set of doses in this study) g ai ha−1 at 8 WAA, respectively (Table 1). The predicted diflufenican doses that caused a 50%, 80%, and 95% decrease in MHR waterhemp density were 42, 123, and — g ai ha−1, and the doses that caused a 50%, 80%, and 95% decrease in MHR waterhemp biomass were 72, 167, and 310 g ai ha−1, respectively (Table 1). No other studies have been published on the biologically effective dose of diflufenican for MHR waterhemp control in corn. Studies conducted by Sarangi and Jhala (Reference Sarangi and Jhala2017) determined that the calculated doses of S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence to elicit 50% and 90% control of glyphosate-resistant waterhemp in corn were 94 and 586 g ha−1 at 2 WAA; 149 and 1,173 g ha−1 at 5 WAA, and 251 and 2,796 g ha−1 at 9 WAA, respectively. The same study determined that the calculated doses of S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence to elicit 50% and 90% reduction in density of glyphosate-resistant waterhemp were 274 and 2,824 g ai ha−1 and glyphosate-resistant waterhemp biomass were 229 and 2,389 g ai ha−1, respectively, at 9 WAA.

Control of MHR Waterhemp with Diflufenican Compared to Isoxaflutole + Atrazine and S-Metolachlor/Mesotrione/Bicyclopyrone/Atrazine

Diflufenican (150 g ai ha−1), isoxaflutole + atrazine (105 + 1,060 g ai ha−1), and S-metolachlor/mesotrione/bicyclopyrone/atrazine (1,259/140/35/588 g ai ha−1) applied preemergence controlled MHR waterhemp by 64%, 98%, and 100%, respectively, at 2 WAA; by 79%, 98%, and 100%, respectively, at 4 WAA; and by 73%, 97%, and 99%, respectively, at 8 WAA (Table 2). Studies on the efficacy of diflufenican for the control of MHR waterhemp in corn are scant. Studies conducted by Benoit et al. (Reference Benoit, Soltani, Hooker, Robinson and Sikkema2019b) with single-active-ingredient herbicides demonstrated only 73% to 83% control of MHR waterhemp with S-metolachlor, 71% to 79% control with dimethenamid-P, 74% to 81% control with pyroxasulfone, 44% to 55% control with pethoxamid, 65% to 73% control with atrazine, and 42% to 54% control with dicamba. However, Willemse et al. (Reference Willemse, Soltani, Benoit, Hooker, Jhala, Robinson and Sikkema2021) observed that multiple-active-ingredient herbicide mixtures such as isoxaflutole + atrazine applied preemergence controlled MHR waterhemp by 70% to 97%, 77% to 97%, and 78% to 97% at 4, 8, and 12 WAA, respectively. In the same study, S-metolachlor/mesotrione/bicyclopyrone/atrazine controlled MHR waterhemp by 93% to 99% at various evaluation timings (Willemse et al. Reference Willemse, Soltani, Benoit, Hooker, Jhala, Robinson and Sikkema2021). Sarangi and Jhala (Reference Sarangi and Jhala2017) observed >95% MHR waterhemp control with S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence to corn. Additionally, Legleiter and Bradley (Reference Legleiter and Bradley2009) observed 98% control of glyphosate-resistant waterhemp with atrazine + mesotrione + S-metolachlor applied to corn 12 wk after emergence.

Diflufenican, isoxaflutole + atrazine, and S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence at the rates mentioned above reduced MHR waterhemp density by 83%, 99%, and 99%, respectively (Table 2). In other studies, Willemse et al. (Reference Willemse, Soltani, Benoit, Hooker, Jhala, Robinson and Sikkema2021) observed 94% and 99% reductions in density of MHR waterhemp with isoxaflutole + atrazine and S-metolachlor/mesotrione/bicyclopyrone/atrazine, respectively, applied preemergence to corn, which is comparable to the findings in this study. Similarly, Benoit et al. (Reference Benoit, Soltani, Hooker, Robinson and Sikkema2019b) documented 94% and 98% reductions in density of MHR waterhemp with isoxaflutole + atrazine and S-metolachlor/mesotrione/bicyclopyrone/atrazine, respectively, applied preemergence to corn. Vyn et al. (Reference Vyn, Swanton, Weaver and Sikkema2006) reported that the density of a triazine-resistant waterhemp population was reduced by 97% at 10 WAA with isoxaflutole + atrazine applied preemergence to corn.

Diflufenican, isoxaflutole + atrazine, and S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence at the rates mentioned above reduced MHR waterhemp biomass by 83%, 99%, and 99%, respectively (Table 2). Similarly, in other studies, Willemse et al. (Reference Willemse, Soltani, Benoit, Hooker, Jhala, Robinson and Sikkema2021) and Benoit et al. (Reference Benoit, Soltani, Hooker, Robinson and Sikkema2019b) observed up to 98% reductions in aboveground dry biomass of MHR waterhemp with isoxaflutole + atrazine and S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence to corn.

Diflufenican, isoxaflutole + atrazine, and S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence caused no crop injury to corn at 2, 4, and 8 WAA (data not shown). Additionally, all herbicide treatments evaluated resulted in similar corn yield (Table 2). These results are similar to those reported by Willemse et al. (Reference Willemse, Soltani, Benoit, Hooker, Jhala, Robinson and Sikkema2021) who documented no or minimal corn injury with isoxaflutole + atrazine or S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence to corn. Benoit et al. (Reference Benoit, Soltani, Hooker, Robinson and Sikkema2019b) also found transient visible corn injury with isoxaflutole + atrazine or S-metolachlor/mesotrione/bicyclopyrone/atrazine applied preemergence to corn. Similarly, Brown et al., (Reference Brown, Shropshire and Sikkema2016) found no corn injury with isoxaflutole + atrazine applied preplant to corn. Jha (Reference Jha2021), Lawson (Reference Lawson2017), and Richburg et al. (Reference Richburg, Norsworthy, Barber, Ford, Kelley and McKinney2019) also observed no visible corn injury or yield loss of corn with S-metolachlor/atrazine/mesotrione/bicyclopyrone applied preplant.

In conclusion, diflufenican applied preemergence at 150 g ai ha−1 provided lower MHR waterhemp control than the currently used multiple active ingredient herbicide mixtures of isoxaflutole + atrazine (105 + 1060 g ai ha-−1) and S-metolachlor/mesotrione/bicyclopyrone/atrazine (1259/140/35/588 g ai ha-−1). Diflufenican, with its unique site of action, has potential use as part of an integrated weed management strategy for the control of MHR waterhemp in corn. Future studies are needed to evaluate preemergence applications of diflufenican combined with other effective herbicides for control of MHR waterhemp and other weed species in corn.

Practical Implications

MHR waterhemp biotypes are present in 17 counties over a distance of 800 km, causing an average of 19% corn yield loss in Ontario. Herbicides with new modes of action are needed for managing MHR waterhemp in corn. Diflufenican is a new group 12 herbicide from the phenyl ether chemical family that has just been registered in Canada for control of MHR waterhemp in corn and soybean. Based on regression analysis, the predicted doses of diflufenican to elicit 95% MHR waterhemp control in corn were 417, 314, and — g ai ha−1 at 2, 4, and 8 WAA, respectively. Additionally, the predicted doses of diflufenican to elicit 50%, 80%, and 95% decreases in MHR waterhemp density were 42, 123, and — g ai ha−1, and MHR waterhemp biomass were 72, 167, and 310 g ai ha−1. Diflufenican applied preemergence caused no corn injury or yield reduction to corn. Based on these results, diflufenican applied preemergence alone does not provide superior MHR waterhemp control than the commonly used corn herbicides isoxaflutole + atrazine or S-metolachlor/mesotrione/bicyclopyrone/atrazine. However, diflufenican offers a new mode of action for the control of MHR waterhemp in corn and can be a complementary herbicide partner with other available herbicides to diversify modes of action and minimize the selection intensity for the evolution of additional herbicide-resistant weed biotypes.

Acknowledgments

We thank Dr. Michelle Edwards for her statistical support.

Funding

Funding for this research was provided by Grain Farmers of Ontario, Ontario Agri-Food Innovation Alliance, and Bayer Crop Science Inc.

Competing Interests

The authors declare they have no competing interests.

Footnotes

Associate Editor: Kevin Bradley, University of Missouri

References

Ashton, IA, Abulnaja, KO, Pallett, KE, Cole, DJ, Harwood, JL (1994) The mechanism of inhibition of fatty acid synthase by the herbicide diflufenican. Phytochemistry 35:587590 CrossRefGoogle Scholar
Bell, MS, Tranel, PJ (2010) Time requirement from pollination to seed maturity in waterhemp (Amaranthus tuberculatus). Weed Sci 58:163173 Google Scholar
Bending, GD, Lincoln, SD, Edmondson, RN (2006) Spatial variation in the degradation rate of the pesticides isoproturon, azoxystrobin and diflufenican in soil and its relationship with chemical and microbial properties. Env Pollution 139:279287 CrossRefGoogle ScholarPubMed
Benoit, L, Hedges, B, Schryver, MG, Soltani, N, Hooker, DC, Robinson, DE, Laforest, M, Soufiane, B, Tranel, PJ, Giacomini, D, Sikkema, PH (2019a) The first record of protoporphyrinogen oxidase and four-way herbicide resistance in eastern Canada. Can J Plant Sci 100:327331 CrossRefGoogle Scholar
Benoit, L, Soltani, N, Hooker, DC, Robinson, DE, Sikkema, PH (2019b) Control of multiple-resistant waterhemp [Amaranthus tuberculatus (Moq.) Sauer] with preemergence and postemergence herbicides in corn in Ontario. Can J Plant Sci 99:364370 CrossRefGoogle Scholar
Brown, LR, Shropshire, C, Sikkema, PH (2016) Control of glyphosate-resistant Canada fleabane in corn with preplant herbicides. Can J Plant Sci 96:932934 Google Scholar
Conte, E, Morali, G, Galli, M, Imbroglini, G, Leake, CR (1998) Long-term degradation and potential plant uptake of diflufenican under field conditions. J Agric Food Chem 46:47664770 CrossRefGoogle Scholar
Cordes, JC, Johnson, WG, Scharf, P, Smeda, RJ (2004) Late-emerging common waterhemp (Amaranthus rudis) interference in conventional tillage corn. Weed Technol 18:9991005 CrossRefGoogle Scholar
Effertz, AD (2021) Investigating the Impact of Soil Type, Soil Moisture, and Soil Surface Residue Cover on the Efficacy of Diflufenican [master’s thesis].Fort Collins: Colorado State University 85 p.Google Scholar
Haynes, C, Kirkwood, RC (1992) Studies on the mode of action of diflufenican in selected crop and weed species: Basis of selectivity of pre-and early post-emergence applications. Pestic Sci 35:161165 CrossRefGoogle Scholar
Heap, I (2024) The international herbicide-resistant weed database. http://www.weedscience.org/. Accessed: March 20, 2024Google Scholar
Jha, P (2021) Comparisons of One and Two-Pass Herbicide Programs for Weed Control in Corn. Publication ISRF20-16, 30. Ames: Iowa State University Google Scholar
Lawson, V (2017) Evaluation of new sweet corn herbicides. Farm Progress Report RFR-A1603. Ames: Iowa State University. https://doi.org/10.31274/farmprogressreports-180814-1620. Accessed: March 18, 2024CrossRefGoogle Scholar
Legleiter, TR, Bradley, KW (2009) Evaluation of herbicide programs for the management of glyphosate-resistant waterhemp (Amaranthus rudis) in maize. Crop Prot 28:917922 CrossRefGoogle Scholar
McCulloch, C (2023) Ontario grains by the numbers. Ontario Grain Farmers Magazine, October 2023. https://ontariograinfarmer.ca/2023/10/01/ontario-grains-by-the-numbers/. Accessed: March 18, 2024Google Scholar
Miras-Moreno, B, Pedreño, MA, Fraser, PD, Sabater-Jara, AB, Almagro, L (2019) Effect of diflufenican on total carotenoid and phytoene production in carrot suspension-cultured cells. Planta 249:113122 CrossRefGoogle ScholarPubMed
[OMAFRA] Ontario Ministry of Agriculture, Food and Rural Affairs (2023) 2023 Corn seasonal summary. https://fieldcropnews.com/2023/12/2023-corn-seasonal-summary/. Accessed: March 18, 2024Google Scholar
[OMAFRA] Ontario Ministry of Agriculture, Food and Rural Affairs (2024) Ontario field crop area and production estimates by county. https://www.ontario.ca/page/field-crops-statistics. Accessed: March 10, 2024Google Scholar
Richburg, JT, Norsworthy, JK, Barber, LT (2019). Herbicide programs with and without atrazine in corn. Pages 4247 in Ford, V, Kelley, J, McKinney, J II, eds., Corn and Grain Sorghum Research Studies 2019. University of Arkansas Division of Agriculture. https://scholarworks.uark.edu/cgi/viewcontent.cgi?article=1161&context=aaesser#page=45. Accessed: March 18, 2024Google Scholar
Sarangi, D, Jhala, AJ (2017). Biologically effective rates of a new premix (atrazine, bicyclopyrone, mesotrione, and S-metolachlor) for preemergence or postemergence control of common waterhemp [Amaranthus tuberculatus (Moq.) Sauer var. rudis] in corn. Can J Plant Sci 97:10751089 Google Scholar
Soltani, N, Geddes, C, Laforest, M, Dille, JA, Sikkema, PH (2022) Economic impact of glyphosate-resistant weeds on major field crops grown in Ontario. Weed Technol 36:629635 CrossRefGoogle Scholar
Soltani, N, Oliveira, MC, Alves, GC, Werle, R, Norsworthy, JK, Sprague, CL, Young, BG, Reynolds, DB, Brown, A, Sikkema, PH (2020) Off-target movement assessment of dicamba in North America. Weed Technol 34:318330 CrossRefGoogle Scholar
Statista (2024) Global corn production in 2023/2024, by country. https://www.statista.com/statistics/254292/global-corn-production-by-country. Accessed: March 11, 2024Google Scholar
Steckel, LE, Sprague, CL (2004) Common waterhemp (Amaranthus rudis) interference in corn. Weed Sci 52:359364 CrossRefGoogle Scholar
Symington, HE, Soltani, N, Sikkema, PH (2022) Confirmation of 4-hydroxyphenylpyruvate dioxygenase inhibitor-resistant and 5-way multiple-herbicide-resistant waterhemp in Ontario. J Agric Sci 14:5358 Google Scholar
Tejada, M (2009) Evolution of soil biological properties after addition of glyphosate, diflufenican and glyphosate + diflufenican herbicides. Chemosphere 76:365373 CrossRefGoogle ScholarPubMed
Van Wychen, L (2016) 2015 Survey of the Most Common and Troublesome Weeds in the United States and Canada. Lawrence, KS: Weed Science Society of America http://wssa.net/wp-content/uploads/2015-Weed-Survey_FINAL1.xlsx. Accessed: March 15, 2024Google Scholar
Vyn, JD, Swanton, CJ, Weaver, SE, Sikkema, PH (2006) Control of Amaranthus tuberculatus var. rudis (common waterhemp) with pre and post-emergence herbicides in Zea mays L. (maize). Crop Prot 25:10511056 CrossRefGoogle Scholar
Willemse, C, Soltani, N, Benoit, L, Hooker, DC, Jhala, AJ, Robinson, DE, Sikkema, PH (2021) Herbicide programs for control of waterhemp (Amaranthus tuberculatus) resistant to three distinct herbicide sites of action in corn. Weed Technol 35:753760 CrossRefGoogle Scholar
Figure 0

Table 1. Regression parameters and the predicted doses of diflufenican for 50%, 80%, and 95% control of multiple herbicide–resistant waterhemp at 2, 4, and 8 wk after application; and reductions of 50%, 80%, and 95% in density and biomass at 8 wk after application from five field trials in 2017 and 2018.a

Figure 1

Table 2. Multiple herbicide–resistant waterhemp control 2, 4, and 8 wk after application; density and biomass at 8 wk after application; and corn yield provided by diflufenican and industry-standard herbicides applied preemergence from five field trials in 2017 and 2018.a,b