Weed Control, Environmental Impact and Profitability of Pre-Plant Incorporated Herbicides in White Bean

Abstract

Three field experiments were conducted over a three-year period (2009 to 2011) to evaluate various preplant incorporated (PPI) herbicides in white bean in Ontario, Canada. There was minimal visible injury in white bean for any of the treatments evaluated. The control of AMARE, AMBEL, CHEAL, SETVI, and SINAR ranged 91%-93%, 13%-21%, 56%-92%, 96%-98%, and 16%-24% with pendimethalin, 93%-99%, 34%-43%, 65%-99%, 95%-100%, and 20%-47% with trifluralin, 66%-77%, 61%-76%, 64%-86%, 94%-99%, and 52%-74% with EPTC, 92%-98%, 27%-48%, 28%-76%, 96%-99%, and 33%-59% with s-metolachlor, 98% - 99%, 50%-72%, 33%-88%, 98%-99%, and 56%-78% with dimethenamid, and 98%-100%, 72%-84%, 97%-100%, 77%-88%, and 98%-100% with imazethapyr, respectively. Weed density and dry weight reduction were similar to visible weed control. Imazethapyr applied PPI at the 75 g ai ha-1 provided yield equivalent to the weed-free check in 2009 and 2011. All other herbicide treatments had significantly lower yield than weed-free check. All herbicide treatments except pendimethalin at 1080 g ai ha-1, EPTC at 4400 g ai ha-1, and imazethapyr at 75 g ai ha-1 had yield equivalent to the weed-free check in 2010. Based on environmental impact (EI) analysis, the herbicide program with the lowest environmental risk was imazethapyr followed by dimethenamid-p, trifluralin, s-metolachlor, EPTC, and then pendimethalin. Economic analysis of herbicide treatments evaluated indicates that imazethapyr had the greatest positive impact on profit margins, followed by dimethenamid-p and EPTC, followed by s-metolachlor and trifluralin and then pendimethalin.

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Soltani, N. , Nurse, R. , Shropshire, C. and Sikkema, P. (2012) Weed Control, Environmental Impact and Profitability of Pre-Plant Incorporated Herbicides in White Bean. American Journal of Plant Sciences, 3, 846-853. doi: 10.4236/ajps.2012.37102.

1. Introduction

North America is the largest producer of white bean (Phaseolus vulgaris L.) in the world [1]. In 2010, Ontario growers planted approximately 34,000 hectares and produced 82,600 tonnes of white bean with a farm gate value of $55,200,000 [2]. White bean has short stature and is not a strong competitor with weeds. Weed interference can result in large yield losses, reduce harvest efficiency, and may stain white bean resulting in reduced market value [3-5]. Troublesome weeds in white bean production in Ontario include common lamb’s-quarters (Chenopodium album L.), redroot pigweed (Amaranthus retroflexus L.), velvetleaf (Abutilon theophrasti Medic), wild mustard (Sinapis arvensis L.), common ragweed (Ambrosia artemisiifolia L.), Solanum spp. (annual nightshades), and green foxtail (Setaria viridis (L.) Beauv.) [6]. More research is needed to identify herbicides that have an adequate margin of crop safety, provide consistent weed control, have low environmental impact and maximize dry bean yield and net returns to white bean growers in Ontario.

Pendimethalin is a dinitroaniline selective herbicide that can control annual grasses such as barnyardgrass (Echinochloa crusgalli (L.) Beauv.), smooth crabgrass (Digitaria ischaemum (Schreb) Muhl.), large crabgrass (Digitaria sanguinalis (L.) Scop), fall panicum (Panicum dichotomiflorum Michx., giant foxtail (Setaria faberii Herrm.), S. viridis, yellow foxtail (Setaria glauca (L.) Beauv.), and certain annual broadleaf weed such as C. album and A. retroflexus including acetolactate synthase and triazine-resistant biotypes [6,7].

Trifluralin is a dinitroaniline herbicide that controls several annual grasses including Setaria, Digitaria, Echinochloa, and Panicum spp. and some broadleaved weeds such as C. album and A. retroflexus, including acetolactate synthase and triazine-resistant biotypes [6,7].

EPTC is a thiocarbamate herbicide that provides control of a number of annual grasses such as Setaria spp., D. sanguinalis, E. crusgalli, P. dichotomiflorum, and yellow nutsedge (Cyperus esculentus L.) [6,7]. EPTC can also control some broadleaf weeds such as C. album, A. retroflexus and S. media including acetolactate synthase and triazine-resistant biotypes [6].

S-metolachlor and dimethenamid-p are chloroacetanilide herbicides that can provide effective control of a number of annual grasses such as S. faberii, S. viridis, S. glauca, E. crusgalli, D. ischaemum, P. dichotomiflorum and P. capillare [6,7]. They also provide partial control of some small-seeded broadleaved weeds such as Solanum spp., C. album, and A. retroflexus.

Imazethapyr is an imidazolinone herbicide that controls several annual grass and broadleaved weeds including Setaria spp, E. crus-galli, P. capillare, Polygonum convolulus L. (wild buckwheat), Polygonum persicaria L. (ladysthumb), C. album, S. arvensis, Solanum spp., A. retroflexus, A. artemisiifolia, and A. theophrasti including triazine-tolerant biotypes [6-10].

Many factors are considered when selecting a weed management strategy including crop safety, weed spectrum, crop rotation, and costs. The environmental impact (EI) of herbicides should also be considered when making weed management decisions. By using lower herbicide application doses, the EI of weed control is reduced. One method to assess the EI of a pesticide is with the environmental impact quotient (EIQ) [11]. The EIQ uses toxicity (chronic, dermal, fish, bird, arthropod, and bee), leaching and surface loss potential, and soil and plant half-life to estimate the relative potential risk of pesticide active ingredients. The EIQ has been used to compare environmental risk of different pesticides and/or production systems [12-14]. The EIQ was designed to provide growers and other decision makers with a single number that indicates the magnitude of relative risk. The EI of a particular pesticide treatment is obtained by multiplying the EIQ by the application rate. A higher EI indicates a greater risk of detrimental impact [11].

Identification of herbicides that provide consistent effective weed control, have low environmental impact and maximize dry bean yield and net returns would be of benefit to Ontario dry bean producers. There is little information on the relative efficacy, environmental impact and profitability of pendimethalin, trifluralin, EPTC, s-metolachlor, dimethenamid-p, and imazethapyr applied preplant incorporated (PPI) in white bean under Ontario environmental conditions.

The objectives of this study were to evaluate the efficacy, environmental impact and profitability of pendimethalin, trifluralin, EPTC, s-metolachlor, dimethenamid-p, and imazethapyr applied PPI in white bean.

2. Materials and Methods

Three field trials were conducted at the Huron Research Station, Exeter, Ontario in 2009 to 2011. The soil was a Brookston clay loam (Orthic Humic Gleysol, mixed, mesic, and poorly drained) with 44% sand, 33% silt, 23% clay, 4.1% organic matter and pH of 7.9 in 2009; 32% sand, 40% silt, 28% clay, 4.5% organic matter and pH of 7.8 in 2010, and 35% sand, 43% silt, 22% clay, 4% organic matter and pH of 7.8 in 2011. Seedbed preparation at all sites consisted of autumn moldboard plowing followed by seedbed preparation and herbicide incorporation with a S-tine cultivator with rolling basket harrows in the spring.

The experiment was arranged in a randomized block design with treatments replicated four times. Treatments are shown in Tables 1-5. Each plot was 3.0 m wide and 10 m long and consisted of four rows of “T9905” white bean spaced 0.75 m apart. White bean was planted at a rate of 250,000 seeds∙ha−1 on May 22, 2009, May 25, 2010 and June 3, 2011.

Herbicide treatments were applied using a CO2-pressurized backpack sprayer calibrated to deliver 200 L∙ha1 at 240 kPa. The boom was 1.5 m long with four ultra-low drift nozzles (ULD120-02, Hypro, New Brighton, MN) spaced 50 cm apart. The surface area sprayed was the center 2.0 m of each plot by 10.0 m in length. There was a 1.0 m unsprayed area between adjacent plots. Preplant incorporated herbicides were applied 1 - 2 days before planting and were immediately incorporated into the soil with two passes (in opposite directions) of an S-tine cultivator with rolling basket harrows. Weed-free plots were maintained weed free during the growing season by hand hoeing as required.

White bean injury and weed control were visually estimated on a scale of 0 (no injury/control) to 100% (complete plant death) 1 and 4 weeks after crop emergence (WAE), and 4 and 8 WAE, respectively. Weed density and dry weight were evaluated 8 WAE by counting and cutting plants at the soil surface in two 0.5 m2 quadrats per plot and separating by species. Plants were dried at 60 C to constant moisture and then weighed. White bean was considered mature when 90% of the pods in the weed-free check had turned from green to a golden colour. Beans were harvested from each plot with a small plot combine, weight and moisture were recorded, and yields were adjusted to 18% moisture.

Data were analyzed using PROC MIXED in SAS 9.2. Herbicide treatment was considered a fixed effect, while environment (year), environment by treatment interaction, and replicate nested within environment were considered random effects. Significance of fixed effects were tested using F-tests and random effects were tested using a Z-test of the variance estimate. Environments were combined for a given variable if the environment by treatment interaction was not significant. The UNIVARIATE procedure was used to test data for normality and homogeneity of variance. Any treatment assigned a value of zero (weedy check for injury and weed control; weedfree check for injury, weed density and dry weights) was excluded from the analysis. However, all values were compared independently to zero to evaluate treatment differences with the weedy and/or weed-free checks. To satisfy the assumptions of the variance analyses, weed control for A. retroflexus and C. album (4 WAE only) and S. viridis were arcsine square root transformed, and all weed density and dry weights were log transformed. Treatment comparisons were made using Fisher’s Protected LSD at a level of P < 0.05. Data compared on the transformed scale were converted back to the original scale for presentation of results.

2.1. Environmental Impact

The EIQ values of pendimethalin, trifluralin, EPTC, s-metolachlor, dimethenamid-p, and imazethapyr were obtained from Kovach et al. [11]. The quantity of herbicide applied was multiplied by the EIQ to determine the EI.

2.2. Profit Margin

A partial economic analysis was conducted to determine the profit margins for each herbicide treatment. The margins were calculated using white bean yields, the average annual price received by white bean growers in Ontario from 2009 to 2011 (Ontario White Bean Producers’ Marketing Board) and herbicide costs in 2009-2011 reported by AGRIS Co-operative Ltd [15]. The profit margin per plot was calculated and data were analyzed using PROC MIXED in the same manner as above, and both the weedy and weed-free checks were excluded from analysis. Data were square root transformed to satisfy the assumptions of the variance analysis.

3. Results and Discussion

3.1. Crop Injury

There was minimal visible injury at 1 and 4 WAE and no effect on seed moisture content (maturity) of white bean for the herbicide treatments evaluated (data not shown).

3.2. Weed Control

Dominant weeds in this study as determined by quantification and qualification of non-treated control plots included A. retroflexus (AMARE), A. artemisiifolia (AMBEL), C. album (CHEAL), S. viridis (SETVI), and S. arvensis (SINAR).

Pendimethalin provided 91% - 93%, 13% - 21%, 56% - 92%, 96% - 98%, and 16% - 24% control of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Tables 1, 2).

Trifluralin provided 93% - 99%, 34% - 43%, 65% - 99%, 95% - 100%, and 20% - 47% control of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Tables 1, 2). Trifluralin applied at 600 or 1155 g·ai·ha−1 provided similar weed control except CHEAL control at 4 WAE and SETVI control at 8 WAE which were greater at the higher rate.

EPTC provided 66% - 77%, 61% - 76%, 64% - 86%, 94% - 99%, and 52% - 74% control of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Tables 1, 2). EPTC applied at 3400 or 4400 g·ai·ha−1 provided similar weed control except CHEAL control at 8 WAE in 2009 which was higher at 4400 g·ai·ha−1.

S-metolachlor provided 92% - 98%, 27% - 48%, 28% - 76%, 96% - 99%, and 33% - 59% control of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Tables 1, 2). S-metolachlor applied at 1050 or 1600 g·ai·ha−1 provided similar weed control except SINAR control at 4 WAE which was higher at 1600 g·ai·ha−1.

Dimethenamid-p provided 98% - 99%, 50% - 72%, 33% - 88%, 98% - 99%, and 56% - 78% control of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Tables 1, 2). There was no difference between dimethenamid-p rates for the control of the weeds evaluated.

Imazethapyr provided 98% - 100%, 72% - 84%, 97% - 100%, 77% - 88%, and 98% - 100% control of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Tables 1, 2). There was no difference between imazethapyr rates for the control of the weeds evaluated.

In other studies, there was no difference between s-metolachlor and trifluralin applied PPI for the control of AMARE and SETVI [16]. However, trifluralin applied PPI provided better control of CHEAL (83% vs. 71%) compared with s-metolachlor [16]. Wall [17] reported improved control of AMARE and CHEAL when imazethapyr was applied at 50 g∙ha−1 in white bean. Blackshaw and Esau [18] also found similar results in pinto bean. However, Cantwell et al. [19] reported that imazethapyr at 50 g∙ha−1 provided only 30% control of CHEAL in soybean.

3.3. Weed Density

There was no significant difference in SINAR density with herbicides evaluated (Table 3). Pendimethalin caused as much as 91%, 21%, 81%, and 91% reduction in density of AMARE, AMBEL, CHEAL, and SETVI (Table 3).

Trifluralin caused as much as 95%, 41%, 97%, and 97% reduction in density of AMARE, AMBEL, CHEAL, and SETVI, respectively (Table 3). Trifluralin applied at 600 or 1155 g·ai·ha−1 caused a similar decrease in density except for AMBEL and CHEAL density which were lower at the higher rate.

Table 1. Visual estimates of percent weed control 4 WAE with various PPI herbicides in white bean at Exeter, ON from 2009 to 2011. Means followed by the same letter within a column are not significantly different according to Fisher’s Protected LSD at P < 0.05.a

Table 2. Visual estimates of percent weed control 8 WAE with various PPI herbicides in white bean at Exeter, ON from 2009 to 2011. Means followed by the same letter within a column are not significantly different according to Fisher’s Protected LSD at P < 0.05a.

Table 3. Weed density 8 WAE with various PPI herbicides in white bean at Exeter, ON from 2009 to 2011. Means followed by the same letter within a column are not significantly different according to Fisher’s Protected LSD at P < 0.05a.

EPTC provided 85%, 63%, 86%, and 93% reduction in AMARE, AMBEL, CHEAL, and SETVI, respectively (Table 3). EPTC applied at 3400 or 4400 g·ai·ha−1 generally caused similar a similar decrease in density of the weeds evaluated.

S-metolachlor caused 97%, 46%, 72%, and 95% reduction in density of AMARE, AMBEL, CHEAL, and SETVI, respectively (Table 3). S-metolachlor applied at 1050 or 1600 g·ai·ha−1 generally caused similar a similar decrease in density of the weeds evaluated.

Dimethenamid-p caused 99%, 56%, 89%, and 97% reduction in density of AMARE, AMBEL, CHEAL, and SETVI, respectively (Table 3). There was no difference between dimethenamid-p rates in respect to weed density.

Imazethapyr caused 99%, 81%, 99%, and 83% reduction in density of AMARE, AMBEL, CHEAL, and SETVI, respectively (Table 3). There was no difference between imazethapyr rates in respect to weed density.

3.4. Weed Dry Weight

Pendimethalin caused 95%, 18%, 81%, 87%, 93%, and 51% reduction in dry weight of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Table 4).

Trifluralin caused 98%, 61%, 99%, 98%, and 77% reduction in dry weight of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Table 4). Trifluralin applied at 600 or 1155 g·ai·ha−1 caused a similar reduction in dry weight of weeds evaluated.

EPTC caused 89%, 90%, 87%, 96%, and 96% reduction in dry weight of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Table 4). EPTC applied at 3400 or 4400 g·ai·ha−1 caused a similar reduction of weeds evaluated.

S-metolachlor caused 99%, 56%, 81%, 97%, and 95% reduction in dry weight of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Table 4). S-metolachlor applied at 1050 or 1600 g·ai·ha−1 caused a similar reduction in dry weight of weeds evaluated.

Dimethenamid-p caused 100%, 57%, 93%, 98%, and 96% reduction in dry weight of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Table 4). There was no difference between dimethenamid-p rates in respect to weed dry weight reduction.

Imazethapyr caused 100%, 95%, 100%, 99%, 92%, and 100% reduction in dry weight of AMARE, AMBEL, CHEAL, SETVI, and SINAR, respectively (Table 4). There was no difference between the imazethapyr rates evaluated in respect to weed dry weight reduction.

3.5. Yield

Pendimethalin, trifluralin, EPTC, s-metolachlor, dimethenamid-p, and imazethapyr applied preplant incorporated increased yield of white bean as much as 35% -

Table 4. Weed dry weight 8 WAE with various PPI herbicides in white bean at Exeter, ON from 2009 to 2011. Means followed by the same letter within a column are not significantly different according to Fisher’s Protected LSD at P < 0.05a.

46%, 49% - 72%, 37% - 248%, 44% - 102%, 42% - 217%, and 37% - 426% compared to the weedy check, respectively (Table 5). However, only imazethapyr applied PPI at the 75 g·ai·ha1 provided yield equivalent to the weed-free check in 2009 and 2011 (Table 5). All other herbicide treatments had significantly lower yield than the weed-free check. All herbicide treatments except pendimethalin at 1080 g·ai·ha1, EPTC at 4400 g·ai·ha1, and imazethapyr at 75 g·ai·ha1 had yield equivalent to the weed-free check in 2010 (Table 5). Other studies have shown yield losses of 40% - 71% in white bean when broadleaf weeds such as AMARE and CHEAL were not adequately controlled [17]. Blackshaw and Esau [18] also reported 71% - 85% yield losses in pinto bean when AMARE and CHEAL were left uncontrolled.

3.6. Environmental Impact

The EI calculated based on Kovach [11] are listed in Table 5. The EI values ranged from 0.8 to 36.9 depending on the herbicide and rate evaluated. Based on the EI analysis, the herbicide program which resulted in the lowest environmental risk was imazethapyr (0.8 and 1.3) followed by dimethenamid-p (5.8 and 7.4), trifluralin (10.1 and 19.4), s-metolachlor (20.6 and 31.4), EPTC (28.5 and 36.9), and then pendimethalin (29.1). Lower rates of each herbicide resulted in a lower EI as expected (Table 5).

3.7. Profitability Analysis

In 2009 and 2011, imazethapyr applied PPI at 45 g·ai·ha1 had a profit margin of $1825.41 and when applied at 75 g·ai·ha1 had a profit margins $1912.97 which was significantly greater than dimethenamid-p and EPTC which at best had a profit margin of $1166.26. Profit margin with other herbicide treatments such as s-metolachlor, trifluralin, and pendimethalin were significantly lower and ranged from $503.51 to $660.41 (Table 5). In 2010, there was no difference in profit margin among the herbicides evaluated (Table 5).

4. Conclusion

Based on this study, there was minimal visible injury with pendimethalin, trifluralin, EPTC, s-metolachlor, dimethenamid-p, and imazethapyr applied PPI in white bean. The control of AMARE, AMBEL, CHEAL, SETVI, and SINAR were as much as 93%, 21%, 92%, 98%, and 24% with pendimethalin, 99%, 43%, 99%, 100%, and 47% with trifluralin, 77%, 76%, 86%, 99%, and 74% with EPTC, 98%, 48%, 76%, 99%, and 59% with s-metolachlor, 99%, 72%, 88%, 99%, and 78% with dimethenamid, and 100%, 84%, 100%, 88%, and 100% with imazethapyr, respectively. Weed density and dry

Table 5. White bean yield and profit margin for various PPI herbicide treatments at Exeter, ON from 2009 to 2011. Means followed by the same letter within a column are not significantly different according to Fisher’s Protected LSD at P < 0.05.

weight reductions were similar to visible weed control. Imazethapyr applied PPI at the 75 g·ai·ha1 provided yield equivalent to weed-free check in 2009 and 2011. All other herbicide treatments had significantly lower yield than the weed-free check. All herbicide treatments except pendimethalin at 1080 g·ai·ha1, EPTC at 4400 g·ai·ha1, and imazethapyr at 75 g·ai·ha1 had yield equivalent to the weed-free check in 2010. Based on EI analysis, the herbicide program which resulted in the lowest environmental risk was imazethapyr followed by dimethenamid-p, trifluralin, s-metolachlor, EPTC, and then pendimethalin. Lower rates of each herbicide provided lower risks to the environment as expected. Economic analysis of herbicide treatments evaluated indicates that imazethapyr had the greatest positive impact on profit margins, followed by dimethenamid-p and EPTC, followed by s-metolachlor and trifluralin and then pendimethalin.

5. Acknowledgements

The authors would like to acknowledge Todd Cowan for his expertise and technical assistance in these studies. Funding for this project was provided by the Ontario White Bean Producers and the Agricultural Adaptation Council.

NOTES

Conflicts of Interest

The authors declare no conflicts of interest.

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