Simulated herbicide spray retention on floating aquatic plants as affected by carrier volume and adjuvant type

Sperry, Benjamin P.; Mudge, Christopher R.; Getsinger, Kurt D.

doi:10.1017/wet.2021.85

Cited by 5 publications

(12 citation statements)

References 47 publications

(48 reference statements)

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“…All experiments used rhodamine WT (RWT) dye (Rhodamine WT Liquid; Keystone Aniline Corp., Chicago, IL) to approximate herbicide deposition. Doing this cost considerably less money than quantifying herbicides analytically (Mudge et al 2021; Sperry et al 2022). Use of RWT to follow trace aqueous herbicide movement has been used in a variety of field environments for decades (e.g., Fox et al 1991, 1993, 2002).…”

Section: Methodsmentioning

confidence: 99%

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Simulated herbicide spray retention of commonly managed invasive emergent aquatic macrophytes

et al. 2023

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Invasive emergent and floating macrophytes can have detrimental impacts on aquatic ecosystems. Management of these aquatic weeds frequently relies upon foliar application techniques with aquatic herbicides. However, there is inherent variability of overspray (herbicide loss) for foliar applications into waters within- and adjacent-to the targeted treatment area. The spray retention (tracer dye captured) of four invasive broadleaf emergent species: water hyacinth, alligatorweed, creeping water primrose, parrotfeather, and two emergent grass-like weeds: cattail and torpedograss were evaluated. For all species, spray retention was simulated using foliar applications of rhodamine WT dye (RWT) as an herbicide surrogate under controlled mesocosm conditions. Spray retention of the broadleaf species was first evaluated using a CO2-pressurized spray chamber overtop dense vegetation growth or no plants (positive control) at a greenhouse scale (GH). Broadleaf species and grass-like species were then evaluated in larger outdoor mesocosms (OM). These applications were made using a CO2-pressurized backpack sprayer. Evaluation metrics included species-wise canopy cover and height influence on in-water RWT concentration using image analysis and modeling techniques. Results indicated spray retention was greatest for water hyacinth (GH: 64.7 ± 7.4, OM: 76.1 ± 3.8). Spray retention values were similar among the three sprawling marginal species alligatorweed (GH: 37.5 ± 4.5, OM: 42 ± 5.7), creeping water primrose (GH: 54.9 ± 7.2, OM:52.7 ± 5.7), and parrotfeather (GH: 48.2 ± 2.3, OM: 47.2 ± 3.5). Canopy cover and height were strongly correlated with spray retention for broadleaf species and less strongly correlated for grass-like species. Torpedograss and cattail, while similar in percent foliar coverage, differed in percent spray retention (OM: 8.5± 2.3 and 28.9 ±4.1, respectively). The upright leaf architecture of the grass-like species likely influenced the lower spray retention values in comparison to the broadleaf species.

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Section: Methodsmentioning

confidence: 99%

“…Data were processed to account for differences in water volumes and pretreatment dye readings. The percentage of the applied spray solution that reached the water column was calculated following the methods described by Sperry et al (2022) and Mudge et al (2021) using the following formula: …”

Section: Methodsmentioning

confidence: 99%

Simulated herbicide spray retention of commonly managed invasive emergent aquatic macrophytes

et al. 2023

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“…Foliar aquatic herbicide applications are largely made via airboat using high carrier volumes (average 935 L ha −1 ) (Haller 2020). However, spray retention on the target plant can be low when using high carrier volumes (Sperry et al 2022), and recent research suggests that reducing carrier volume to 187 L ha −1 increases efficacy of glyphosate, diquat, and 2,4-D on the aquatic plant water hyacinth [ Eichhornia crassipes (Mart.) Solms] (Sperry and Ferrell 2021).…”

Section: Introductionmentioning

confidence: 99%

Sethoxydim performance on torpedograss (Panicum repens) and sand cordgrass (Spartina bakeri) as affected by carrier volume and rate

Sperry

Enloe

Prince

et al. 2023

Invasive plant sci. manag.

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Greenhouse experiments were conducted in 2020 to investigate the effects of carrier volume and sethoxydim rate on torpedograss (Panicum repens L.) control and sand cordgrass (Spartina bakeri Merr.) response from a single application. P. repens control and biomass reductions generally increased with increasing sethoxydim rates in evaluations at 14, 28, and 42 days after treatment (DAT); however, increasing rate to 2X the maximum labeled rate did not always result in increased efficacy. In the first experimental run which consisted of small plants, P. repens control and biomass reductions were largely similar among tested carrier volumes (37, 187, and 935 L ha-1). However, in run two which consisted of larger, mature P. repens plants, efficacy increased when carrier volume was reduced. S. bakeri injury increased with sethoxydim rate reaching a maximum of 45% by 42 DAT. However, no differences in S. bakeri injury among carrier volumes were observed at 14 and 28 DAT evaluations. S. bakeri aboveground biomass reductions were also largely driven by sethoxydim rate increases rather than reduced carrier volumes reaching 40 to 50% reduction in initial aboveground biomass. However, S. bakeri belowground biomass was 20 to 32% greater in treatments applied at 37 or 187 L ha-1 compared to those at 935 L ha-1. Overall, these data suggest that selective P. repens control with sethoxydim may be enhanced through reducing carrier volumes from 935 L ha-1 and that native, perennial, caespitose grasses may exhibit greater tolerance to sethoxydim compared to the rhizomatous P. repens. Future research should further test these hypotheses under field conditions at operational scales.

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“…Limitations of high carrier volumes (e.g., 935 L ha −1 ) include reduced spray retention at low floating plant densities, thus resulting in spray loss to the water column (Mudge et al 2021), and reduced herbicide concentration per spray droplet (Knoche 1994). In general, herbicide applications made with lower carrier volumes are preferred because of time savings when filling spray tanks (Nelson et al 2007), public perception (Sperry and Ferrell 2021), increased spray retention on plant targets (Sperry et al 2022), and the increased performance of some herbicides on floating plant species (Nelson et al 2007; Sperry and Ferrell 2021; Van et al 1986). In a mesocosm study, Sartain and Mudge (2018a) evaluated winter herbicide applications on S. molesta and T. distichum using a carrier volume representative of an aerial application (94 L ha −1 ).…”

Section: Introductionmentioning

confidence: 99%

“…While this foliar application strategy has been successful with numerous herbicides and plant targets (Sperry and Ferrell 2021), there are associated hindrances that make “high” spray-volume applications undesirable for current management tactics. Research has established carrier volume directly affects spray deposition, herbicide activity, and ultimately aquatic plant control (Moreira et al 1999; Nelson et al 2007; Sperry and Ferrell 2021; Sperry et al 2022; Van et al 1986; Willard et al 1998). Limitations of high carrier volumes (e.g., 935 L ha– 1 ) include reduced spray retention at low floating plant densities, thus resulting in spray loss to the water column (Mudge et al 2021), and reduced herbicide concentration per spray droplet (Knoche 1994).…”

Section: Introductionmentioning

confidence: 99%

Low carrier volume herbicide trials and UAAS support management efforts of giant salvinia (Salvinia molesta): a case study

Howell

Haug

Everman

et al. 2023

Invasive plant sci. manag.

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Expanding the current aquatic herbicide portfolio, reducing total spray volumes, or remotely delivering herbicide using novel spray technologies could improve management opportunities targeting invasive aquatic plants, where options are more limited. However, research on giant salvinia [Salvinia molesta (D. S. Mitchell)] response to foliar herbicide applications at carrier volumes ≤ 140 L ha-1 is incomplete. Likewise, no data exists documenting S. molesta control with unoccupied aerial application systems (UAAS). Following the recent >100 ha incursion of S. molesta in Gapway Swamp, North Carolina, a case study was developed to provide guidance for ongoing management efforts. In total, three field trials evaluated registered aquatic and experimental herbicides using a 140 L ha-1 carrier volume. Select foliar applications from UAAS were also evaluated. Results at 8 weeks after treatment (8 WAT) indicated the experimental protoporphyrinogen oxidase inhibitor, PPO-699-01 (424 g a.i. ha-1), in combination with endothall dipotassium salt (2370 g a.e. ha-1) provided 78% visual control, whereas control when PPO-699-01 (212 g a.i. ha-1) was applied alone was lower at 35%. Evaluations also showed diquat (3136 g a.i. ha-1) alone, glyphosate (4539 g a.e. ha-1) alone, and metsulfuron-methyl (42 g a.i. ha-1) alone achieved 86 to 94% visual plant control at 8 WAT. Sequential foliar applications of diquat, flumioxazin (210 g a.i. ha-1), and carfentrazone (67 g a.i. ha-1) 6 wk following exposure to in-water fluridone treatments were no longer efficacious by 6 WAT due to plant regrowth. Carfentrazone applications made from a backpack sprayer displayed greater control than applications made with UAAS at 2 WAT deploying identical carrier volumes; however, neither application method provided effective control at 8 WAT. Additional field validation is needed to further guide management direction of S. molesta control using low carrier volume foliar applications.

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Simulated herbicide spray retention on floating aquatic plants as affected by carrier volume and adjuvant type

Cited by 5 publications

References 47 publications

Simulated herbicide spray retention of commonly managed invasive emergent aquatic macrophytes

Simulated herbicide spray retention of commonly managed invasive emergent aquatic macrophytes

Sethoxydim performance on torpedograss (Panicum repens) and sand cordgrass (Spartina bakeri) as affected by carrier volume and rate

Low carrier volume herbicide trials and UAAS support management efforts of giant salvinia (Salvinia molesta): a case study

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