Peach Tree Response to Low-Dosages of Dicamba as Repeated Applications or with Various Spray Nozzles

IF 1.3 3区农林科学 Q3 AGRONOMY

Weed Technology Pub Date : 2023-11-29 DOI:10.1017/wet.2023.80

Matthew B. Bertucci, Thomas R. Butts, Koffi Badou-Jeremie Kouame, Jason K. Norsworthy

{"title":"Peach Tree Response to Low-Dosages of Dicamba as Repeated Applications or with Various Spray Nozzles","authors":"Matthew B. Bertucci, Thomas R. Butts, Koffi Badou-Jeremie Kouame, Jason K. Norsworthy","doi":"10.1017/wet.2023.80","DOIUrl":null,"url":null,"abstract":"Two low-dose dicamba exposure trials were conducted on container-grown peach trees in Fayetteville, AR. Peach trees were ‘July Prince’ scions grafted onto ‘Guardian’ rootstock and were transplanted into 19 L containers and received experimental dicamba treatments in each year. Container trials were initiated in 2020 and repeated on new trees in 2021. In the repeated application trial, dicamba was applied at 5.6 g ae ha-1 (1/100× field rate) in five sequences: an untreated control receiving no herbicide, one treatment receiving only initial application, and three treatments receiving initial application plus sequential applications at the same rate occurring 14 d, 28 d, 14 d + 28 d after initial treatment (DAT). A separate trial assessed peach tree responses to dicamba applied at 11.2 g ae ha-1 (1/50× field rate) using a selection of nozzles with differing droplet spectrum characteristics: Turbo TeeJet® Induction (TTI11002), Air Induction Turbo TeeJet® (AITTJ60-11002), AIXR TeeJet® (AIXR11002, air induction extended range), XR TeeJet® (XR11002, extended range flat fan), and XR TeeJet® (XR1100067, extended range flat fan). Peach tree height, tree cross sectional area (TCSA) and leaf chlorophyll content were not reduced in response to any sequence of dicamba application or nozzle selection. Repeated applications of dicamba at 1/100× rate did not increase peach injury after 28 DAT. By 84 DAT, no effect of nozzle type on peach tree injury was discernable, and all treatments caused below 4% injury. No dicamba or dicamba metabolites were observed in leaf samples collected at 14, 69, or 85 DAT from trees treated with XR1100067 nor in untreated controls. While peach tree injury was observed throughout the experiment, dicamba residues were only detected consistently in 2020 from leaf samples of trees treated with dicamba at 1/50× rate using TTI1102, AITTJ60-11002, AIXR11002, and XR11002 nozzles.","PeriodicalId":23710,"journal":{"name":"Weed Technology","volume":"11 1","pages":""},"PeriodicalIF":1.3000,"publicationDate":"2023-11-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Weed Technology","FirstCategoryId":"97","ListUrlMain":"https://doi.org/10.1017/wet.2023.80","RegionNum":3,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"AGRONOMY","Score":null,"Total":0}

引用次数: 0

Abstract

Two low-dose dicamba exposure trials were conducted on container-grown peach trees in Fayetteville, AR. Peach trees were ‘July Prince’ scions grafted onto ‘Guardian’ rootstock and were transplanted into 19 L containers and received experimental dicamba treatments in each year. Container trials were initiated in 2020 and repeated on new trees in 2021. In the repeated application trial, dicamba was applied at 5.6 g ae ha-1 (1/100× field rate) in five sequences: an untreated control receiving no herbicide, one treatment receiving only initial application, and three treatments receiving initial application plus sequential applications at the same rate occurring 14 d, 28 d, 14 d + 28 d after initial treatment (DAT). A separate trial assessed peach tree responses to dicamba applied at 11.2 g ae ha-1 (1/50× field rate) using a selection of nozzles with differing droplet spectrum characteristics: Turbo TeeJet® Induction (TTI11002), Air Induction Turbo TeeJet® (AITTJ60-11002), AIXR TeeJet® (AIXR11002, air induction extended range), XR TeeJet® (XR11002, extended range flat fan), and XR TeeJet® (XR1100067, extended range flat fan). Peach tree height, tree cross sectional area (TCSA) and leaf chlorophyll content were not reduced in response to any sequence of dicamba application or nozzle selection. Repeated applications of dicamba at 1/100× rate did not increase peach injury after 28 DAT. By 84 DAT, no effect of nozzle type on peach tree injury was discernable, and all treatments caused below 4% injury. No dicamba or dicamba metabolites were observed in leaf samples collected at 14, 69, or 85 DAT from trees treated with XR1100067 nor in untreated controls. While peach tree injury was observed throughout the experiment, dicamba residues were only detected consistently in 2020 from leaf samples of trees treated with dicamba at 1/50× rate using TTI1102, AITTJ60-11002, AIXR11002, and XR11002 nozzles.

查看原文本刊更多论文

重复施用低剂量麦草畏或不同喷雾方式对桃树的影响

在AR州费耶特维尔的容器栽培桃树上进行了两项低剂量麦草畏暴露试验。桃树是“七月王子”接穗嫁接到“守护者”砧木上，移植到19升的容器中，每年接受麦草畏试验处理。容器试验于2020年启动，并于2021年在新树上重复。在重复施用试验中，麦草畏按5.6 g / hm -1(1/100倍田间施用量)分5个顺序施用:未处理对照不施用除草剂，1个处理只施用初施，3个处理在初施后14 d、28 d、14 d + 28 d以相同的施用量连续施用(DAT)。另一项试验评估了桃树对11.2 g / ha-1(1/50倍场率)麦草畏的反应，使用具有不同液滴光谱特征的喷嘴:Turbo TeeJet®感应(TTI11002)、Air Induction Turbo TeeJet®(AITTJ60-11002)、AIXR TeeJet®(AIXR11002，空气感应扩展范围)、XR TeeJet®(XR11002，扩展范围平风扇)和XR TeeJet®(XR1100067，扩展范围平风扇)。不同施用麦草畏和喷嘴的桃树高、树横截面积(TCSA)和叶片叶绿素含量均不受不同施用顺序的影响。以1/100倍剂量重复施用麦草畏对28天后的桃损伤无显著影响。84个DAT时，喷管类型对桃树伤害无明显影响，所有处理的伤害均在4%以下。在XR1100067处理的树木和未处理的对照中，在14、69或85 DAT采集的叶片样本中未观察到麦草畏或麦草畏代谢物。虽然整个试验过程中都观察到桃树的伤害，但在2020年，使用TTI1102、AITTJ60-11002、AIXR11002和XR11002喷嘴以1/50的比例处理的树木叶片样品中，麦草畏残留的检测结果一致。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Weed Technology 农林科学-农艺学

CiteScore

2.90

自引率

21.40%

发文量

审稿时长

12-24 weeks

期刊介绍： Weed Technology publishes original research and scholarship in the form of peer-reviewed articles focused on understanding how weeds are managed. The journal focuses on: - Applied aspects concerning the management of weeds in agricultural systems - Herbicides used to manage undesired vegetation, weed biology and control - Weed/crop management systems - Reports of new weed problems -New technologies for weed management and special articles emphasizing technology transfer to improve weed control -Articles dealing with plant growth regulators and management of undesired plant growth may also be accepted, provided there is clear relevance to weed science technology, e.g., turfgrass or woody plant management along rights-of-way, vegetation management in forest, aquatic, or other non-crop situations. -Surveys, education, and extension topics related to weeds will also be considered