Evaluation of sulfuryl fluoride as a soil fumigant in China

文献类型: 外文期刊

第一作者: Guo, Meixia

作者: Guo, Meixia;Yan, Dongdong;Mao, Liangang;Wang, Qiuxia;Li, Yuan;Duan, Xiayu;Cao, Aocheng;Guo, Meixia;Wang, Qiuxia;Li, Yuan;Duan, Xiayu;Wang, Peisheng

作者机构:

关键词: sulfuryl fluoride;methyl bromide;alternatives;soil disinfestation;Meloidogyne;Fusarium

期刊名称:PEST MANAGEMENT SCIENCE ( 影响因子:4.845; 五年影响因子:4.674 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: BACKGROUND: Root-knot nematodes and soil-borne diseases constrain the rapid development of protected agriculture in China, especially while phasing out methyl bromide (MB). The fumigant sulf uryl fluoride (SF) is currently used as an alternative to MB for the disinfestation of buildings and post-harvest commodities. Our experiments aimed to evaluate a novel application of SF as a soil fumigant in greenhouses in China. RESULTS: Dose-response experiments indicated that SF has good efficacy on root-knot nematodes {Meloidogyne spp.) and moderate activity against Fusarium spp. and weeds (Digitaria sanguinalis (L.) Scop, and Abutilon theophrasti Medicus). The field trials indicates that SF has good efficacy, between 80 and 94%, on Meloidogyne spp., and Fusarium spp. at the rates of 25-50 g m~(-2) in tomato and cucumber in Beijing and Shandong Province. Marketable yield and plant vigour was not significantly different in SF and MB treatments. SF has lower emissions than MB during the fumigation operation. It is simple to apply, can be used at low temperature, and has a short plant-back time. SF was found to be an economically feasible alternative to MB for nematode control in China. CONCLUSION: SF can be used as a soil fumigant to control root-knot nematodes and to reduce the levels of key soil pathogens.

分类号: S4

  • 相关文献

[1]Nitrification dynamics in a soil after addition of different fumigants. Wang, Qiuxia,Mao, Liangang,Ma, Taotao,Li, Yuan,Guo, Meixia,Cao, Aocheng. 2013

[2]Isolation of Antagonistic Endophytes from Banana Roots against Meloidogyne javanica and Their Effects on Soil Nematode Community. Su, Lanxi,Shen, Zongzhuan,Tao, Chengyuan,Chao, Yifan,Li, Rong,Shen, Qirong,Su, Lanxi,Ruan, Yunze. 2017

[3]Identification of a candidate gene for resistance to root-knot nematode in a wild peach and screening of its polymorphisms. Cao, Ke,Wang, Lirong,Zhao, Pei,Zhu, Gengrui,Fang, Weichao,Chen, Changwen,Wang, Xinwei.

[4]Nematicidal Effects of 5-Aminolevulinic Acid on Plant-Parasitic Nematodes. Song, Zhiqiang,Cheng, Ju'e,Zhang, Deyong,Liu, Yong,Cheng, Feixue,Song, Zhiqiang,Cheng, Ju'e,Zhang, Deyong,Liu, Yong,Wang, Jian. 2017

[5]Effects of 1,3-dichloropropene as a methyl bromide alternative for management of nematode, soil-borne disease, and weed in ginger (Zingiber officinale) crops in China. Qiao, Kang,Zhu, Yukun,Wang, Kaiyun,Wang, Hongyan,Ji, Xiaoxue. 2012

[6]Evaluation of 1,3-Dichloropropene as a Methyl Bromide Alternative in Tomato Crops in China. Qiao, Kang,Jiang, Lili,Wang, Kaiyun,Wang, Hongyan,Ji, Xiaoxue.

[7]Efficacy of soil fumigation with dazomet for controlling ginger bacterial wilt (Ralstonia solanacearum) in China. Jiang, Hongyun,Wang, Qiuxia,Yan, Dongdong,Cao, Aocheng.

[8]Quantification of Fusarium oxysporum in fumigated soils by a newly developed real-time PCR assay to assess the efficacy of fumigants for Fusarium wilt disease in strawberry plants. Li, Yuan,Mao, Liangang,Yan, Dongdong,Ma, Taotao,Shen, Jin,Guo, Meixia,Wang, Qiuxia,Ouyang, Canbin,Cao, Aocheng.

[9]Construction of Streptomyces lydicus A01 transformant with the chit33 gene from Trichoderma harzianum CECT2413 and its biocontrol effect on Fusaria. Wu Qiong,Li YingYing,Li YaQian,Lin ZhenYa,Wang Meng,Chen Jie,Bai LinQuan,Liu WeiCheng,Lu CaiGe,Xue ChunSheng. 2013

[10]Management factors affecting size and structure of soil Fusarium communities under irrigated maize in Australia. Wakelin, Steven A.,Warren, Rosemary A.,Harvey, Paul R.,Kong, Lingxiao. 2008

[11]Identification and Genetic Division of Fusarium graminearum and Fusarium asiaticum by Species-Specific SCAR Markers. Zhang, Xu,Ma, Hong-xiang,Zhou, Yong-jin,Xing, Jin-cheng,Chen, Jian-hua,Yu, Gui-hong,Sun, Xiao-bo,Wang, Lei,Zhou, Yong-jin. 2014

[12]Rapid detection and quantification of zearalenone-producing Fusarium species by targeting the zearalenone synthase gene PKS4. Meng, Kun,Wang, Yaru,Yang, Peilong,Luo, Huiying,Bai, Yingguo,Shi, Pengjun,Yuan, Tiezheng,Ma, Rui,Yao, Bin. 2010

[13]Effect of Jasmonic Acid to Resistance against Fusarium in Lily. Zhang, Y. P.,Cui, G. F.,Wu, L. F.,Wang, J. H.,Tang, D. S.,Lee, I. J.. 2011

[14]Sequencing and characterization of mitochondrial genome of Fusarium sp (Hypocreales: Nectriaceae). Lu, Daihua,Chen, Cheng,Bi, Guiqi. 2017

[15]Screening and monitoring zearalenone-producing Fusarium species by PCR and zearalenone by monoclonal antibodies in feed from China. Pei, Shi-Chun,Zhang, Hong-Fu,Ji, Cheng,Pei, Shi-Chun,Zhen, Yu-Ping,Gao, Jian-Wei,Lee, Won-Jong,Chen, Cong,Zhang, Xuan-Zhe.

[16]Artificial Inoculation Method of Pokkah Boeng Disease of Sugarcane and Screening of Resistant Germplasm Resources in Subtropical China. Sun, Hai-Jun,Guo, Qiang,Xu, Shi-Qiang,Wang, Ji-Hua,Zhang, Mu-Qing,Wang, Ze-Ping,Lin, Shan-Hai,Zhang, Mu-Qing,Wang, Ze-Ping,Lin, Shan-Hai,Zhang, Mu-Qing. 2017

[17]Effects of feeding a Fusarium toxin-contaminated diet to infectious bursal disease virus-infected broilers on the protein turnover of the bursa of Fabricius and spleen. Daenicke, Sven,Pappritz, Julia,Goyarts, Tanja,Xu, Bu,Rautenschlein, Silke. 2011

[18]Screening survey of co-production of fusaric acid, fusarin C, and fumonisins B-1, B-2 and B-3 by Fusarium strains grown in maize grains. Han, Z.,Wu, A.,Tangni, E. K.,Huybrechts, B.,Callebaut, A.,Munaut, F.,Scauflaire, J.. 2014

[19]Biogeography of Fusarium graminearum species complex and chemotypes: a review. Waalwijk, Cees,Zhang, Hao,van Diepeningen, Anne.

[20]Complete mitogenome of the high ethanol production fungus Fusarium oxysporum Mh2-2. Zeng, Lu,Kang, Xincong,Xiong, Xingyao,Liu, Chichuan,Lin, Runmao,Xie, Bingyan,Xiong, Xingyao,Lin, Runmao. 2017

作者其他论文 更多>>

微信小程序