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http://dx.doi.org/10.3839/jabc.2020.037

Identification of reduced plant uptake and reduction effects of azoxystrobin, procymidone and tricyclazole by biochars and quicklime  

Lee, Hyo-Sub (Chemical Safety Division, Agro-Food and Crop Protection Department, NAS)
Hwang, In-Seong (Residue Research Department, Hanearl Science)
Park, Sang-Won (Chemical Safety Division, Agro-Food and Crop Protection Department, NAS)
Choi, Geun-Hyoung (Chemical Safety Division, Agro-Food and Crop Protection Department, NAS)
Ryu, Song-Hee (Chemical Safety Division, Agro-Food and Crop Protection Department, NAS)
Publication Information
Journal of Applied Biological Chemistry / v.63, no.3, 2020 , pp. 275-282 More about this Journal
Abstract
As pesticide safety was extended to agricultural environments and Positive List System was carried out, Pesticide safety management in soils has become even more important. To improve pesticide safety in soils needs the degradation technology of the residues in soils and reduce plant uptake of pesticides. In this study, biochars and quicklime as the degradation methods of pesticides (azoxystrboin, procymidone and tricyclazole) were used to identify the reduction effects. The experimental methods were putting biochars and quicklimes (0, 0.5, 1.0, 2.0% per 15 cm soil weight) in soils and analyzing the pesticide residues at 0, 10, 20, 35, 50 day. To identify the reduction effects of uptake from soil to korean cabbages (roots, leave, stems) by biochar treatment, the residues in samples were analyzed. As a results, azoxystrobin (36-96%), procymidone (40-117%) and tricyclazole (26-83%) were reduced in soils when treated with 2.0% quicklime (p<0.05). There were no reduction effect in soils when treated with 1.0% or less biochar. However, the amounts of residues translocated to roots (0.11-1.62 mg/kg), leave (0.05-0.29 mg/kg), stems (0.06-0.1 mg/kg) were reduced treated with 2.0% biochar treatments. The biochar and quicklime can be applicable to agricultural field to improve pesticide safety in soils.
Keywords
Biochar; Pesticides; Quicklime; Reduction effects; Uptake;
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1 Qiu Y, Pang H, Zhou Z, Zhang P, Feng Y, Sheng DG (2009) Competitive biodegradation of dichlobenil and atrazine coexisting in soil amended with a char and citrate. Environ Pollut 157 (11): 2964-2969   DOI
2 Lopez-Pineiro A, Pena D, Albarran A, Sanchez-Llerena J,Becerra D (2013) Behavior of MCPA in four intensive croppingsoils amended with fresh, composted, and aged olive mill waste. J Contam Hydrol 152: 137-146   DOI
3 Leng L,Huang H, Li H, Li J, Zhou W (2019) Biochar stability assessment methods: a review. Science of the total environment 647: 210-222   DOI
4 Noh HO, Lee JY, Park SH, Jeong OS, Kim SH, Kyung KS (2012) Monitoring of pesticide residues in rice paddy soil and paddy water. Korean J Pestic Sci 16(2): 137-144   DOI
5 Marin-Benito JM, Brown CD, Herrero-Hernandez E, Arienzo M, Sanchez-Martin MJ Rodriguez-Cruz MS (2013) Use of raw or incubated organic wastes as amendments in reducing pesticide leaching through soil columns. Science of the Total Environment 463-464: 589-599   DOI
6 Lee HS, Hong SM, Kim TK, Kwon HY, Kim DB, Moon BC, Moon JK (2016) Reduction Effects of Residual Pesticides using the Eco-Friendly Soil Amendments in Agricultural Soil. Korean J Pestic Sci 16(2): 137-144   DOI
7 Kim JY, Kim HN, Saravanan M, Heo SJ, Jeong HN, Lim JE, Kim KR, Hur JH (2014) Translocation of tolclofos-methyl from ginseng cultivated soil to ginseng (Panax ginseng C A Meyer) and residue analysis of various pesticides in ginseng and soil. Korean J Pestic Sci 18(3): 130-140   DOI
8 Jeon SO, Hwang JI, Lee SH, Kim JE (2014) Uptake of boscalid and chlorfenapyr residues in soil into Korean cabbage. Korean J Pestic Sci 18(4): 314-320   DOI
9 Hwang JI, Jeon SO, Lee SH, Lee SE, Hur JH, Kim KR, Kim JE (2014) Distribution patterns of organophosphorous insecticide chlorpyrifos absorbed from soil into cucumber. Korean J Pestic Sci 18(3): 148-155   DOI
10 Park BJ, Kim CS, Park KH, Park HJ, Im GJ, Choi JH, Shim JH, Rye GH (2006) Distribution and Mobility of Herbicide 14C-Molinate in a Rice-Paddy-Soil Lysimeter. Korean J Pestic Sci 10(3): 172-182
11 Blackwell P, Krull E, Butler G, Herbert A, Solaiman Z (2010) Effect of banded biochar on dryland wheat production and fertilizer use in southwestern Australia: an agronomic and economic perspective. Aust J Soil Res 48 (7): 531-545   DOI
12 Tang J, Zhu W, Kookana R, Katayama A (2013) Characteristics of biochar and its application in remediation of contaminated soi.l J Biosci Bioeng 116 (6): 653-659   DOI
13 Shaheen SM, Niazi NK, Hassan NE, Bibi I, Wang H, Tsang DC, Ok YS, Bolan N, Rinklebe J (2019) Woodbased biochar for the removal of potentially toxic elements in water and wastewater: a critical review. International Materials Reviews 64(4): 216-247   DOI
14 Kim MG, Hwang KW, Hwang EJ, Yoo SC, Moon JK (2017) Translocation of Residual Azoxystrobin from Soil to Korean Cabbage. Korean J Pestic Sci 21(4): 427-433   DOI
15 Yu XY, Ying GG, Kookana RS (2009) Reduced plant uptake of pesticides with biochar additions to soil. Chemosphere 76: 665-671   DOI
16 Chu WK, Wong MH, Zhang J (2006) Accumulation, distribution and transformation of DDT and PCBs by Phragmites australis and Oryza sativa L: I Whole plant study Environ Geochem Health 28: 159-168   DOI
17 Whitfield AML, Zeeb BA, Rutter A, Reimer KJ (2007) In situ phytoextraction of polychlorinated biphenyls residues in vegetables, grain and soil from organic and conventional farming in Poland. J Environ Sci health B 47: 343-353
18 Kim SM, Jo IG, Gyeon GS, Lee JK (2003) Influence of soil organic matter and moisture on the persistence of the herbicide mefenacet in soils. Korean J Pestic Sci 7(3): 182-187
19 Khorram MS, Zhang Q, Lin D, Zheng Y, Fang H, Yu Y (2016) Biochar: A review of its impact on pesticide behavior in soil environments and its potential applications. J Environ Sci 44: 269-279   DOI
20 Park BJ, Lee BM, Kim CS, Park KH, Park SW, Kwon HY, Kim JH, Choi GH, Lim SJ (2013) Long-term Monitoring of Pesticides Residues in Arable Soils in Korea. Korean J Pestic Sci 17(4): 283-292   DOI
21 Dechene A, Rosendahl I, Laabs V, Amelung W (2014) Sorption of polar herbicides and herbicide metabolites by biocharamended soil. Chemosphere 109: 180-186   DOI
22 Ahmad M, Rajapaksha AU, Lim JE, Zhang M, Bolan N, Mohan D (2014) Biochar as a sorbent for contaminant management in soil and water: A review. Chemosphere 99: 19-33   DOI
23 Jones DL, Edwards-Jones G, Murphy DV (2011) Biochar mediated alterations in herbicide breakdown and leaching in soil. Soil Biol Biochem 43 (4): 804-813   DOI
24 Cabrera A, Cox L, Spokas L, Hermosin MC, Cornejo J, Koskinen WC (2014) Influence of biochar amendments on the sorption-desorption of aminocyclopyrachlor, bentazone and pyraclostrobin pesticides to an agricultural soi.l Sci Total Environ 470-471: 438-443   DOI
25 Chun BS, Ko KS (1998) Improvement effect of marine clay in yul-chon by quick Lime pile. J Korean Soci Civil Engin 18(2-4): 521-529
26 Kim YH, Chu BS (2010) Improvement effects of soft clay soils using quick lime piles. J the Korean Geoenviron Society 11(5): 45-51
27 Jung KH, Seo IW, Nam HJ, Shin HS (2008) Effects of Ozonated Water Treatment on Pesticide Residues and Catechin Content in Green Tea Leaves. Korean J Food Sci Technol 40(3): 265-270
28 Yan M, Binbin D, Xiaosong H, Yi S, Mingyue X, Xuwen H, Xiaoming D, Fasheng L (2017) Quicklime-induced chages of soil properties: Implications for enganced remedation of volatile chlorinated hydrocarbon contaminated soils via mechanical soil aeration. Chemosphere 173: 435-443   DOI
29 Zhang P, Sheng G, Feng Y, Miller DM (2006) Predominance ofchar sorption over substrate concentration and soil pH in influencing biodegradation of benzonitrile. Biodegradation 17 (1): 1-8   DOI