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Persistence and degradation of herbicide molinate in paddy-soil environment  

Park, Byung-Jun (National Institute of Agricultural Science & Technology, RDA)
Park, Hyeon-Ju (National Institute of Agricultural Science & Technology, RDA)
Lee, Byung-Moo (National Institute of Agricultural Science & Technology, RDA)
Ihm, Yang-Bin (National Institute of Agricultural Science & Technology, RDA)
Choi, Ju-Hyeon (National Institute of Agricultural Science & Technology, RDA)
Ryu, Gab-Hee (National Institute of Agricultural Science & Technology, RDA)
Publication Information
The Korean Journal of Pesticide Science / v.9, no.1, 2005 , pp. 60-69 More about this Journal
Abstract
The herbicide molinate has been detected with high frequency in the main river during the growing season in Korea. To elucidate the exposure of molinate in agricultural environment, the persistence and the degradation characteristics of molinate were investigated in paddy ecosystems. The half-lives of molinate were 4.1 days with soil aquatic system, and 4.2 days in only aquatic system. Initial dissipation rate of molinate in water was greater with soil aquatic system than that of only aquatic system. Photolysis of molinate was occurred about 31.0% of molinate treated in pure water, when irradiated at 5,530 $J/cm^2$ by the xenon lamp, but its hydrolysis was stable. For the accelerated photolysis of molinate in aqueous solution, several photosensitizers were screened, showing that the hydroperoxide($H_2O_2$) and acetone were prominent among the chemical tested. When hydroperoxide and zinkoxide(ZnO) were used as photosensitizer, their photolysis were accelerated greater than 98% and 58% in aqueous solution, respectively. Elution rate of molinate as granular formulations in aqueous system was more than 90% in 30 hour at $35^{\circ}C$. Molinate concentration pattern in paddy water was rapidly decrease from treatment till 7 days in paddy rice field and its half-lives were 3.7 days($Y=1.9258{\times}e^{-0.1865X}$(r=-0.9402)).
Keywords
persistence; degradation; molinate; paddy ecosystem;
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