Degradation of metaflumizone in soil: Impact of varying moisture, light, temperature, atmospheric CO2 level, soil type and soil sterilization

Soil is a major sink for the bulk of globally used pesticides. Hence, fate of pesticides in soil under the influence of various biotic and abiotic factors becomes important for evaluation of stability and safety. This paper presents the impact of varying moisture, light, temperature, atmospheric CO2 level, soil type and soil sterilization on degradation of metaflumizone, a newly registered insecticide in India. Degradation of metaflumizone in soil followed the first order reaction kinetics and its half life values varied from similar to 20 to 150 d. Under anaerobic condition, degradation of metaflumizone was faster (t(1/2) 33.4 d) compared to aerobic condition (t(1/2) 50.1 d) and dry soil (t(1/2) 150.4 d). Under different light exposures, degradation was the fastest under UV light (t(1/2) 27.3 d) followed by Xenon light (t(1/2) 43 d) and dark condition (t(1/2) 50.1 d). Degradation rate of metaflumizone increased with temperature and its half life values ranged from 30.1 to 100.3 d. Elevated atmospheric CO2 level increased the degradation in soil (t(1/2) 20.1-50.1 d). However, overall degradation rate was the fastest at 550 ppm atmospheric CO2 level, followed by 750 ppm and ambient level (375 ppm). Degradation of metaflumizone was faster in Oxisol (pH 5.2, Total Organic Carbon 1.2%) compared to Inceptisol (pH 8.15, TOC 0.36%). In sterile soil, only 5% dissipation of initial concentration was observed after 90 d of sampling. Under various conditions, 4-cyanobenzoic acid (0.22-1.86 mg kg(-1)) and 4-trifluoromethoxy aniline (0.21-1.23 mg kg(-1)) were detected as major degradation products. (C) 2012 Elsevier Ltd. All rights reserved.