Quantifying soil surface photolysis under conditions simulating water movement in the field: a new laboratory test design

Soil surface photolysis can be a significant dissipation pathway for agrochemicals under field conditions, although it is assumed that such degradation ceases once the agrochemical is transported away from the surface following rainfall or irrigation and subsequent drainage of soil porewater. Howeve...

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Veröffentlicht in:	Environmental toxicology and chemistry 2015-10, Vol.34 (10), p.2236-2243
Hauptverfasser:	Hand, Laurence H., Nichols, Carol, Kuet, Sui F., Oliver, Robin G., Harbourt, Christopher M., El-Naggar, Essam M.
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Sprache:	eng
Schlagworte:	Abiotic transformation Agricultural chemicals Agrochemicals Bridged Bicyclo Compounds, Heterocyclic - analysis Carbon Radioisotopes - chemistry Chromatography, High Pressure Liquid Cores Degradation Dissipation Drainage Environmental fate Evaporation Herbicides - analysis Irrigation Laboratories Laboratory tests Light Moisture Pesticide Photolysis Photolysis - radiation effects Pore water Pyrones - analysis Pyrones - chemistry Radioactivity Rainfall Simulated rainfall Simulation Soil Soil (material) Soil - chemistry Soil Pollutants - analysis Soil Pollutants - chemistry Soil surfaces Soils Ultraviolet radiation Water Movements Xenon
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creator	Hand, Laurence H. Nichols, Carol Kuet, Sui F. Oliver, Robin G. Harbourt, Christopher M. El-Naggar, Essam M.
description	Soil surface photolysis can be a significant dissipation pathway for agrochemicals under field conditions, although it is assumed that such degradation ceases once the agrochemical is transported away from the surface following rainfall or irrigation and subsequent drainage of soil porewater. However, as both downward and upward water movements occur under field conditions, relatively mobile compounds may return to the surface, prolonging exposure to ultraviolet light and increasing the potential for degradation by photolysis. To test this hypothesis, a novel experimental system was used to quantify the contribution of photolysis to the overall dissipation of a new herbicide, bicyclopyrone, under conditions that mimicked field studies more closely than the standard laboratory test guidance. Soil cores were taken from 3 US field study sites, and the surfaces were treated with [14C]‐bicyclopyrone. The radioactivity was redistributed throughout the cores using a simulated rainfall event, following which the cores were incubated under a xenon‐arc lamp with continuous provision of moisture from below and a wind simulator to induce evaporation. After only 2 d, most of the test compound had returned to the soil surface. Significantly more degradation was observed in the irradiated samples than in a parallel dark control sample. Degradation rates were very similar to those observed in both the thin layer photolysis study and the field dissipation studies and significantly faster than in the soil metabolism studies conducted in the dark. Thus, for highly soluble, mobile agrochemicals, such as bicyclopyrone, photolysis is not terminated permanently by rainfall or irrigation but can resume following transport to the surface in evaporating water. Environ Toxicol Chem 2015;34:2236–2243. © 2015 SETAC
doi_str_mv	10.1002/etc.3074
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However, as both downward and upward water movements occur under field conditions, relatively mobile compounds may return to the surface, prolonging exposure to ultraviolet light and increasing the potential for degradation by photolysis. To test this hypothesis, a novel experimental system was used to quantify the contribution of photolysis to the overall dissipation of a new herbicide, bicyclopyrone, under conditions that mimicked field studies more closely than the standard laboratory test guidance. Soil cores were taken from 3 US field study sites, and the surfaces were treated with [14C]‐bicyclopyrone. The radioactivity was redistributed throughout the cores using a simulated rainfall event, following which the cores were incubated under a xenon‐arc lamp with continuous provision of moisture from below and a wind simulator to induce evaporation. After only 2 d, most of the test compound had returned to the soil surface. Significantly more degradation was observed in the irradiated samples than in a parallel dark control sample. Degradation rates were very similar to those observed in both the thin layer photolysis study and the field dissipation studies and significantly faster than in the soil metabolism studies conducted in the dark. Thus, for highly soluble, mobile agrochemicals, such as bicyclopyrone, photolysis is not terminated permanently by rainfall or irrigation but can resume following transport to the surface in evaporating water. 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However, as both downward and upward water movements occur under field conditions, relatively mobile compounds may return to the surface, prolonging exposure to ultraviolet light and increasing the potential for degradation by photolysis. To test this hypothesis, a novel experimental system was used to quantify the contribution of photolysis to the overall dissipation of a new herbicide, bicyclopyrone, under conditions that mimicked field studies more closely than the standard laboratory test guidance. Soil cores were taken from 3 US field study sites, and the surfaces were treated with [14C]‐bicyclopyrone. The radioactivity was redistributed throughout the cores using a simulated rainfall event, following which the cores were incubated under a xenon‐arc lamp with continuous provision of moisture from below and a wind simulator to induce evaporation. After only 2 d, most of the test compound had returned to the soil surface. Significantly more degradation was observed in the irradiated samples than in a parallel dark control sample. Degradation rates were very similar to those observed in both the thin layer photolysis study and the field dissipation studies and significantly faster than in the soil metabolism studies conducted in the dark. Thus, for highly soluble, mobile agrochemicals, such as bicyclopyrone, photolysis is not terminated permanently by rainfall or irrigation but can resume following transport to the surface in evaporating water. Environ Toxicol Chem 2015;34:2236–2243. © 2015 SETAC</description><subject>Abiotic transformation</subject><subject>Agricultural chemicals</subject><subject>Agrochemicals</subject><subject>Bridged Bicyclo Compounds, Heterocyclic - analysis</subject><subject>Carbon Radioisotopes - chemistry</subject><subject>Chromatography, High Pressure Liquid</subject><subject>Cores</subject><subject>Degradation</subject><subject>Dissipation</subject><subject>Drainage</subject><subject>Environmental fate</subject><subject>Evaporation</subject><subject>Herbicides - analysis</subject><subject>Irrigation</subject><subject>Laboratories</subject><subject>Laboratory tests</subject><subject>Light</subject><subject>Moisture</subject><subject>Pesticide</subject><subject>Photolysis</subject><subject>Photolysis - radiation effects</subject><subject>Pore water</subject><subject>Pyrones - analysis</subject><subject>Pyrones - chemistry</subject><subject>Radioactivity</subject><subject>Rainfall</subject><subject>Simulated rainfall</subject><subject>Simulation</subject><subject>Soil</subject><subject>Soil (material)</subject><subject>Soil - chemistry</subject><subject>Soil Pollutants - analysis</subject><subject>Soil Pollutants - chemistry</subject><subject>Soil surfaces</subject><subject>Soils</subject><subject>Ultraviolet radiation</subject><subject>Water Movements</subject><subject>Xenon</subject><issn>0730-7268</issn><issn>1552-8618</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqN0U9rFDEYBvAgil2r4CeQgBcvU_Nnk8x4k6JboVQLVY8hk3mnTc0ka5JxnW9vlq4VBEFyCCG_PEl4EHpOyQklhL2GYk84UesHaEWFYE0rafsQrYjipFFMtkfoSc63hFDZdd1jdMQkoUQpuULL5WxCcePiwjXO0Xmc5zQaC3h7E0v0S3YZz2GAhG0Mgysuhoyzm2Zvyv7MzpS6N8UfMEEo2AVcbgCPDvzwBhscYIe96WMyJaYFF8gFD5DddXiKHo3GZ3h2mI_R5_fvrk7PmvOPmw-nb88bKyRZNwLU2BPORmPaYeQ9b4UBKUzfAUhKpCSqN52xdBzqqqPrng3Ciq5XVqieSn6MXt3lblP8Ptf79eSyBe9NgDhnTZXgdUj1P5QxqrhsVaUv_6K3cU6hfmSvqJRcCfYn0KaYc4JRb5ObTFo0JXrfnK7N6X1zlb44BM79BMM9_F1VBc0d2DkPyz-DdDWHwIN3ucDPe2_SNy1VfZ3-erHRm8szcfXpy0Zf8F88mLKc</recordid><startdate>201510</startdate><enddate>201510</enddate><creator>Hand, Laurence H.</creator><creator>Nichols, Carol</creator><creator>Kuet, Sui F.</creator><creator>Oliver, Robin G.</creator><creator>Harbourt, Christopher M.</creator><creator>El-Naggar, Essam M.</creator><general>Blackwell Publishing Ltd</general><scope>BSCLL</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QO</scope><scope>7SN</scope><scope>7SS</scope><scope>7ST</scope><scope>7T7</scope><scope>7TK</scope><scope>7U7</scope><scope>8FD</scope><scope>C1K</scope><scope>FR3</scope><scope>K9.</scope><scope>P64</scope><scope>RC3</scope><scope>SOI</scope><scope>7SU</scope><scope>KR7</scope></search><sort><creationdate>201510</creationdate><title>Quantifying soil surface photolysis under conditions simulating water movement in the field: a new laboratory test design</title><author>Hand, Laurence H. ; 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However, as both downward and upward water movements occur under field conditions, relatively mobile compounds may return to the surface, prolonging exposure to ultraviolet light and increasing the potential for degradation by photolysis. To test this hypothesis, a novel experimental system was used to quantify the contribution of photolysis to the overall dissipation of a new herbicide, bicyclopyrone, under conditions that mimicked field studies more closely than the standard laboratory test guidance. Soil cores were taken from 3 US field study sites, and the surfaces were treated with [14C]‐bicyclopyrone. The radioactivity was redistributed throughout the cores using a simulated rainfall event, following which the cores were incubated under a xenon‐arc lamp with continuous provision of moisture from below and a wind simulator to induce evaporation. After only 2 d, most of the test compound had returned to the soil surface. Significantly more degradation was observed in the irradiated samples than in a parallel dark control sample. Degradation rates were very similar to those observed in both the thin layer photolysis study and the field dissipation studies and significantly faster than in the soil metabolism studies conducted in the dark. Thus, for highly soluble, mobile agrochemicals, such as bicyclopyrone, photolysis is not terminated permanently by rainfall or irrigation but can resume following transport to the surface in evaporating water. Environ Toxicol Chem 2015;34:2236–2243. © 2015 SETAC</abstract><cop>United States</cop><pub>Blackwell Publishing Ltd</pub><pmid>26010776</pmid><doi>10.1002/etc.3074</doi><tpages>8</tpages></addata></record>
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subjects	Abiotic transformation Agricultural chemicals Agrochemicals Bridged Bicyclo Compounds, Heterocyclic - analysis Carbon Radioisotopes - chemistry Chromatography, High Pressure Liquid Cores Degradation Dissipation Drainage Environmental fate Evaporation Herbicides - analysis Irrigation Laboratories Laboratory tests Light Moisture Pesticide Photolysis Photolysis - radiation effects Pore water Pyrones - analysis Pyrones - chemistry Radioactivity Rainfall Simulated rainfall Simulation Soil Soil (material) Soil - chemistry Soil Pollutants - analysis Soil Pollutants - chemistry Soil surfaces Soils Ultraviolet radiation Water Movements Xenon
title	Quantifying soil surface photolysis under conditions simulating water movement in the field: a new laboratory test design
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