Relating dissolved organic matter fluorescence and functional properties

The fluorescence excitation–emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are sampled in duplicate, and the 25 samples include ten taken from the lake site, and nine from one of the rivers, to cover variations in dissolved or...

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Published in	Chemosphere (Oxford) Vol. 73; no. 11; pp. 1765 - 1772
Main Authors	Baker, A., Tipping, E., Thacker, S.A., Gondar, D.
Format	Journal Article
Language	English
Published	Kidlington Elsevier Ltd 01.12.2008 Elsevier
Subjects	Absorbance Dissolved organic matter Earth sciences Earth, ocean, space Exact sciences and technology Fluorescence Freshwater Geochemical function Geochemistry Hydrology Hydrology. Hydrogeology Linear Models Marine and continental quaternary Mineralogy Organic Chemicals - chemistry Principal Component Analysis Silicates Solubility Surficial geology Water geochemistry Fluorescence Absorbance Dissolved organic matter Geochemical function fresh-water environment optical methods fluvial environment optical properties lake sediments hydrochemistry fluorescence lacustrine environment organic materials alluvium dissolved materials
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Abstract	The fluorescence excitation–emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are sampled in duplicate, and the 25 samples include ten taken from the lake site, and nine from one of the rivers, to cover variations in dissolved organic matter composition due to season and river flow. Fluorescence properties are compared to the functional properties of the dissolved organic matter; the functional assays provide quantitative information on photochemical fading, buffering capacity, copper binding, benzo[ a]pyrene binding, hydrophilicity and adsorption to alumina. Optical (absorbance and fluorescence) characterization of the dissolved organic matter samples demonstrates that (1) peak C (excitation 300–350 nm; emission 400–460 nm) fluorescence emission wavelength; (2) the ratio of peak T (excitation 220–235 nm; emission 330–370 nm) to peak C fluorescence intensity; and (3) the peak C fluorescence intensity: absorbance at 340 nm ratio have strong correlations with many of the functional assays. Strongest correlations are with benzo[ a]pyrene binding, alumina adsorption, hydrophilicity and buffering capacity, and in many cases linear regression equations with a correlation coefficient >0.8 are obtained. These optical properties are independent of freshwater dissolved organic carbon concentration (for concentrations <10 mg L −1) and therefore hold the potential for laboratory, field and on-line monitoring and prediction of organic matter functional properties.
AbstractList	The fluorescence excitation–emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are sampled in duplicate, and the 25 samples include ten taken from the lake site, and nine from one of the rivers, to cover variations in dissolved organic matter composition due to season and river flow. Fluorescence properties are compared to the functional properties of the dissolved organic matter; the functional assays provide quantitative information on photochemical fading, buffering capacity, copper binding, benzo[ a]pyrene binding, hydrophilicity and adsorption to alumina. Optical (absorbance and fluorescence) characterization of the dissolved organic matter samples demonstrates that (1) peak C (excitation 300–350 nm; emission 400–460 nm) fluorescence emission wavelength; (2) the ratio of peak T (excitation 220–235 nm; emission 330–370 nm) to peak C fluorescence intensity; and (3) the peak C fluorescence intensity: absorbance at 340 nm ratio have strong correlations with many of the functional assays. Strongest correlations are with benzo[ a]pyrene binding, alumina adsorption, hydrophilicity and buffering capacity, and in many cases linear regression equations with a correlation coefficient >0.8 are obtained. These optical properties are independent of freshwater dissolved organic carbon concentration (for concentrations <10 mg L −1) and therefore hold the potential for laboratory, field and on-line monitoring and prediction of organic matter functional properties. The excitation-emission matrices (EEMs) fluorescence properties to characterize the dissolved organic matter (DOM) samples and derive relationships between fluorescence derived DOM character and DOM function was examined. Fluorescence was measured in 4 cm super(3) capacity cuvettes using a Varian Cary Eclipse fluorescence spectrophotometer. It was observed that peak C fluorescence emission wavelength, the ratio of peak T to peak C fluorescence intensity, and the fluorescence-absorbance ratio best differentiate different DOM samples. In particular many DOM samples had a lower peak C emission wavelength and higher peak T intensity. The results showed that regression equations with a correlation coefficient >0.8 were obtained, suggesting that DOM functional character could be predicted from DOM fluorescence properties. The fluorescence excitation-emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are sampled in duplicate, and the 25 samples include ten taken from the lake site, and nine from one of the rivers, to cover variations in dissolved organic matter composition due to season and river flow. Fluorescence properties are compared to the functional properties of the dissolved organic matter; the functional assays provide quantitative information on photochemical fading, buffering capacity, copper binding, benzo[a]pyrene binding, hydrophilicity and adsorption to alumina. Optical (absorbance and fluorescence) characterization of the dissolved organic matter samples demonstrates that (1) peak C (excitation 300-350nm; emission 400-460nm) fluorescence emission wavelength; (2) the ratio of peak T (excitation 220-235nm; emission 330-370nm) to peak C fluorescence intensity; and (3) the peak C fluorescence intensity: absorbance at 340nm ratio have strong correlations with many of the functional assays. Strongest correlations are with benzo[a]pyrene binding, alumina adsorption, hydrophilicity and buffering capacity, and in many cases linear regression equations with a correlation coefficient >0.8 are obtained. These optical properties are independent of freshwater dissolved organic carbon concentration (for concentrations <10mgL super(-) super(1)) and therefore hold the potential for laboratory, field and on-line monitoring and prediction of organic matter functional properties. The fluorescence excitation-emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are sampled in duplicate, and the 25 samples include ten taken from the lake site, and nine from one of the rivers, to cover variations in dissolved organic matter composition due to season and river flow. Fluorescence properties are compared to the functional properties of the dissolved organic matter; the functional assays provide quantitative information on photochemical fading, buffering capacity, copper binding, benzo[a]pyrene binding, hydrophilicity and adsorption to alumina. Optical (absorbance and fluorescence) characterization of the dissolved organic matter samples demonstrates that (1) peak C (excitation 300-350 nm; emission 400-460 nm) fluorescence emission wavelength; (2) the ratio of peak T (excitation 220-235 nm; emission 330-370 nm) to peak C fluorescence intensity; and (3) the peak C fluorescence intensity: absorbance at 340 nm ratio have strong correlations with many of the functional assays. Strongest correlations are with benzo[a]pyrene binding, alumina adsorption, hydrophilicity and buffering capacity, and in many cases linear regression equations with a correlation coefficient >0.8 are obtained. These optical properties are independent of freshwater dissolved organic carbon concentration (for concentrations <10 mg L(-1)) and therefore hold the potential for laboratory, field and on-line monitoring and prediction of organic matter functional properties. The fluorescence excitation-emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are sampled in duplicate, and the 25 samples include ten taken from the lake site, and nine from one of the rivers, to cover variations in dissolved organic matter composition due to season and river flow. Fluorescence properties are compared to the functional properties of the dissolved organic matter; the functional assays provide quantitative information on photochemical fading, buffering capacity, copper binding, benzo[a]pyrene binding, hydrophilicity and adsorption to alumina. Optical (absorbance and fluorescence) characterization of the dissolved organic matter samples demonstrates that (1) peak C (excitation 300-350 nm; emission 400-460 nm) fluorescence emission wavelength; (2) the ratio of peak T (excitation 220-235 nm; emission 330-370 nm) to peak C fluorescence intensity; and (3) the peak C fluorescence intensity: absorbance at 340 nm ratio have strong correlations with many of the functional assays. Strongest correlations are with benzo[a]pyrene binding, alumina adsorption, hydrophilicity and buffering capacity, and in many cases linear regression equations with a correlation coefficient >0.8 are obtained. These optical properties are independent of freshwater dissolved organic carbon concentration (for concentrations <10 mg L(-1)) and therefore hold the potential for laboratory, field and on-line monitoring and prediction of organic matter functional properties.
Author	Thacker, S.A. Tipping, E. Gondar, D. Baker, A.
Author_xml	– sequence: 1 givenname: A. surname: Baker fullname: Baker, A. email: a.baker.2@bham.ac.uk organization: School of Geography, Earth and Environmental Sciences, University of Birmingham, Edgbaston, Birmingham B15 2TT, UK – sequence: 2 givenname: E. surname: Tipping fullname: Tipping, E. organization: Centre for Ecology and Hydrology, Lancaster Environment Centre, Bailrigg, Lancaster LA1 4AP, UK – sequence: 3 givenname: S.A. surname: Thacker fullname: Thacker, S.A. organization: Centre for Ecology and Hydrology, Lancaster Environment Centre, Bailrigg, Lancaster LA1 4AP, UK – sequence: 4 givenname: D. surname: Gondar fullname: Gondar, D. organization: Departamento de Química Física, Facultad de Química. Universidad de Santiago de Compostela, Avda. das Ciencias, 15782 Santiago de Compostela, Spain
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Keywords	Fluorescence Absorbance Dissolved organic matter Geochemical function fresh-water environment optical methods fluvial environment optical properties lake sediments hydrochemistry fluorescence lacustrine environment organic materials alluvium dissolved materials
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Snippet	The fluorescence excitation–emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are... The fluorescence excitation-emission matrix properties of 25 dissolved organic matter samples from three rivers and one lake are analysed. All sites are... The excitation-emission matrices (EEMs) fluorescence properties to characterize the dissolved organic matter (DOM) samples and derive relationships between...
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SubjectTerms	Absorbance Dissolved organic matter Earth sciences Earth, ocean, space Exact sciences and technology Fluorescence Freshwater Geochemical function Geochemistry Hydrology Hydrology. Hydrogeology Linear Models Marine and continental quaternary Mineralogy Organic Chemicals - chemistry Principal Component Analysis Silicates Solubility Surficial geology Water geochemistry
Title	Relating dissolved organic matter fluorescence and functional properties
URI	https://dx.doi.org/10.1016/j.chemosphere.2008.09.018 https://www.ncbi.nlm.nih.gov/pubmed/18951610 https://search.proquest.com/docview/14016233 https://search.proquest.com/docview/14882220 https://search.proquest.com/docview/19585764 https://search.proquest.com/docview/69771570
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