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Investigations of freezing and cold storage for the analysis of peatland dissolved organic carbon (DOC) and absorbance properties. / Peacock, M.; Freeman, C.; Gaucia, V. et al.
In: Environmental Science: Processes and Impacts, Vol. 17, No. 7, 29.05.2015.

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Peacock M, Freeman C, Gaucia V, Lebronc IE. Investigations of freezing and cold storage for the analysis of peatland dissolved organic carbon (DOC) and absorbance properties. Environmental Science: Processes and Impacts. 2015 May 29;17(7). doi: 10.1039/C5EM00126A

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Peacock, M. ; Freeman, C. ; Gaucia, V. et al. / Investigations of freezing and cold storage for the analysis of peatland dissolved organic carbon (DOC) and absorbance properties. In: Environmental Science: Processes and Impacts. 2015 ; Vol. 17, No. 7.

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TY - JOUR

T1 - Investigations of freezing and cold storage for the analysis of peatland dissolved organic carbon (DOC) and absorbance properties

AU - Peacock, M.

AU - Freeman, C.

AU - Gaucia, V.

AU - Lebronc, I.E.

PY - 2015/5/29

Y1 - 2015/5/29

N2 - Although measured rates of biological degradation of DOC are typically low under dark conditions, it is assumed that water samples must be analysed soon after collection to provide an accurate measure of DOC concentration and UV-visible absorbance. To examine the impact of storage on DOC quality and quantity, we took water samples from an ombrotrophic peatland, and stored them in the dark at 4 °C for 138–1082 days. A median of 29% of DOC was lost during storage, but losses of absorbance at 254 nm were less. DOC loss followed a first-order exponential decay function, and was dependent on storage time. DOC half-life was calculated as 1253 days. Specific absorbance at 254 nm suggested that samples containing more aromatic DOC were more resistant to degradation, although time functioned as the primary control. Samples from two fens showed that loss of absorbance was greater at 400 nm rather than 254 nm, after 192 days storage, suggesting that non-aromatic DOC is preferentially degraded. These results suggest that samples can be stored for several months before losses of DOC become detectable, and that it is possible to back-calculate initial DOC concentrations in long-term stored samples based on known decay rates. Freeze/thaw experiments using samples from a range of peatlands suggested that DOC concentration was mostly unaffected by the process, but DOC increased 37% in one sample. Freezing had unpredictable and sometimes strong effects on absorbance, SUVA and E ratios, therefore freezing is not recommended as a method of preservation for these analyses.

AB - Although measured rates of biological degradation of DOC are typically low under dark conditions, it is assumed that water samples must be analysed soon after collection to provide an accurate measure of DOC concentration and UV-visible absorbance. To examine the impact of storage on DOC quality and quantity, we took water samples from an ombrotrophic peatland, and stored them in the dark at 4 °C for 138–1082 days. A median of 29% of DOC was lost during storage, but losses of absorbance at 254 nm were less. DOC loss followed a first-order exponential decay function, and was dependent on storage time. DOC half-life was calculated as 1253 days. Specific absorbance at 254 nm suggested that samples containing more aromatic DOC were more resistant to degradation, although time functioned as the primary control. Samples from two fens showed that loss of absorbance was greater at 400 nm rather than 254 nm, after 192 days storage, suggesting that non-aromatic DOC is preferentially degraded. These results suggest that samples can be stored for several months before losses of DOC become detectable, and that it is possible to back-calculate initial DOC concentrations in long-term stored samples based on known decay rates. Freeze/thaw experiments using samples from a range of peatlands suggested that DOC concentration was mostly unaffected by the process, but DOC increased 37% in one sample. Freezing had unpredictable and sometimes strong effects on absorbance, SUVA and E ratios, therefore freezing is not recommended as a method of preservation for these analyses.

U2 - 10.1039/C5EM00126A

DO - 10.1039/C5EM00126A

M3 - Article

VL - 17

JO - Environmental Science: Processes and Impacts

JF - Environmental Science: Processes and Impacts

SN - 2050-7887

IS - 7

ER -