Effects of decreasing acid deposition and climate change on acid extremes in an upland stream

This study assesses the major chemical processes leading to acid extremes in a small, moorland stream in mid-Wales, UK, which has been monitored since 1979. Results suggest that base cation (mainly calcium) dilution, the "sea-salt effect", and elevated nitrate pulses, are the major...

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Main Authors: C. D. Evans, B. Reynolds, C. Hinton, S. Hughes, D. Norris, S. Grant, B. Williams
Format: Article
Language:English
Published: Copernicus Publications 2008-03-01
Series:Hydrology and Earth System Sciences
Online Access:http://www.hydrol-earth-syst-sci.net/12/337/2008/hess-12-337-2008.pdf
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spelling doaj-070189c849df4b12b83683ce5d013e6c2020-11-24T22:50:42ZengCopernicus PublicationsHydrology and Earth System Sciences1027-56061607-79382008-03-01122337351Effects of decreasing acid deposition and climate change on acid extremes in an upland streamC. D. EvansB. ReynoldsC. HintonS. HughesD. NorrisS. GrantB. WilliamsThis study assesses the major chemical processes leading to acid extremes in a small, moorland stream in mid-Wales, UK, which has been monitored since 1979. Results suggest that base cation (mainly calcium) dilution, the "sea-salt effect", and elevated nitrate pulses, are the major causes of seasonal/episodic minima in acid neutralising capacity (ANC), and that the relative importance of these drivers has remained approximately constant during 25 years of decreasing acid deposition and associated long-term chemical recovery. Many of the chemical variations causing short-term reductions in stream acidity, particularly base cation dilution and organic acid increases, are closely related to changes in water-flowpath and therefore to stream discharge. Changes in the observed pH-discharge relationship over time indicate that high-flow pH has increased more rapidly than mean-flow pH, and therefore that episodes have decreased in magnitude since 1980. However a two-box application of the dynamic model MAGIC, whilst reproducing this trend, suggests that it will not persist in the long term, with mean ANC continuing to increase until 2100, but the ANC of the upper soil (the source of relatively acid water during high-flow episodes) stabilising close to zero beyond 2030. With climate change predicted to lead to an increase in maximum flows in the latter half of the century, high-flow related acid episodes may actually become more rather than less severe in the long term, although the model suggests that this effect may be small. Two other predicted climatic changes could also detrimentally impact on acid episodes: increased severity of winter "sea-salt" episodes due to higher wind speeds during winter storms; and larger sulphate pulses due to oxidation of reduced sulphur held in organic soils, during more extreme summer droughts. At the Gwy, the near-coastal location and relatively small extent of peat soils suggest that sea-salt episodes may have the greatest influence. http://www.hydrol-earth-syst-sci.net/12/337/2008/hess-12-337-2008.pdf
collection DOAJ
language English
format Article
sources DOAJ
author C. D. Evans
B. Reynolds
C. Hinton
S. Hughes
D. Norris
S. Grant
B. Williams
spellingShingle C. D. Evans
B. Reynolds
C. Hinton
S. Hughes
D. Norris
S. Grant
B. Williams
Effects of decreasing acid deposition and climate change on acid extremes in an upland stream
Hydrology and Earth System Sciences
author_facet C. D. Evans
B. Reynolds
C. Hinton
S. Hughes
D. Norris
S. Grant
B. Williams
author_sort C. D. Evans
title Effects of decreasing acid deposition and climate change on acid extremes in an upland stream
title_short Effects of decreasing acid deposition and climate change on acid extremes in an upland stream
title_full Effects of decreasing acid deposition and climate change on acid extremes in an upland stream
title_fullStr Effects of decreasing acid deposition and climate change on acid extremes in an upland stream
title_full_unstemmed Effects of decreasing acid deposition and climate change on acid extremes in an upland stream
title_sort effects of decreasing acid deposition and climate change on acid extremes in an upland stream
publisher Copernicus Publications
series Hydrology and Earth System Sciences
issn 1027-5606
1607-7938
publishDate 2008-03-01
description This study assesses the major chemical processes leading to acid extremes in a small, moorland stream in mid-Wales, UK, which has been monitored since 1979. Results suggest that base cation (mainly calcium) dilution, the "sea-salt effect", and elevated nitrate pulses, are the major causes of seasonal/episodic minima in acid neutralising capacity (ANC), and that the relative importance of these drivers has remained approximately constant during 25 years of decreasing acid deposition and associated long-term chemical recovery. Many of the chemical variations causing short-term reductions in stream acidity, particularly base cation dilution and organic acid increases, are closely related to changes in water-flowpath and therefore to stream discharge. Changes in the observed pH-discharge relationship over time indicate that high-flow pH has increased more rapidly than mean-flow pH, and therefore that episodes have decreased in magnitude since 1980. However a two-box application of the dynamic model MAGIC, whilst reproducing this trend, suggests that it will not persist in the long term, with mean ANC continuing to increase until 2100, but the ANC of the upper soil (the source of relatively acid water during high-flow episodes) stabilising close to zero beyond 2030. With climate change predicted to lead to an increase in maximum flows in the latter half of the century, high-flow related acid episodes may actually become more rather than less severe in the long term, although the model suggests that this effect may be small. Two other predicted climatic changes could also detrimentally impact on acid episodes: increased severity of winter "sea-salt" episodes due to higher wind speeds during winter storms; and larger sulphate pulses due to oxidation of reduced sulphur held in organic soils, during more extreme summer droughts. At the Gwy, the near-coastal location and relatively small extent of peat soils suggest that sea-salt episodes may have the greatest influence.
url http://www.hydrol-earth-syst-sci.net/12/337/2008/hess-12-337-2008.pdf
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