Spatial and temporal variations in critical loads for rivers in NE Scotland: A validation of approaches

C C White; R Smart; M S Cresser

Spatial and temporal variations in critical loads for rivers in NE Scotland: A validation of approaches

C C White, R Smart, M S Cresser

Environment and Geography

Research output: Contribution to journal › Article › peer-review

Abstract

Previously, critical load maps for UK surface freshwaters have been created by applying the steady state water chemistry model to a spot sample of water from a lake, from each 10 km square. If no lake is present, as was the case for many squares in the north east of Scotland, a sample from a river thought likely to be most sensitive to acidification was used. This study evaluates the effectiveness of this approach for protecting all the waters of the complex river network of a major catchment in N.E. Scotland, under high and low Row regimes. Samples were collected and analysed over a period of one year, at intervals of two weeks, from 59 sub-catchments of the River Dee catchment. Critical load values were calculated for every sample, and also using mean annual concentrations of Na (+)(,) Ca2 + Mg-2 (+), K (+) and Cl-. In addition, to investigate discharge effects, they also were calculated for each site for base and high flows, using stream water chemistry corresponding to the three lowest and the three highest discharge levels respectively. Only two rivers were insufficiently protected under base flow conditions, whereas 20 apparently were not sufficiently protected under high Row conditions. It is concluded that the system used in the UK is generally very effective for protection of rivers, but only under low flow conditions. More work is needed to assess the biological impacts of episodic critical load exceedance in upland rivers. A more recently suggested approach for classifying UK river water sensitivity to acidification from the Na (+) dominance of the solute base cations in water samples is also shown to be effective for this river system. (C) 2000 Elsevier Science Ltd. All rights reserved.

Original language	English
Pages (from-to)	1912-1918
Number of pages	7
Journal	Water research
Volume	34
Issue number	6
Publication status	Published - Apr 2000

Keywords

critical load
freshwaters
acidification
weathering rates
sea salts
WATER-QUALITY
CATCHMENT

Cite this

@article{d82c271ebb7f4f9786e2dff6602fc77a,

title = "Spatial and temporal variations in critical loads for rivers in NE Scotland: A validation of approaches",

abstract = "Previously, critical load maps for UK surface freshwaters have been created by applying the steady state water chemistry model to a spot sample of water from a lake, from each 10 km square. If no lake is present, as was the case for many squares in the north east of Scotland, a sample from a river thought likely to be most sensitive to acidification was used. This study evaluates the effectiveness of this approach for protecting all the waters of the complex river network of a major catchment in N.E. Scotland, under high and low Row regimes. Samples were collected and analysed over a period of one year, at intervals of two weeks, from 59 sub-catchments of the River Dee catchment. Critical load values were calculated for every sample, and also using mean annual concentrations of Na (+)(,) Ca2 + Mg-2 (+), K (+) and Cl-. In addition, to investigate discharge effects, they also were calculated for each site for base and high flows, using stream water chemistry corresponding to the three lowest and the three highest discharge levels respectively. Only two rivers were insufficiently protected under base flow conditions, whereas 20 apparently were not sufficiently protected under high Row conditions. It is concluded that the system used in the UK is generally very effective for protection of rivers, but only under low flow conditions. More work is needed to assess the biological impacts of episodic critical load exceedance in upland rivers. A more recently suggested approach for classifying UK river water sensitivity to acidification from the Na (+) dominance of the solute base cations in water samples is also shown to be effective for this river system. (C) 2000 Elsevier Science Ltd. All rights reserved.",

keywords = "critical load, freshwaters, acidification, weathering rates, sea salts, WATER-QUALITY, CATCHMENT",

author = "White, {C C} and R Smart and Cresser, {M S}",

year = "2000",

month = apr,

language = "English",

volume = "34",

pages = "1912--1918",

journal = "Water research",

issn = "0043-1354",

publisher = "Elsevier",

number = "6",

}

TY - JOUR

T1 - Spatial and temporal variations in critical loads for rivers in NE Scotland: A validation of approaches

AU - White, C C

AU - Smart, R

AU - Cresser, M S

PY - 2000/4

Y1 - 2000/4

N2 - Previously, critical load maps for UK surface freshwaters have been created by applying the steady state water chemistry model to a spot sample of water from a lake, from each 10 km square. If no lake is present, as was the case for many squares in the north east of Scotland, a sample from a river thought likely to be most sensitive to acidification was used. This study evaluates the effectiveness of this approach for protecting all the waters of the complex river network of a major catchment in N.E. Scotland, under high and low Row regimes. Samples were collected and analysed over a period of one year, at intervals of two weeks, from 59 sub-catchments of the River Dee catchment. Critical load values were calculated for every sample, and also using mean annual concentrations of Na (+)(,) Ca2 + Mg-2 (+), K (+) and Cl-. In addition, to investigate discharge effects, they also were calculated for each site for base and high flows, using stream water chemistry corresponding to the three lowest and the three highest discharge levels respectively. Only two rivers were insufficiently protected under base flow conditions, whereas 20 apparently were not sufficiently protected under high Row conditions. It is concluded that the system used in the UK is generally very effective for protection of rivers, but only under low flow conditions. More work is needed to assess the biological impacts of episodic critical load exceedance in upland rivers. A more recently suggested approach for classifying UK river water sensitivity to acidification from the Na (+) dominance of the solute base cations in water samples is also shown to be effective for this river system. (C) 2000 Elsevier Science Ltd. All rights reserved.

AB - Previously, critical load maps for UK surface freshwaters have been created by applying the steady state water chemistry model to a spot sample of water from a lake, from each 10 km square. If no lake is present, as was the case for many squares in the north east of Scotland, a sample from a river thought likely to be most sensitive to acidification was used. This study evaluates the effectiveness of this approach for protecting all the waters of the complex river network of a major catchment in N.E. Scotland, under high and low Row regimes. Samples were collected and analysed over a period of one year, at intervals of two weeks, from 59 sub-catchments of the River Dee catchment. Critical load values were calculated for every sample, and also using mean annual concentrations of Na (+)(,) Ca2 + Mg-2 (+), K (+) and Cl-. In addition, to investigate discharge effects, they also were calculated for each site for base and high flows, using stream water chemistry corresponding to the three lowest and the three highest discharge levels respectively. Only two rivers were insufficiently protected under base flow conditions, whereas 20 apparently were not sufficiently protected under high Row conditions. It is concluded that the system used in the UK is generally very effective for protection of rivers, but only under low flow conditions. More work is needed to assess the biological impacts of episodic critical load exceedance in upland rivers. A more recently suggested approach for classifying UK river water sensitivity to acidification from the Na (+) dominance of the solute base cations in water samples is also shown to be effective for this river system. (C) 2000 Elsevier Science Ltd. All rights reserved.

KW - critical load

KW - freshwaters

KW - acidification

KW - weathering rates

KW - sea salts

KW - WATER-QUALITY

KW - CATCHMENT

M3 - Article

SN - 0043-1354

VL - 34

SP - 1912

EP - 1918

JO - Water research

JF - Water research

IS - 6

ER -