Publication details for Professor Jeff WarburtonWorrall, F., Reed, M., Warburton, J. & Burt, T. (2003). Carbon budget for a British upland peat catchment. The Science of the Total Environment 312(1-3): 133-146.
- Publication type: Journal Article
- ISSN/ISBN: 0048-9697
- DOI: 10.1016/S0048-9697(03)00226-2
- Keywords: Carbon budget, Dissolved CO2, Dissolved organic carbon, Inorganic carbon, Peat.
- Further publication details on publisher web site
- Durham Research Online (DRO) - may include full text
Author(s) from Durham
This study describes the analysis of fluvial carbon flux from an upland peat catchment in the North Pennines. Dissolved organic carbon (DOC), pH, alkalinity and calcium were measured in weekly samples, with particulate organic carbon (POC) measured from the suspended sediment load from the stream outlet of an 11.4-km2 catchment. For calendar year 1999, regular monitoring of the catchment was supplemented with detailed quasi-continuous measurements of flow and stream temperature, and DOC for the months September through November. The measurements were used to calculate the annual flux of dissolved CO2, dissolved inorganic carbon, DOC and POC from the catchment and were combined with CO2 and CH4 gaseous exchanges calculated from previously published values and the observations of water table height within the peat. The study catchment represents a net sink of 15.4±11.9 gC/m2/yr. Carbon flows calculated for the study catchment are combined with values in the literature, using a Monte Carlo method, to estimate the carbon budget for British upland peat. For all British upland peat the calculation suggests a net carbon sink of between 0.15 and 0.29 MtC/yr. This is the first study to include a comprehensive study of the fluvial export of carbon within carbon budgets and shows the size of the peat carbon sink to be smaller than previous estimates, although sensitivity analysis shows that the primary productivity rather than fluvial carbon flux is a more important element in estimating the carbon budget in this regard.
Archer D, Stewart D.The installation and use of a snow
pillow to monitor snow water equivalent.J Chart Inst Water
Environ Manage 1995;9:221 –230.
Best EPH, Jacobs FHH.The influence of raised water table
levels on carbon dioxide and methane production in ditchdissected
peat grasslands in the Netherlands.Ecol Eng
Burt TP, Adamson JK, Lane AMJ.Long-term rainfall and
streamflow records for north central England: putting the
Environmental Change Network site at Moor House, Upper
Teesdale, in context.Hydr ol Sci J 1998;43:775 –787.
Cannell MGR, Dewar RC, Pyatt DG.Conifer plantations on
drained peatlands in Britain: a net gain or loss of carbon?
Forestry 1993;66:353 –369.
Cannell MGR, Milne R, Hargreaves KJ, Brown TAW, Cruickshank
MM, Bradley RI, Spencer T, Hope D, Billett MF,
Adger WN, Subak S.National inventories of terrestrial
carbon sources and sinks: the UK experience.Climatic
Change 1999;42:505 –538.
Chapman SJ, Thurlow M.The influence of climate on CO2
and CH4 emissions from organic soils.Agric Forest Meteorol
Clymo RS, Reddaway EJF.Pr oductivity of Sphagnum (bogmoss)
and peat accumulation.Hydr obiologia 1971;12:181 –
Clymo RS, Pearce DME.Methane and carbon dioxide production
in, transport through, and efflux from a peatland.Philos
Trans Roy Soc A 1995;350:249 –259.
Clymo RS, Turunen J, Tolonen K.Carbon accumulation in
peatland.Oikos 1998;81:368 –388.
Crisp DT.Input and output of minerals for an area of Pennine
moorland: the importance of precipitation, drainage, peat
erosion and animals.J Appl Ecol 1966;3:327 –348.
Crisp DT, Howson G.Effect of air temperature upon mean
water temperature in streams in the north Pennines and
English Lake District.Fr esh Biol 1982;12:359 –367.
Dawson JJC, Hope D, Cresser MS, Billet MF.Downstr eam
changes in free carbon dioxide in an upland catchment from
Northeastern Scotland.J Environ Qual 1995;24:699 –706.
Dawson JC, Billet MF, Neal C, Hill S.A comparison of
particulate, dissolved and gaseous carbon in two contrasting
upland streams in the UK.J Hydrol 2002;257:226 –246.
Evans MG, Burt TP, Holden J, Adamson JK.Runoff generation
and water table fluctuations in blanket peat: evidence from
UK data spanning the dry summer of 1995.J Hydrol
Francis IS.Blanket peat erosion in Mid-Wales: two catchment
studies.Ph. D. Thesis (unpublished), Univ.of Wales, Aberystwyth,
Garnett MH.Unpublished Ph.D.Thesis, University of Newcastle-
Haines-Young RH, Barr CJ, Black HIJ, Briggs DJ, Bunce
RGH, Clarke RT, Cooper A, Dawson FH, Firbank LG,
Fuller RM, Furse MT, Gillespie MK, Hill R, Hornung M,
Howard DC, McCann T, Morecroft MD, Petit S, Sier ARJ,
Smart SM, Smith GM, Stott AP, Stuart RC, Watkins JW.
Accounting for nature: assessing habitats in the UK countryside.
London: HMSO, 2000.
HMSO.Climate change—United Kingdom’s report under the
framework convention on climate change.HMSO, London,
Hope D, Billett MF, Cresser MS.A review of the export of
carbon in river water: fluxes and processes.Envir on Pollut
Hope D, Billett MF, Cresser MS.Export of organic carbon in
two river systems in NE Scotland.J Hydrol 1997;193:61 –
Hope D, Billett MF, Milne R, Brown TAW.Exports of organic
carbon in British rivers.Hydr ol Process 1997;11:325 –344.
Hutchinson SM.Use of magnetic and radiometric measurements
to investigate erosion and sedimentation in a British
upland catchment.Earth Surf Process Landforms
Inter-governmental Panel on Climate Change.Climate Change:
the scientific basis 2001.Cambridge University Press, Cambridge,
Johnson GAL, Dunham K.The geology of Moor House.
Nature Conservancy Council.London: HMSO, 1963.
Labadz JC, Burt TP, Potter AWR.Sediment yield and delivery
in the blanket peat moorlands of the Southern Pennines.
Earth Surf Process Landforms 1991;16:255 –271.
Littlewood IG.Estimating constituent loads in rivers: a review.
Institute of Hydrology, rep.117. Institute of Hydrology,
Wallingford, UK 1992.
Lloyd D, Thomas KL, Benstead J, Davies KL, Lloyd SH,
Arah JRM, Stephen KD.Methanogenesis and CO2 exchange
in an ombrotrophic peat bog.Atmos Environ 1998;32:3229 –
Milne R, Brown TA.Carbon in the vegetation and soils of
Great Britain.J Environ Manage 1997;49:413 –433.
Minshall GW, Petersen RC, Cummins KW, Bott TL, Sedell
JR, Cushing CE, Vannote RL.Interbiome comparison of
stream ecosystem dynamics.Ecol Manage 1983;53:1 –25.
Mitchell G, McDonald AT.Discolouration of water by peat
following induced drought and rainfall simulation.W ater
Res 1992;26:321 –326.
Nakano T, Kuniyoshi S, Fukuda M.T emporal variation in
methane emission from tundra wetlands in a permafrost
area, northeastern Siberia.Atmos Environ 2000;34:1205 –
Neal C, House WA, Down K.An assessment of excess carbon
dioxide partial pressures in natural waters based on pH and
alkalinity measurements.Sci Tot Environ 1998;210/
Neumann HH, den Hartog G, Kling KM, Chipanshi AC.
Carbon dioxide fluxes over a raised open bog at Kinosheo
Lake tower site during the Northern Wetlands Study (NOWES).
J Geophys Res 1994;99:1529 –1541.
Newbold JD, Mulholland PJ, Elwood JW, O’Niell RV.Or ganic
carbon spiraling in stream ecosystems.Oikos 1982;38:266 –
Rivers JS, Siegel DI, Chasar LS, Chanton JP, Glaser PH,
Roulet NT, McKenzie JM.A stochastic appraisal of the
annual carbon budget of a large circumboreal peatland,
Rapid River watershed, northern Minnesota.Global Biogeochem
Cycles 1998;12:715 –727.
Scott MJ, Jones MN, Woof C, Tipping E.Concentrations and
fluxes of dissolved organic carbon in drainage water from
an upland peat system.Envir on Int 1998;24:537 –546.
Shurpali NJ, Verma SB, Kim J, Arkebauer TJ.Seasonal
distribution of methane flux in a Minnesota peatland measured
by eddy correlation.J Geophys Res 1993;98:20649 –
Smithsonian Institute.Smithsonian miscellaneous collections,
114 6th Ed, Smithsonian Institution Press, Washington,
Sykes JM, Lane AMJ.The United Kingdom environmental
change network: protocols for standard measurements of terrestrial sites.London: Natural Environment Research
Tallis JH, Meade R.Blanket mire degradation and management.
In: Tallis JH, Meade R, Hulme PD, editors. Blanket
mire degradation: causes, challenges and consequences.
Aberdeen: Macauley Land Use Research Institute, 1998.p.
UNFCCC.Report of the conference of the parties on the
second part of the sixth session, held at Bonn, 16th–17th
July 2001, FCCCyCPy2001y5, United Nations, Geneva.
Van den Pol-Van Dasselaar A, Van Beusichem ML, Oenema
O.Determinants of spatial variability of methane emissions
from wet grasslands on peat soil.Biogeochemistry
Waddington JM, Roulet NT.Atmospher e-wetland carbon
exchanges: scale dependency of CO2and CH4exchange on
development topography of a peatland.Global Biogeochem
Cycles 1996;10:233 –245.
Walling DE, Webb BW.Estimating the discharge of contaminants
to coastal waters by rivers: some cautionary comments.
Marine Poll Bull 1985;16:488 –492.
Whiting GJ.CO 2 exchange in the Hudson Bay Lowlands:
community characteristics and multispectral reflectance
properties.J Geophys Res 1994;99:1519 –1528.
Worrall F, Burt TP, Adamson J.Contr ols on the chemistry of
runoff from an upland peat catchment.Hydr ol Process, in
Worrall F, Burt TP, Jaeban RY, Shedden R.Release of
dissolved organic carbon from upland peat.Hydr ol Process
Wright J.Sustainability of estuarine impoundments. Unpublished
Ph.D. Thesis, University of Durham, 2002.