Dissolved inorganic carbon export from rivers of Great Britain: Spatial distribution and potential catchment-scale controls

Tye, Andrew M.; Williamson, Jennifer L.; Jarvie, Helen P.; Dise, Nancy B.; Lapworth, Dan J.; Monteith, Don; Sanders, Richard; Mayor, Daniel J.; Bowes, Michael J.; Bowes, Michael; Burden, Annette; Callaghan, Nathan; Farr, Gareth; Felgate, Stacey L.; Gibb, Stuart; Gilbert, Pete J.; Hargreaves, Geoff; Keenan, Patrick; Kitidis, Vassilis; Jürgens, Monika D.; Martin, Adrian; Mounteney, Ian; Nightingale, Philip D.; Gloria Pereira, M.; Olszewska, Justyna; Pickard, Amy; Rees, Andrew P.; Spears, Bryan; Stinchcombe, Mark; White, Debbie; Williams, Peter; Worrall, Fred; Evans, Chris D.

doi:10.1016/j.jhydrol.2022.128677

Dissolved inorganic carbon export from rivers of Great Britain: Spatial distribution and potential catchment-scale controls

Tye, Andrew M.; Williamson, Jennifer L.; Jarvie, Helen P.; Dise, Nancy B.; Lapworth, Dan J.; Monteith, Don; Sanders, Richard; Mayor, Daniel J.; Bowes, Michael J.; Bowes, Michael; Burden, Annette; Callaghan, Nathan; Farr, Gareth; Felgate, Stacey L.; Gibb, Stuart; Gilbert, Pete J.; Hargreaves, Geoff; Keenan, Patrick; Kitidis, Vassilis; Jürgens, Monika D.; Martin, Adrian; Mounteney, Ian; Nightingale, Philip D.; Gloria Pereira, M.; Olszewska, Justyna; Pickard, Amy; Rees, Andrew P.; Spears, Bryan; Stinchcombe, Mark; White, Debbie; Williams, Peter; Worrall, Fred; Evans, Chris D.

Authors

Andrew M. Tye

Jennifer L. Williamson

Helen P. Jarvie

Nancy B. Dise

Dan J. Lapworth

Don Monteith

Richard Sanders

Daniel J. Mayor

Michael J. Bowes

Michael Bowes

Annette Burden

Nathan Callaghan

Gareth Farr

Stacey L. Felgate

Stuart Gibb

Pete J. Gilbert

Geoff Hargreaves

Patrick Keenan

Vassilis Kitidis

Monika D. Jürgens

Adrian Martin

Ian Mounteney

Philip D. Nightingale

M. Gloria Pereira

Justyna Olszewska

Amy Pickard

Andrew P. Rees

Bryan Spears

Mark Stinchcombe

Debbie White

Peter Williams

Professor Fred Worrall fred.worrall@durham.ac.uk
Professor

Chris D. Evans

Abstract

Dissolved inorganic carbon (DIC) fluxes from the land to ocean have been quantified for many rivers globally. However, CO2 fluxes to the atmosphere from inland waters are quantitatively significant components of the global carbon cycle that are currently poorly constrained. Understanding, the relative contributions of natural and human-impacted processes on the DIC cycle within catchments may provide a basis for developing improved management strategies to mitigate free CO2 concentrations in rivers and subsequent evasion to the atmosphere. Here, a large, internally consistent dataset collected from 41 catchments across Great Britain (GB), accounting for ∼36% of land area (∼83,997 km2) and representative of national land cover, was used to investigate catchment controls on riverine dissolved inorganic carbon (DIC), bicarbonate (HCO3−) and free CO2 concentrations, fluxes to the coastal sea and annual yields per unit area of catchment. Estimated DIC flux to sea for the survey catchments was 647 kt DIC yr−1 which represented 69% of the total dissolved carbon flux from these catchments. Generally, those catchments with large proportions of carbonate and sedimentary sandstone were found to deliver greater DIC and HCO3− to the ocean. The calculated mean free CO2 yield for survey catchments (i.e. potential CO2 emission to the atmosphere) was 0.56 t C km−2 yr−1. Regression models demonstrated that whilst river DIC (R2 = 0.77) and HCO3− (R2 = 0.77) concentrations are largely explained by the geology of the landmass, along with a negative correlation to annual precipitation, free CO2 concentrations were strongly linked to catchment macronutrient status. Overall, DIC dominates dissolved C inputs to coastal waters, meaning that estuarine carbon dynamics are sensitive to underlying geology and therefore are likely to be reasonably constant. In contrast, potential losses of carbon to the atmosphere via dissolved CO2, which likely constitute a significant fraction of net terrestrial ecosystem production and hence the national carbon budget, may be amenable to greater direct management via altering patterns of land use.

Citation

Tye, A. M., Williamson, J. L., Jarvie, H. P., Dise, N. B., Lapworth, D. J., Monteith, D., …Evans, C. D. (2022). Dissolved inorganic carbon export from rivers of Great Britain: Spatial distribution and potential catchment-scale controls. Journal of Hydrology, 615(Part A), Article 128677. https://doi.org/10.1016/j.jhydrol.2022.128677

Journal Article Type	Article
Acceptance Date	Oct 11, 2022
Online Publication Date	Nov 7, 2022
Publication Date	2022
Deposit Date	Oct 26, 2023
Publicly Available Date	Oct 26, 2023
Journal	Journal of Hydrology
Print ISSN	0022-1694
Publisher	Elsevier
Peer Reviewed	Peer Reviewed
Volume	615
Issue	Part A
Article Number	128677
DOI	https://doi.org/10.1016/j.jhydrol.2022.128677
Public URL	https://durham-repository.worktribe.com/output/1818792

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Published by Elsevier B.V. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)