Riverine concentrations and export of dissolved silicon, and potential controls on nutrient stoichiometry, across the land–ocean continuum in Great Britain

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

doi:10.1016/j.jhydrol.2024.131738

Riverine concentrations and export of dissolved silicon, and potential controls on nutrient stoichiometry, across the land–ocean continuum in Great Britain

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

Authors

Andrew M. Tye

Helen P. Jarvie

Bryan M. Spears

Nancy B. Dise

Jennifer L. Williamson

Dan J. Lapworth

Don Monteith

Richard Sanders

Daniel J. Mayor

Michael J. Bowes

Michael Bowes

Annette Burden

Nathan Callaghan

Gareth Farr

Stacey Felgate

Stuart Gibb

Pete Gilbert

Geoff Hargreaves

Olivier S. Humphrey

Patrick Keenan

Vassilis Kitidis

Monika D. Jürgens

Adrian Martin

Monty Pearson

Philip D. Nightingale

M. Gloria Pereira

Justyna Olszewska

Amy Pickard

Andrew P. Rees

Mark Stinchcombe

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

Chris D. Evans

Abstract

Silicon (Si) is an essential nutrient element in freshwater and marine ecosystems, and its abundance relative to macro-nutrients (N, P) can impact phytoplankton communities in eutrophic rivers and estuaries. This study is the first national assessment examining (i) the primary sources (geological, biological, landcover) and controls (geomorphological, precipitation) on the transport of terrestrial dissolved silicon across Great Britain to the ocean, and (ii) the current extent and nature of its interactions with macro-nutrients in these catchments in relation to its potential impacts on phytoplankton community structure. It uses results from a year-long survey of 41 rivers along with historical data. Highest concentrations of dissolved Si (4–5.5 mg L-1) were found in rivers of the chalk- and sedimentary sandstone-based catchments of southern Great Britain and the hard sandstone catchments of Scotland. Catchment yield rates for dissolved Si varied between 0.2 and 2.6 t km−2 yr−1, with highest yields found in catchments with higher precipitation and runoff. Analysis of river N:P and dissolved Si:N ratios suggested that the sampled rivers were typically N enriched, and P limited with respect to dissolved Si. Molar dissolved Si:N ratios < 1, an indicator of river eutrophication, were associated with total nitrogen concentrations exceeding 1.8 mg L-1 or greater. The Indicator of Coastal Eutrophication index was used to assess the potential role of dissolved Si in the eutrophication of coastal waters. Negative values indicating limited eutrophication potential to non-siliceous algae were generally found, although some rivers had annual Indicator of Coastal Eutrophication index values exceeding 0, with values as high as 35 kg C km−2 day−1. In many eutrophic rivers, high dissolved Si concentrations derived from catchment lithology, kept the Indicator of Coastal Eutrophication index values below zero. Results have demonstrated that high N and P export have likely shifted most Great Britain rivers and coastal waters beyond the stoichiometric range where diatoms dominate production and into one where non-siliceous algae maybe increasingly present. Thus, future assessments of macro-nutrient management schemes, such as those involving wetlands should include dissolved Si routinely due to its stoichiometric importance.

Citation

Tye, A. M., Jarvie, H. P., Spears, B. M., Dise, N. B., Williamson, J. L., Lapworth, D. J., Monteith, D., Sanders, R., Mayor, D. J., Bowes, M. J., Bowes, M., Burden, A., Callaghan, N., Farr, G., Felgate, S., Gibb, S., Gilbert, P., Hargreaves, G., Humphrey, O. S., Keenan, P., …Evans, C. D. (2024). Riverine concentrations and export of dissolved silicon, and potential controls on nutrient stoichiometry, across the land–ocean continuum in Great Britain. Journal of Hydrology, 640, Article 131738. https://doi.org/10.1016/j.jhydrol.2024.131738

Journal Article Type	Article
Acceptance Date	Jul 15, 2024
Online Publication Date	Jul 31, 2024
Publication Date	2024-08
Deposit Date	Sep 5, 2024
Publicly Available Date	Sep 5, 2024
Journal	Journal of Hydrology
Print ISSN	0022-1694
Publisher	Elsevier
Peer Reviewed	Peer Reviewed
Volume	640
Article Number	131738
DOI	https://doi.org/10.1016/j.jhydrol.2024.131738
Public URL	https://durham-repository.worktribe.com/output/2798789