Long-term rise in riverine dissolved organic carbon concentration is predicted by electrolyte solubility theory

Monteith, D.T., Henrys, P.A., Hruska, J., de Wit, H.A., Kram, P., Moldan, F., Posch, M. ORCID: https://orcid.org/0000-0001-8649-9129, Raike, A., et al. (2023). Long-term rise in riverine dissolved organic carbon concentration is predicted by electrolyte solubility theory. Science Advances 9 (3) eade3491. 10.1126/sciadv.ade3491.

[thumbnail of Monteith_etal-23.pdf]
Preview
Text
Monteith_etal-23.pdf - Published Version
Available under License Creative Commons Attribution.

Download (1MB) | Preview
[thumbnail of Monteith_etal-23_SI.pdf]
Preview
Text
Monteith_etal-23_SI.pdf - Supplemental Material
Available under License Creative Commons Attribution.

Download (1MB) | Preview

Abstract

The riverine dissolved organic carbon (DOC) flux is of similar magnitude to the terrestrial sink for atmospheric CO2, but the factors controlling it remain poorly determined and are largely absent from Earth system models (ESMs). Here, we show, for a range of European headwater catchments, that electrolyte solubility theory explains how declining precipitation ionic strength (IS) has increased the dissolution of thermally moderated pools of soluble soil organic matter (OM), while hydrological conditions govern the proportion of this OM entering the aquatic system. Solubility will continue to rise exponentially with declining IS until pollutant ion deposition fully flattens out under clean air policies. Future DOC export will increasingly depend on rates of warming and any directional changes to the intensity and seasonality of precipitation and marine ion deposition. Our findings provide a firm foundation for incorporating the processes dominating change in this component of the global carbon cycle in ESMs. More dilute rainwater, due to less polluted air, dissolves more soil organic matter, resulting in the browning of rivers.

Item Type: Article
Research Programs: Energy, Climate, and Environment (ECE)
Energy, Climate, and Environment (ECE) > Pollution Management (PM)
Depositing User: Luke Kirwan
Date Deposited: 19 Jan 2023 12:40
Last Modified: 23 Jan 2023 17:50
URI: https://pure.iiasa.ac.at/18576

Actions (login required)

View Item View Item