Groundwater deeper than 500 m contributes less than 0.1% of global river discharge

Grant Ferguson; Jennifer C. McIntosh; Scott Jasechko; Ji Hyun Kim; James S. Famiglietti; Jeffrey J. McDonnell

doi:10.1038/s43247-023-00697-6

Groundwater deeper than 500 m contributes less than 0.1% of global river discharge

Grant Ferguson, Jennifer C. McIntosh, Scott Jasechko, Ji Hyun Kim, James S. Famiglietti, Jeffrey J. McDonnell

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19 Scopus citations

Abstract

Groundwater is one of the largest reservoirs of water on Earth but has relatively small fluxes compared to its volume. This behavior is exaggerated at depths below 500 m, where the majority of groundwater exists and where residence times of millions to even a billion years have been documented. However, the extent of interactions between deep groundwater (>500 m) and the rest of the terrestrial water cycle at a global scale are unclear because of challenges in detecting their contributions to streamflow. Here, we use a chloride mass balance approach to quantify the contribution of deep groundwater to global streamflow. Deep groundwater likely contributes <0.1% to global streamflow and is only weakly and sporadically connected to the rest of the water cycle on geological timescales. Despite this weak connection to streamflow, we found that deep groundwaters are important to the global chloride cycle, providing ~7% of the flux of chloride to the ocean.

Original language	English (US)
Article number	48
Journal	Communications Earth and Environment
Volume	4
Issue number	1
DOIs	https://doi.org/10.1038/s43247-023-00697-6
State	Published - Dec 2023

ASJC Scopus subject areas

General Environmental Science
General Earth and Planetary Sciences

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title = "Groundwater deeper than 500 m contributes less than 0.1% of global river discharge",

abstract = "Groundwater is one of the largest reservoirs of water on Earth but has relatively small fluxes compared to its volume. This behavior is exaggerated at depths below 500 m, where the majority of groundwater exists and where residence times of millions to even a billion years have been documented. However, the extent of interactions between deep groundwater (>500 m) and the rest of the terrestrial water cycle at a global scale are unclear because of challenges in detecting their contributions to streamflow. Here, we use a chloride mass balance approach to quantify the contribution of deep groundwater to global streamflow. Deep groundwater likely contributes <0.1% to global streamflow and is only weakly and sporadically connected to the rest of the water cycle on geological timescales. Despite this weak connection to streamflow, we found that deep groundwaters are important to the global chloride cycle, providing ~7% of the flux of chloride to the ocean.",

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AU - Ferguson, Grant

AU - McIntosh, Jennifer C.

AU - Jasechko, Scott

AU - Kim, Ji Hyun

AU - Famiglietti, James S.

AU - McDonnell, Jeffrey J.

PY - 2023/12

Y1 - 2023/12

N2 - Groundwater is one of the largest reservoirs of water on Earth but has relatively small fluxes compared to its volume. This behavior is exaggerated at depths below 500 m, where the majority of groundwater exists and where residence times of millions to even a billion years have been documented. However, the extent of interactions between deep groundwater (>500 m) and the rest of the terrestrial water cycle at a global scale are unclear because of challenges in detecting their contributions to streamflow. Here, we use a chloride mass balance approach to quantify the contribution of deep groundwater to global streamflow. Deep groundwater likely contributes <0.1% to global streamflow and is only weakly and sporadically connected to the rest of the water cycle on geological timescales. Despite this weak connection to streamflow, we found that deep groundwaters are important to the global chloride cycle, providing ~7% of the flux of chloride to the ocean.

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Groundwater deeper than 500 m contributes less than 0.1% of global river discharge

Abstract

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