The power of runoff

•Quantification of the spatial and temporal characteristics of energies in terrestrial hydrology.•Determination of climatic factors explaining the fluctuation in hydrological energies.•Spectral decomposition of runoff and climate processes reveals hydro-climatic coherence.•The power of runoff drives...

Full description

Saved in:
Bibliographic Details
Published inJournal of hydrology (Amsterdam) Vol. 548; pp. 784 - 793
Main Authors Wörman, A., Lindström, G., Riml, J.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.05.2017
Subjects
Online AccessGet full text

Cover

Loading…
More Information
Summary:•Quantification of the spatial and temporal characteristics of energies in terrestrial hydrology.•Determination of climatic factors explaining the fluctuation in hydrological energies.•Spectral decomposition of runoff and climate processes reveals hydro-climatic coherence.•The power of runoff drives geo-scientific processes like erosion and solute cycling. Although the potential energy of surface water is a small part of Earth’s energy budget, this highly variable physical property is a key component in the terrestrial hydrologic cycle empowering geomorphological and hydrological processes throughout the hydrosphere. By downscaling of the daily hydrometeorological data acquired in Sweden over the last half-century this study quantifies the spatial and temporal distribution of the dominating energy components in terrestrial hydrology, including the frictional resistance in surface water and groundwater as well as hydropower. The energy consumed in groundwater circulation was found to be 34.6TWh/y or a heat production of approximately 13% of the geothermal heat flux. Significant climate driven, periodic fluctuations in the power of runoff, stream flows and groundwater circulation were revealed that have not previously been documented. We found that the runoff power ranged from 173 to 260TWh/y even when averaged over the entire surface of Sweden in a five-year moving window. We separated short-term fluctuations in runoff due to precipitation filtered through the watershed from longer-term seasonal and climate driven modes. Strong climate driven correlations between the power of runoff and climate indices, wind and solar intensity were found over periods of 3.6 and 8years. The high covariance that we found between the potential energy of surface water and wind energy implies significant challenges for the combination of these renewable energy sources.
ISSN:0022-1694
1879-2707
1879-2707
DOI:10.1016/j.jhydrol.2017.03.041