Cross-scale impact of climate temporal variability on ecosystem water and carbon fluxes
Cross-scale impact of climate temporal variability on ecosystem water and carbon fluxes
While the importance of ecosystem functioning is undisputed in the context of climate change and Earth system modeling, the role of short-scale temporal variability of hydrometeorological forcing (~1?h) on the related ecosystem processes remains to be fully understood. Various impacts of meteorological forcing variability on water and carbon fluxes across a range of scales are explored here using numerical simulations. Synthetic meteorological drivers that highlight dynamic features of the short temporal scale in series of precipitation, temperature, and radiation are constructed. These drivers force a mechanistic ecohydrological model that propagates information content into the dynamics of water and carbon fluxes for an ensemble of representative ecosystems. The focus of the analysis is on a cross-scale effect of the short-scale forcing variability on the modeled evapotranspiration and ecosystem carbon assimilation. Interannual variability of water and carbon fluxes is emphasized in the analysis. The main study inferences are summarized as follows: (a) short-scale variability of meteorological input does affect water and carbon fluxes across a wide range of time scales, spanning from the hourly to the annual and longer scales; (b) different ecosystems respond to the various characteristics of the short-scale variability of the climate forcing in various ways, depending on dominant factors limiting system productivity; (c) whenever short-scale variability of meteorological forcing influences primarily fast processes such as photosynthesis, its impact on the slow-scale variability of water and carbon fluxes is small; and (d) whenever short-scale variability of the meteorological forcing impacts slow processes such as movement and storage of water in the soil, the effects of the variability can propagate to annual and longer time scales.
cross-scale interactions, ecohydrological modeling, ecosystem response, interannual variability, short-scale temporal climate variability, spectral analysis
1716-1740
Paschalis, Athanasios
e7626e9f-172b-4da2-882c-bddb219f3fb6
Fatichi, Simone
2a12468d-8094-495b-922d-4d00aa0afb11
Katul, Gabriel G.
5f0cb2ab-2d91-4cc4-9ac2-e5c2eaf928f9
Ivanov, Valeriy Y.
6f2ad766-068f-45f6-93c2-33d2f1565bdf
September 2015
Paschalis, Athanasios
e7626e9f-172b-4da2-882c-bddb219f3fb6
Fatichi, Simone
2a12468d-8094-495b-922d-4d00aa0afb11
Katul, Gabriel G.
5f0cb2ab-2d91-4cc4-9ac2-e5c2eaf928f9
Ivanov, Valeriy Y.
6f2ad766-068f-45f6-93c2-33d2f1565bdf
Paschalis, Athanasios, Fatichi, Simone, Katul, Gabriel G. and Ivanov, Valeriy Y.
(2015)
Cross-scale impact of climate temporal variability on ecosystem water and carbon fluxes.
Journal of Geophysical Research, 120 (9), .
(doi:10.1002/2015JG003002).
Abstract
While the importance of ecosystem functioning is undisputed in the context of climate change and Earth system modeling, the role of short-scale temporal variability of hydrometeorological forcing (~1?h) on the related ecosystem processes remains to be fully understood. Various impacts of meteorological forcing variability on water and carbon fluxes across a range of scales are explored here using numerical simulations. Synthetic meteorological drivers that highlight dynamic features of the short temporal scale in series of precipitation, temperature, and radiation are constructed. These drivers force a mechanistic ecohydrological model that propagates information content into the dynamics of water and carbon fluxes for an ensemble of representative ecosystems. The focus of the analysis is on a cross-scale effect of the short-scale forcing variability on the modeled evapotranspiration and ecosystem carbon assimilation. Interannual variability of water and carbon fluxes is emphasized in the analysis. The main study inferences are summarized as follows: (a) short-scale variability of meteorological input does affect water and carbon fluxes across a wide range of time scales, spanning from the hourly to the annual and longer scales; (b) different ecosystems respond to the various characteristics of the short-scale variability of the climate forcing in various ways, depending on dominant factors limiting system productivity; (c) whenever short-scale variability of meteorological forcing influences primarily fast processes such as photosynthesis, its impact on the slow-scale variability of water and carbon fluxes is small; and (d) whenever short-scale variability of the meteorological forcing impacts slow processes such as movement and storage of water in the soil, the effects of the variability can propagate to annual and longer time scales.
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More information
Accepted/In Press date: 4 August 2015
e-pub ahead of print date: 7 August 2015
Published date: September 2015
Keywords:
cross-scale interactions, ecohydrological modeling, ecosystem response, interannual variability, short-scale temporal climate variability, spectral analysis
Organisations:
Water & Environmental Engineering Group
Identifiers
Local EPrints ID: 385303
URI: http://eprints.soton.ac.uk/id/eprint/385303
ISSN: 0148-0227
PURE UUID: 9159e584-8c1e-49f3-a91a-4768648be372
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Date deposited: 18 Jan 2016 16:44
Last modified: 14 Mar 2024 22:14
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Contributors
Author:
Athanasios Paschalis
Author:
Simone Fatichi
Author:
Gabriel G. Katul
Author:
Valeriy Y. Ivanov
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