Coupling terrestrial and atmospheric water dynamics to improve prediction in a changing environment

Steve W. Lyon; Francina Dominguez; David J. Gochis; Nathaniel A. Brunsell; Christopher L. Castro; Fotini K. Chow; Ying Fan; Daniel Fuka; Yang Hong; Paula A. Kucera; Stephen W. Nesbitt; Nadine Salzmann; Juerg Schmidli; Peter K. Synder; Adriaan J. Teuling; Tracye E. Twine; Samuel Levis; Jessica D. Lundquist; Guido D. Salvucci; Andrea M. Sealy; M. Todd Walter

doi:10.1175/2008BAMS2547.1

Coupling terrestrial and atmospheric water dynamics to improve prediction in a changing environment

Steve W. Lyon, Francina Dominguez, David J. Gochis, Nathaniel A. Brunsell, Christopher L. Castro, Fotini K. Chow, Ying Fan, Daniel Fuka, Yang Hong, Paula A. Kucera, Stephen W. Nesbitt, Nadine Salzmann, Juerg Schmidli, Peter K. Synder, Adriaan J. Teuling, Tracye E. Twine, Samuel Levis, Jessica D. Lundquist, Guido D. Salvucci, Andrea M. SealyM. Todd Walter

Soil, Water, and Climate

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16 Scopus citations

Abstract

Atmospheric scientists see a potential in the improvement of climate prediction by coupling terrestrial and atmospheric water dynamics. This is also important to understand local processes such as evapotranspiration and streamflow. Simplifications in numerical models that pertain to terrestrial hydrology must also be addressed because such simplifications can limit the numerical prediction capabilities with respect to how water partition capabilities with respect to how water partitions itself throughout all phases of the cycle. When simplifications have been addressed, understanding the feedback interactions between the land surface and the atmosphere can be done by defining improved feedback metrics for assessing the relative magnitude of soil moisture, vegetation, and snow feedbacks on the atmosphere. There will also be a need on models as groundwater flow, unsaturated zone subsurface flow, atmospheric flow, vegetation dynamics, and landsurface modules that link below and above-ground hydrologic and biogeochemical regimes.

Original language	English (US)
Pages (from-to)	1275-1279
Number of pages	5
Journal	Bulletin of the American Meteorological Society
Volume	89
Issue number	9
DOIs	https://doi.org/10.1175/2008BAMS2547.1
State	Published - Sep 2008

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Lyon, S. W., Dominguez, F., Gochis, D. J., Brunsell, N. A., Castro, C. L., Chow, F. K., Fan, Y., Fuka, D., Hong, Y., Kucera, P. A., Nesbitt, S. W., Salzmann, N., Schmidli, J., Synder, P. K., Teuling, A. J., Twine, T. E., Levis, S., Lundquist, J. D., Salvucci, G. D., ... Walter, M. T. (2008). Coupling terrestrial and atmospheric water dynamics to improve prediction in a changing environment. Bulletin of the American Meteorological Society, 89(9), 1275-1279. https://doi.org/10.1175/2008BAMS2547.1

Lyon, SW, Dominguez, F, Gochis, DJ, Brunsell, NA, Castro, CL, Chow, FK, Fan, Y, Fuka, D, Hong, Y, Kucera, PA, Nesbitt, SW, Salzmann, N, Schmidli, J, Synder, PK, Teuling, AJ, Twine, TE, Levis, S, Lundquist, JD, Salvucci, GD, Sealy, AM & Walter, MT 2008, 'Coupling terrestrial and atmospheric water dynamics to improve prediction in a changing environment', Bulletin of the American Meteorological Society, vol. 89, no. 9, pp. 1275-1279. https://doi.org/10.1175/2008BAMS2547.1

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abstract = "Atmospheric scientists see a potential in the improvement of climate prediction by coupling terrestrial and atmospheric water dynamics. This is also important to understand local processes such as evapotranspiration and streamflow. Simplifications in numerical models that pertain to terrestrial hydrology must also be addressed because such simplifications can limit the numerical prediction capabilities with respect to how water partition capabilities with respect to how water partitions itself throughout all phases of the cycle. When simplifications have been addressed, understanding the feedback interactions between the land surface and the atmosphere can be done by defining improved feedback metrics for assessing the relative magnitude of soil moisture, vegetation, and snow feedbacks on the atmosphere. There will also be a need on models as groundwater flow, unsaturated zone subsurface flow, atmospheric flow, vegetation dynamics, and landsurface modules that link below and above-ground hydrologic and biogeochemical regimes.",

author = "Lyon, {Steve W.} and Francina Dominguez and Gochis, {David J.} and Brunsell, {Nathaniel A.} and Castro, {Christopher L.} and Chow, {Fotini K.} and Ying Fan and Daniel Fuka and Yang Hong and Kucera, {Paula A.} and Nesbitt, {Stephen W.} and Nadine Salzmann and Juerg Schmidli and Synder, {Peter K.} and Teuling, {Adriaan J.} and Twine, {Tracye E.} and Samuel Levis and Lundquist, {Jessica D.} and Salvucci, {Guido D.} and Sealy, {Andrea M.} and Walter, {M. Todd}",

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AU - Synder, Peter K.

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AU - Twine, Tracye E.

AU - Levis, Samuel

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AU - Salvucci, Guido D.

AU - Sealy, Andrea M.

AU - Walter, M. Todd

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AB - Atmospheric scientists see a potential in the improvement of climate prediction by coupling terrestrial and atmospheric water dynamics. This is also important to understand local processes such as evapotranspiration and streamflow. Simplifications in numerical models that pertain to terrestrial hydrology must also be addressed because such simplifications can limit the numerical prediction capabilities with respect to how water partition capabilities with respect to how water partitions itself throughout all phases of the cycle. When simplifications have been addressed, understanding the feedback interactions between the land surface and the atmosphere can be done by defining improved feedback metrics for assessing the relative magnitude of soil moisture, vegetation, and snow feedbacks on the atmosphere. There will also be a need on models as groundwater flow, unsaturated zone subsurface flow, atmospheric flow, vegetation dynamics, and landsurface modules that link below and above-ground hydrologic and biogeochemical regimes.

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Coupling terrestrial and atmospheric water dynamics to improve prediction in a changing environment

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