%0 Journal Article %1 Harper_2010 %A Harper, Anna B. %A Denning, A. Scott %A Baker, Ian T. %A Branson, Mark D. %A Prihodko, Lara %A Randall, David A. %D 2010 %I American Geophysical Union (AGU) %J Geophysical Research Letters %K brazil k83 %N 5 %P n/a--n/a %R 10.1029/2009gl042302 %T Role of deep soil moisture in modulating climate in the Amazon rainforest %U https://doi.org/10.1029%2F2009gl042302 %V 37 %X Both local and large‐scale processes affect the Amazon hydrologic cycle. We investigate the impact of deep soils on the atmosphere through local feedbacks. The Simple Biosphere model, version 3 (SiB3), is coupled to a single column model. Historically, land surface schemes parameterize soil moisture stress based on shallow soils and incorrectly capture seasonal cycles in the Amazon. Following observations, SiB3 is updated to allow deep roots to access soil moisture at depth. The new (“Unstressed”) version of SiB3 has a stronger hydrologic cycle, with increased evapotranspiration and moisture export during the dry season. The boundary layer responds through changes in its depth, relative humidity, and turbulent kinetic energy, and these changes feed back to influence wet season onset and intensity. Differences in atmospheric latent heating could affect circulation in a global model. The results have important consequences for modeling the Amazon hydrologic cycle and climate in global climate models.

@article{Harper_2010, abstract = {Both local and large‐scale processes affect the Amazon hydrologic cycle. We investigate the impact of deep soils on the atmosphere through local feedbacks. The Simple Biosphere model, version 3 (SiB3), is coupled to a single column model. Historically, land surface schemes parameterize soil moisture stress based on shallow soils and incorrectly capture seasonal cycles in the Amazon. Following observations, SiB3 is updated to allow deep roots to access soil moisture at depth. The new (“Unstressed”) version of SiB3 has a stronger hydrologic cycle, with increased evapotranspiration and moisture export during the dry season. The boundary layer responds through changes in its depth, relative humidity, and turbulent kinetic energy, and these changes feed back to influence wet season onset and intensity. Differences in atmospheric latent heating could affect circulation in a global model. The results have important consequences for modeling the Amazon hydrologic cycle and climate in global climate models.}, added-at = {2019-09-04T16:05:52.000+0200}, author = {Harper, Anna B. and Denning, A. Scott and Baker, Ian T. and Branson, Mark D. and Prihodko, Lara and Randall, David A.}, biburl = {https://www.bibsonomy.org/bibtex/2c4882b58156be82892501b81098a59ce/karinawilliams}, doi = {10.1029/2009gl042302}, interhash = {fc7f1d90a2c820e34e3228681cd038cc}, intrahash = {c4882b58156be82892501b81098a59ce}, journal = {Geophysical Research Letters}, keywords = {brazil k83}, month = mar, number = 5, pages = {n/a--n/a}, publisher = {American Geophysical Union ({AGU})}, timestamp = {2019-09-04T16:05:52.000+0200}, title = {Role of deep soil moisture in modulating climate in the Amazon rainforest}, url = {https://doi.org/10.1029%2F2009gl042302}, volume = 37, year = 2010 }