Abstract
Abstract. Subseasonal-to-seasonal (S2S) prediction, especially the prediction of extreme hydroclimate events such as droughts and floods, is not only scientifically challenging, but also has substantial societal impacts. Motivated by preliminary studies, the Global Energy and Water Exchanges (GEWEX)/Global Atmospheric System Study (GASS) has launched a new initiative called “Impact of Initialized Land Surface Temperature and Snowpack on Subseasonal to Seasonal Prediction” (LS4P) as the first international grass-roots effort to introduce spring land surface temperature (LST)/subsurface temperature (SUBT) anomalies over high mountain areas as a crucial factor that can lead to significant improvement in precipitation prediction through the remote effects of land–atmosphere interactions. LS4P focuses on process understanding and predictability, and hence it is different from, and complements, other international projects that focus on the operational S2S prediction. More than 40 groups worldwide have participated in this effort, including 21 Earth system models, 9 regional climate models, and 7 data groups. This paper provides an overview of the history and objectives of LS4P, provides the first-phase experimental protocol (LS4P-I) which focuses on the remote effect of the Tibetan Plateau, discusses the LST/SUBT initialization, and presents the preliminary results. Multi-model ensemble experiments and analyses of observational data have revealed that the hydroclimatic effect of the spring LST on the Tibetan Plateau is not limited to the Yangtze River basin but may have a significant large-scale impact on summer precipitation beyond East Asia and its S2S prediction. Preliminary studies and analysis have also shown that LS4P models are unable to preserve the initialized LST anomalies in producing the observed anomalies largely for two main reasons: (i) inadequacies in the land models arising from total soil depths which are too shallow and the use of simplified parameterizations, which both tend to limit the soil memory; (ii) reanalysis data, which are used for initial conditions, have large discrepancies from the observed mean state and anomalies of LST over the Tibetan Plateau. Innovative approaches have been developed to largely overcome these problems.
Highlights
Subseasonal-to-seasonal (S2S) prediction, especially the prediction of extreme hydroclimatic events such as droughts and floods, is scientifically challenging, and has substantial societal impacts since such phenomena can have serious agricultural, economic, and ecological consequences (Merryfield et al, 2020)
The possible remote effects of large-scale spring land surface/subsurface temperature (LST/SUBT) anomalies in geographical areas upstream of the areas which experience late spring–summer drought/flood, an underappreciated relation, were largely ignored until recent preliminary modeling and data analysis studies revealed the important role of high mountain land surface temperature (LST)/SUBT in S2S predictability: this discovery has stimulated research in this direction
There are large amounts of observational data available in the Tibetan Plateau area, which are produced by the data groups, which are participating in LS4P and are available for the community to conduct further LS4P-related research, such as studying the causes of the LST/SUBT anomalies, the characteristics of the surface and atmospheric processes in the Tibetan Plateau, etc
Summary
Subseasonal-to-seasonal (S2S) prediction, especially the prediction of extreme hydroclimatic events such as droughts and floods, is scientifically challenging, and has substantial societal impacts since such phenomena can have serious agricultural, economic, and ecological consequences (Merryfield et al, 2020). The possible remote (nonlocal) effects of large-scale spring land surface/subsurface temperature (LST/SUBT) anomalies in geographical areas upstream of the areas which experience late spring–summer drought/flood, an underappreciated relation, were largely ignored until recent preliminary modeling and data analysis studies revealed the important role of high mountain LST/SUBT in S2S predictability: this discovery has stimulated research in this direction. There are large amounts of observational data available in the Tibetan Plateau area, which are produced by the data groups, which are participating in LS4P and are available for the community to conduct further LS4P-related research, such as studying the causes of the LST/SUBT anomalies, the characteristics of the surface and atmospheric processes in the Tibetan Plateau, etc. This data set consists of surface skin temperature, albedo, emissivity, surface radiation components and vegetation conditions (http://www.glass.umd.edu, last access: 1 June 2021)
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