Role of Land–Atmosphere Interaction in the 2016 Northeast Asia Heat Wave: Impact of Soil Moisture Initialization

The impact of soil moisture initialization on the 2016 Northeast Asian heat wave was explored using the Land Information System (LIS) Weather Research and Forecasting (WRF) model. To obtain advanced soil moisture estimates, various meteorological variables from the Global Data Assimilation System an...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2023-01, Vol.128 (2), p.n/a
Main Authors: Yoon, Donghyuck, Kang, Taehun, Cha, Dong‐Hyun, Song, Chang‐Keun, Lee, Myong‐In, Min, Ki‐Hong, Kim, Joowan, Chun, Jong Ahn, Seo, Eunkyo
Format: Article
Language:English
Subjects:
Active satellites
Air temperature
Atmosphere
Cytotoxicity
Data assimilation
Data collection
Dynamic height
Estimates
Experiments
Extreme heat
Extreme high temperatures
Geophysics
Geopotential
Geopotential height
Global precipitation
Heat
Heat flux
Heat transfer
heat wave
Heat waves
Information systems
Land information systems
Land surface models
land–atmosphere interaction
Latent heat
Latent heat flux
Lymphocytes T
Modelling
Moisture effects
Numerical experiments
Passive satellites
Satellite data
Satellite observation
Satellites
Simulation
Soil
Soil moisture
soil moisture initialization
Soil temperature
Surface temperature
Surface-air temperature relationships
Systems analysis
Temperature
Weather forecasting
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Summary:The impact of soil moisture initialization on the 2016 Northeast Asian heat wave was explored using the Land Information System (LIS) Weather Research and Forecasting (WRF) model. To obtain advanced soil moisture estimates, various meteorological variables from the Global Data Assimilation System analysis and Integrated Multi‐Satellite Retrievals for Global Precipitation Measurement observation data were used as atmospheric forcings for the offline simulation of the Noah land surface model (Noah‐LSM). Based on the LIS, Soil Moisture Active Passive satellite were assimilated in the Noah LSM simulation. The assimilated soil moisture estimates revealed the drier land surface conditions over Northeast Asia compared with the product from the National Centers for Environmental Prediction Final Analysis (FNL) and were used as the initial condition of the WRF model. The WRF experiment initialized by the assimilated soil moisture product (LIS experiment) exhibited the observed surface air temperature (SAT) and 500 hPa geopotential height (500 GPH) over Northeast Asia compared with the result from the experiment initialized by the FNL (CTL experiment). At Week 1, the LIS experiment simulated warmer SAT than that from the CTL experiment, which was induced by the negative anomaly of latent heat flux over Mongolia. Then, 500 GPH became strong and spatially expanded in response to the thermal low induced by the warmer SAT, and the SAT was further increased during Weeks 2 and 3. Plain Language Summary The association between soil moisture and land–atmosphere interaction occurring in the East Asia were analyzed by focusing on the 2016 extreme heat wave case. The numerical experiment with the initial soil moisture from the fusion of satellite data and land surface model output simulated a more realistic land–atmosphere interaction over East Asia within a 3‐week heat wave simulation period, compared to the experiment with the operational soil moisture product. Key Points The soil moisture estimates assimilated by Soil Moisture Active Passive onto the offline land surface model were initialized in the Weather Research and Forecasting model Advanced soil moisture initialization represented the observed land–atmosphere interaction in the 2016 Northeast Asia heat wave
ISSN:2169-897X
2169-8996
DOI:10.1029/2022JD037718