IGSNRR OpenIR
Subdaily to Seasonal Change of Surface Energy and Water Flux of the Haihe River Basin in China: Noah and Noah-MP Assessment
Yang, Fuqiang1,2; Dan, Li1; Peng, Jing1; Yang, Xiujing1,2; Li, Yueyue2,3; Gao, Dongdong4
2019
Source PublicationADVANCES IN ATMOSPHERIC SCIENCES
ISSN0256-1530
Volume36Issue:1Pages:79-92
Corresponding AuthorDan, Li(danli@tea.ac.cn)
AbstractThe land surface processes of the Noah-MP and Noah models are evaluated over four typical landscapes in the Haihe River Basin (HRB) using in-situ observations. The simulated soil temperature and moisture in the two land surface models (LSMs) is consistent with the observation, especially in the rainy season. The models reproduce the mean values and seasonality of the energy fluxes of the croplands, despite the obvious underestimated total evaporation. Noah shows the lower deep soil temperature. The net radiation is well simulated for the diurnal time scale. The daytime latent heat fluxes are always underestimated, while the sensible heat fluxes are overestimated to some degree. Compared with Noah, Noah-MP has improved daily average soil heat flux with diurnal variations. Generally, Noah-MP performs fairly well for different landscapes of the HRB. The simulated cold bias in soil temperature is possibly linked with the parameterized partition of the energy into surface fluxes. Thus, further improvement of these LSMs remains a major challenge.
Keywordland surface model Haihe River Basin soil temperature soil moisture surface energy flux seasonal cycle
DOI10.1007/s00376-018-8035-4
WOS KeywordMODEL SIMULATIONS ; CARBON FLUX ; EVAPOTRANSPIRATION ; PARAMETERIZATION ; IMPLEMENTATION ; AMAZONIA ; IMPACTS ; SITES ; STATE
Indexed BySCI
Language英语
Funding ProjectNational Key Research and Development Program of China[2016YFA0602501] ; National Natural Science Foundation of China[41630532] ; National Natural Science Foundation of China[41575093]
Funding OrganizationNational Key Research and Development Program of China ; National Natural Science Foundation of China
WOS Research AreaMeteorology & Atmospheric Sciences
WOS SubjectMeteorology & Atmospheric Sciences
WOS IDWOS:000449963000007
PublisherSCIENCE PRESS
Citation statistics
Document Type期刊论文
Identifierhttp://ir.igsnrr.ac.cn/handle/311030/52461
Collection中国科学院地理科学与资源研究所
Corresponding AuthorDan, Li
Affiliation1.Chinese Acad Sci, Inst Atmospher Phys, Key Lab Reg Climate Environm Temperate East Asia, Beijing 100029, Peoples R China
2.Univ Chinese Acad Sci, Beijing 100049, Peoples R China
3.Chinese Acad Sci, Inst Geog Sci & Nat Resources Res, Beijing 100101, Peoples R China
4.Chengdu Univ Informat Technol, Sch Atmospher Sci, Chengdu 610225, Sichuan, Peoples R China
Recommended Citation
GB/T 7714
Yang, Fuqiang,Dan, Li,Peng, Jing,et al. Subdaily to Seasonal Change of Surface Energy and Water Flux of the Haihe River Basin in China: Noah and Noah-MP Assessment[J]. ADVANCES IN ATMOSPHERIC SCIENCES,2019,36(1):79-92.
APA Yang, Fuqiang,Dan, Li,Peng, Jing,Yang, Xiujing,Li, Yueyue,&Gao, Dongdong.(2019).Subdaily to Seasonal Change of Surface Energy and Water Flux of the Haihe River Basin in China: Noah and Noah-MP Assessment.ADVANCES IN ATMOSPHERIC SCIENCES,36(1),79-92.
MLA Yang, Fuqiang,et al."Subdaily to Seasonal Change of Surface Energy and Water Flux of the Haihe River Basin in China: Noah and Noah-MP Assessment".ADVANCES IN ATMOSPHERIC SCIENCES 36.1(2019):79-92.
Files in This Item:
There are no files associated with this item.
Related Services
Recommend this item
Bookmark
Usage statistics
Export to Endnote
Google Scholar
Similar articles in Google Scholar
[Yang, Fuqiang]'s Articles
[Dan, Li]'s Articles
[Peng, Jing]'s Articles
Baidu academic
Similar articles in Baidu academic
[Yang, Fuqiang]'s Articles
[Dan, Li]'s Articles
[Peng, Jing]'s Articles
Bing Scholar
Similar articles in Bing Scholar
[Yang, Fuqiang]'s Articles
[Dan, Li]'s Articles
[Peng, Jing]'s Articles
Terms of Use
No data!
Social Bookmark/Share
All comments (0)
No comment.
 

Items in the repository are protected by copyright, with all rights reserved, unless otherwise indicated.