STOCHASTIC MULTICLOUD MODEL
; COMMUNITY ATMOSPHERE MODEL
; DEEP CONVECTION
; PART I
; BOUNDARY-LAYER
; DIURNAL CYCLE
; CLIMATE MODEL
; CUMULUS PARAMETERIZATION
; MICROPHYSICS PARAMETERIZATION
; TROPICAL CONVECTION
WOS学科分类:
Meteorology & Atmospheric Sciences
WOS研究方向:
Meteorology & Atmospheric Sciences
英文摘要:
Purpose of Review While the increase of computer power mobilizes a part of the atmospheric modeling community toward models with explicit convection or based on machine learning, we review the part of the literature dedicated to convective parameterization development for large-scale forecast and climate models.
Recent Findings Many developments are underway to overcome endemic limitations of traditional convective parameterizations, either in unified or multiobject frameworks: scale-aware and stochastic approaches, new prognostic equations or representations of new components such as cold pools. Understanding their impact on the emergent properties of a model remains challenging, due to subsequent tuning of parameters and the limited understanding given by traditional metrics.
Summary Further effort still needs to be dedicated to the representation of the life cycle of convective systems, in particular their mesoscale organization and associated cloud cover. The development of more process-oriented metrics based on new observations is also needed to help quantify model improvement and better understand the mechanisms of climate change.
1.Univ Toulouse, Meteo France, CNRS, Ctr Natl Rech Meteorol, Toulouse, France 2.NASA, Goddard Inst Space Studies, New York, NY 10025 USA 3.Sorbonne Univ, IPSL, CNRS, Lab Meteorol Dynam, Paris, France
Recommended Citation:
Rio, Catherine,Del Genio, Anthony D.,Hourdin, Frederic. Ongoing Breakthroughs in Convective Parameterization[J]. CURRENT CLIMATE CHANGE REPORTS,2019-01-01,5(2):95-111