A new stable boundary‐layer mixing scheme and its impact on the simulated East Asian summer monsoon

This paper investigates the impact of stable boundary‐layer (SBL) mixing in a vertical diffusion package on the simulated climatology in a regional model. In contrast to previous studies, we focus on the sensitivity of the simulated climatology to the representation of SBL processes in the modelled...

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Published inQuarterly journal of the Royal Meteorological Society Vol. 136; no. 651; pp. 1481 - 1496
Main Author Hong, Song‐You
Format Journal Article
LanguageEnglish
Published Chichester, UK John Wiley & Sons, Ltd 01.07.2010
Wiley
Subjects
Boundaries
Climatology
Computer simulation
Earth, ocean, space
Exact sciences and technology
External geophysics
Marine
Mathematical models
Meteorology
Moisture
Monsoons
PBL scheme
Physics of the high neutral atmosphere
planetary boundary layer
Precipitation
precipitation interaction
Simulation
stable boundary layer
Temperature distribution
Climatology
models
atmospheric precipitation
sensitivity analysis
Surface layer
Regional scope
East Asia
troposphere
Summer monsoon
Convergence
Interannual variation
feedback
PBL scheme
Stable boundary layer
Short range forecast
Atmospheric boundary layer
precipitation interaction
Richardson number
seasonal variations
planetary boundary layer
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Abstract This paper investigates the impact of stable boundary‐layer (SBL) mixing in a vertical diffusion package on the simulated climatology in a regional model. In contrast to previous studies, we focus on the sensitivity of the simulated climatology to the representation of SBL processes in the modelled atmosphere, paying particular attention to precipitation and associated large‐scale patterns. The new SBL scheme, based on the bulk Richardson number between the surface layer and the top of the boundary layer and implemented in the Yonsei University (YSU) boundary‐layer scheme, was evaluated against the local scheme in which the mixing coefficient is a function of the local Richardson number at a given model level. A statistical evaluation of a series of short‐range forecast confirms that the boundary‐layer structure is closer to the radiosonde observation when the new SBL scheme is used. In a regional climate framework, the results with the new SBL scheme in July 2006 demonstrate that modulating the subcloud structure with enhanced vertical mixing improves the simulated monsoon climatology by displacing the monsoonal precipitation southwards. Together with the local effects of the enhanced SBL mixing that warms and dries the boundary layer, the dynamical feedbacks accompanying strengthened moisture convergence results in enhanced precipitation towards what was observed. A ten‐member ensemble of three‐month June–July–August simulations for 1999–2008 shows that the revised SBL scheme improves the temperature and moisture profiles in the lower troposphere as well as the precipitation climatology. The interannual variation of seasonal precipitation is more realistic over both land and oceans. Copyright © 2010 Royal Meteorological Society
AbstractList This paper investigates the impact of stable boundary‐layer (SBL) mixing in a vertical diffusion package on the simulated climatology in a regional model. In contrast to previous studies, we focus on the sensitivity of the simulated climatology to the representation of SBL processes in the modelled atmosphere, paying particular attention to precipitation and associated large‐scale patterns. The new SBL scheme, based on the bulk Richardson number between the surface layer and the top of the boundary layer and implemented in the Yonsei University (YSU) boundary‐layer scheme, was evaluated against the local scheme in which the mixing coefficient is a function of the local Richardson number at a given model level. A statistical evaluation of a series of short‐range forecast confirms that the boundary‐layer structure is closer to the radiosonde observation when the new SBL scheme is used. In a regional climate framework, the results with the new SBL scheme in July 2006 demonstrate that modulating the subcloud structure with enhanced vertical mixing improves the simulated monsoon climatology by displacing the monsoonal precipitation southwards. Together with the local effects of the enhanced SBL mixing that warms and dries the boundary layer, the dynamical feedbacks accompanying strengthened moisture convergence results in enhanced precipitation towards what was observed. A ten‐member ensemble of three‐month June–July–August simulations for 1999–2008 shows that the revised SBL scheme improves the temperature and moisture profiles in the lower troposphere as well as the precipitation climatology. The interannual variation of seasonal precipitation is more realistic over both land and oceans. Copyright © 2010 Royal Meteorological Society
This paper investigates the impact of stable boundary-layer (SBL) mixing in a vertical diffusion package on the simulated climatology in a regional model. In contrast to previous studies, we focus on the sensitivity of the simulated climatology to the representation of SBL processes in the modelled atmosphere, paying particular attention to precipitation and associated large-scale patterns. The new SBL scheme, based on the bulk Richardson number between the surface layer and the top of the boundary layer and implemented in the Yonsei University (YSU) boundary-layer scheme, was evaluated against the local scheme in which the mixing coefficient is a function of the local Richardson number at a given model level. A statistical evaluation of a series of short-range forecast confirms that the boundary-layer structure is closer to the radiosonde observation when the new SBL scheme is used. In a regional climate framework, the results with the new SBL scheme in July 2006 demonstrate that modulating the subcloud structure with enhanced vertical mixing improves the simulated monsoon climatology by displacing the monsoonal precipitation southwards. Together with the local effects of the enhanced SBL mixing that warms and dries the boundary layer, the dynamical feedbacks accompanying strengthened moisture convergence results in enhanced precipitation towards what was observed. A ten-member ensemble of three-month June-July-August simulations for 1999-2008 shows that the revised SBL scheme improves the temperature and moisture profiles in the lower troposphere as well as the precipitation climatology. The interannual variation of seasonal precipitation is more realistic over both land and oceans.
Author Hong, Song‐You
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IsPeerReviewed true
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Issue 651
Keywords Temperature distribution
Climatology
models
atmospheric precipitation
sensitivity analysis
Surface layer
Regional scope
East Asia
troposphere
Summer monsoon
Convergence
Interannual variation
feedback
PBL scheme
Stable boundary layer
Short range forecast
Atmospheric boundary layer
precipitation interaction
Richardson number
seasonal variations
planetary boundary layer
Language English
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Wiley
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2006; 119
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1986; 37
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1999; 88
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2006
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1993; 6
2004; 132
1990; 118
2009; 36
2003; 107
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2000; 128
1997; 78
2007; 8
2008; 47
1999; 12
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1998; 1
2008; 136
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1994; 7
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Snippet This paper investigates the impact of stable boundary‐layer (SBL) mixing in a vertical diffusion package on the simulated climatology in a regional model. In...
This paper investigates the impact of stable boundary-layer (SBL) mixing in a vertical diffusion package on the simulated climatology in a regional model. In...
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SubjectTerms Boundaries
Climatology
Computer simulation
Earth, ocean, space
Exact sciences and technology
External geophysics
Marine
Mathematical models
Meteorology
Moisture
Monsoons
PBL scheme
Physics of the high neutral atmosphere
planetary boundary layer
Precipitation
precipitation interaction
Simulation
stable boundary layer
Title A new stable boundary‐layer mixing scheme and its impact on the simulated East Asian summer monsoon
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fqj.665
https://www.proquest.com/docview/883042460
Volume 136
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