Abstract
Abstract. Convection as one dominant source of atmospheric gravity waves (GWs) has been the focus of investigation over recent years. However, its spatial and temporal forcing scales are not well known. In this work we address this open issue by a systematic verification of free parameters of the Yonsei convective GW source scheme based on observations from the High Resolution Dynamics Limb Sounder (HIRDLS). The instrument can only see a limited portion of the gravity wave spectrum due to visibility effects and observation geometry. To allow for a meaningful comparison of simulated GWs to observations, a comprehensive filter, which mimics the instrument limitations, is applied to the simulated waves. By this approach, only long horizontal-scale convective GWs are addressed. Results show that spectrum, distribution of momentum flux, and zonal mean forcing of long horizontal-scale convective GWs can be successfully simulated by the superposition of three or four combinations of parameter sets reproducing the observed GW spectrum. These selected parameter sets are different for northern and southern summer. Although long horizontal-scale waves are only part of the full spectrum of convective GWs, the momentum flux of these waves is found to be significant and relevant for the driving of the QBO (quasi-biennial oscillation). The zonal momentum balance is considered in vertical cross sections of GW momentum flux (GWMF) and GW drag (GWD). Global maps of the horizontal distribution of GWMF are considered and consistency between simulated results and HIRDLS observations is found. The latitude dependence of the zonal phase speed spectrum of GWMF and its change with altitude is discussed.
Highlights
Gravity waves (GWs) significantly impact global circulations by accelerating or decelerating the background wind while dissipating or breaking (e.g., McLandress, 1998; McIntyre, 1998; Kim et al, 2003; Alexander et al, 2010)
In this paper we focus on the convective GW source (CGWS) scheme of Song and Chun (2005)
Simulations focus on the year 2006, similar convective regions are observed in different years (e.g. Ern et al, 2006, 2011; Alexander et al, 2008) and the current study aims to determine general characteristics of convective GWs by tuning the parameterization based on observations
Summary
Gravity waves (GWs) significantly impact global circulations by accelerating or decelerating the background wind while dissipating or breaking (e.g., McLandress, 1998; McIntyre, 1998; Kim et al, 2003; Alexander et al, 2010). There is an increasing number of recent studies showing the importance of large-scale convective systems This indicates a need of finding a new larger scale set for the CGWS scheme, which can correctly reproduce the spectrum observed by limb sounders. Simulations focus on the year 2006, similar convective regions are observed in different years (e.g. Ern et al, 2006, 2011; Alexander et al, 2008) and the current study aims to determine general characteristics of convective GWs by tuning the parameterization based on observations. This will be supported by modelmeasurement comparison of 3 consecutive years.
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