Jung Hee Ryu scite author profile

The relationship between local convection, vertically propagating Kelvin waves, and tropical tropopause height variability is examined. This study utilizes both simulations of a global primitive-equation model and global observational datasets. Regression analysis with the data shows that convection over the western tropical Pacific is followed by warming in the upper troposphere (UT) and cooling in lower stratosphere (LS) over most longitudes, which results in a lifting of the tropical tropopause. The model results reveal that these UT-LS temperature anomalies are closely associated with vertically propagating Kelvin waves, indicating that these Kelvin waves drive tropical tropopause undulations at intraseasonal time scales.The model simulations further show that regardless of the longitudinal position of the imposed heating, the UT-LS Kelvin wave reaches its maximum amplitude over the western Pacific. This result, together with an analysis based on wave action conservation, is used to contend that the Kelvin wave amplification over the western Pacific should be attributed to the zonal variation of background zonal wind field, rather than to the proximity of the heating. The wave action conservation law is also used to offer an explanation as to why the vertically propagating Kelvin waves play the central role in driving tropical tropopause height undulations.The zonal and vertical modulation of the Kelvin waves by the background flow may help explain the origin of the very cold air over the western tropical Pacific, which is known to cause freeze-drying of tropospheric air en route to the stratosphere.

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Response of moist convection to multi‐scale surface flux heterogeneity

Kang

Ryu

2016

Quart J Royal Meteoro Soc

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We investigate the response of moist convection to the spatial variation of surface sensible heat flux (SHF) in a mesoscale domain during the evolution of the afternoon convective boundary layer (CBL), using large-eddy simulation. The surface SHF heterogeneity in the domain is analytically created as a function of the spectral slope in the wavelength range from a few tens of kilometres to a few hundreds of metres in the SHF spectrum on a log-log scale. Assuming surface energy balance and spatially uniform available energy, the prescribed SHF has a phase lag of 180• with respect to the latent heat flux (LHF) in the domain. Two sets of three simulations are forced by heterogeneous surface SHF fields, which are characterized by similar statistics. One set, however, is created with a spectral slope of k −3 (where k is wave number) and the other with a slope of k −2 . All of the simulations are integrated with the same observation-based initial sounding favourable for moist convection.In all of the k

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Space-borne observations link the tropical atlantic ozone maximum and paradox to lightning

Jenkins

Ryu

2004

Atmos. Chem. Phys.

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Jung Hee Ryu

Understanding the sources of Caribbean precipitation biases in CMIP3 and CMIP5 simulations

Vertically Propagating Kelvin Waves and Tropical Tropopause Variability

Response of moist convection to multi‐scale surface flux heterogeneity

Space-borne observations link the tropical atlantic ozone maximum and paradox to lightning

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