Impacts of Topography on Airflow and Precipitation in the Pyeongchang Area Seen from Multiple-Doppler Radar Observations

This study uses high-resolution radar and surface observations to investigate the finescale structural evolution of airflow and precipitation over complex terrain in the Pyeongchang area, South Korea. The Taebaek Mountain range (TMR) runs parallel to the northeastern coast of South Korea, with a per...

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Bibliographic Details
Published in:Monthly weather review 2018-10, Vol.146 (10), p.3401-3424
Main Authors: Tsai, Chia-Lun, Kim, Kwonil, Liou, Yu-Chieng, Lee, Gyuwon, Yu, Cheng-Ku
Format: Article
Language:English
Subjects:
Advection
Air flow
Astronomy
Atmospheric sciences
Climate
Coastal zone
Coasts
Deceleration
Doppler radar
Doppler radar observation
Doppler sonar
Easterlies
Environmental conditions
Evolution
Heavy precipitation
Lee waves
Low pressure
Low pressure systems
Mountain waves
Offshore
Olympic games
PCB
Physiographic features
Polychlorinated biphenyls
Precipitation
Radar
Rain
Remote sensing
Snow
Topography
Topography (geology)
Weather
Wind
Winds
Winter sports
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Summary:This study uses high-resolution radar and surface observations to investigate the finescale structural evolution of airflow and precipitation over complex terrain in the Pyeongchang area, South Korea. The Taebaek Mountain range (TMR) runs parallel to the northeastern coast of South Korea, with a perpendicular ridge known as the Pyeongchang branch (PCB). The objective of this study was to identify the mechanisms of wintertime precipitation over these topographic features during the passage of a low pressure system (LPS) through the southern Korean Peninsula. The analysis indicates that intense precipitation occurred over the southwestern and northeastern sides of the TMR during stage I but only over the northeastern side during stage II. The prevailing southwesterly winds were dominated by warm advection associated with the LPS over the PCB during stage I. These prevailing southwesterly winds locally enhanced precipitation on the southwestern end of the PCB; multiple influences of mountain waves, airflow convergence, and drifted particles are possible factors for causing precipitation on the northeastern side of the TMR. During stage II, the prevailing winds changed from easterlies to northeasterlies offshore from Gangneung. The easterly winds decelerated and were deflected locally along the mountainous coast, and this blocked zone interacted with the oncoming flow to trigger a precipitation band. Consequently, the northeasterly winds helped push the precipitation band toward the coast, causing heavy precipitation in Gangneung. The observational evidence presented shows that the interaction of temporally changing winds accompanying the movement of an LPS over topography is a critical factor for determining the distribution and intensity of precipitation.
ISSN:0027-0644
1520-0493
DOI:10.1175/MWR-D-17-0394.1