Your search keyword '"back-building"' showing total 3 results

1. Dual-Doppler radar analysis of a near-shore line-shaped convective system on 27 July 2011, Korea: a case study

Author

Jung-Tae Lee, Dong-In Lee, Cheol-Hwan You, Hiroshi Uyeda, Yu-Chieng Liou, and In-Seong Han

Subjects

line-shaped convective system, back-building, low-level convergence, nearshore, Oceanography, GC1-1581, Meteorology. Climatology, QC851-999

Abstract

In the summer rainy season, the Korean Peninsula is frequently influenced by severe weather phenomena such as floods and rain-induced landslides. A band-shaped precipitation system associated with unstable atmospheric conditions occurred over northwest Korea on 27 July 2011. This precipitation system produced heavy rainfall over the Seoul metropolitan area, which received over 80 mm h−1 of rainfall and suffered 70 weather-related fatalities. To investigate the precipitation system, we used diverse meteorological data of environmental condition and estimated three-dimensional wind field from dual-Doppler radar measurements of vertical air motion. Environmental conditions included high equivalent potential temperature (θe) of over 355 K at low levels, and low θe of under 330 K at middle levels, causing vertical instability. Furthermore, a pressure trough was located to the northwest of Korea, favouring the development of the band-shaped precipitation system. The tip of the band-shaped precipitation system was made up of line-shaped convective systems (LSCSs) that caused flooding and landslides, and the LSCSs were continuously enhanced by merging between new cells and the pre-existing cell. The position of merging moved from the coast to offshore areas and influenced the positioning of the regions of enhanced convection. In turn, this affected the roughness of the convective cell and the internal structure of the enhanced convective regions. Onshore, the convective area was higher than in offshore areas because of strong convergence (≤−4×10−4 s−1) at low levels caused by friction over land. The strong convergence generated strong updraft (≥4 m s−1) that influenced the height of the convective area. The convective region offshore was wider than that onshore because of weak convergence (≥−2.2×10−4 s−1) at low levels. Updraft in offshore areas was weak (≤3 m s−1) compared with onshore, resulting in a lower and wider convective area. Spatial variations in surface roughness result in different structural features and profiles of divergence within LSCSs, even if they originate in the same convective region.

Published

2014

2. Analysis on the Future Change of Back-building Extreme Rainfall by Pseudo Global Warming Experiment Based on Different Resolutions for 2012 Kameoka Event

Author

OSAKADA, Yukari and NAKAKITA, Eiichi

Subjects

解像度, climate change, resolution, 519.9, back-building, 気候変動, バックビルディング, line-shaped extreme rainfall, 線状降水帯

Abstract

Pseudo global warming experiments (PGW) were conducted with 1000m and 500m horizontal resolution for the 2012 Kameoka extreme rainfall event, which was the type of back-building convection system. As a result, the back-building system was very well represented in both of present and PGW experiments, and the rainfall intensity and total rainfall increased in PGW experiments. This is due to the fact that: in the future, the amount of condensation in cumulonimbus will increase and a convective unstable field will be realized (meso γ ~ β), the back-building structure will be strengthened (meso β), and the convective unstable atmosphere was continuously supplied from the south (meso α). We also showed that the result of 500m resolution can represent the back-building system much better than that of 1000m because 1000m resolution can capture future changes in meso-α, but cannot capture changes smaller than meso-β sufficiently.

Published

2020

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Author

OSAKADA, Yukari, NAKAKITA, Eiichi, 30909445, OSAKADA, Yukari, NAKAKITA, Eiichi, and 30909445

Published

2020