Impacts of local topography on snowfall distribution in the Kanto Plain: A case study

IF 1.7 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Sola Pub Date : 2024-09-04 DOI:10.2151/sola.2024-043

Hiroaki Kawase, Takahiro Ito, Yukiko Sakamoto, Yuya Takane

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Abstract

On February 5, 2024, an extratropical cyclone passing the south coast of Japan brought 8 cm of snow to Tokyo, while in Tsukuba, located about 50 km from Tokyo, the snow cover was 0 cm. We investigated the mechanism generating the inhomogeneous distribution of snow cover using a numerical weather model with 1 km grid spacings. Our numerical simulation shows that a coastal front is located on the eastern coast of the Kanto Plain. On the other hand, a relatively warm area broadly spreads from the leeward side of mountainous areas including Mt. Tsukuba. A strong downward flow related to a gravity wave caused by the mountainous area brings adiabatic warming on the leeward side of the mountains. This adiabatic heating accelerates snowfall melting at the low troposphere, and the melting layer is higher on the leeward side of the mountains. Also, the adiabatic heating reduces relative humidity and decreases total precipitation amount. As a result, there is much less snowfall on the leeward side of the mountainous areas, including Tsukuba observational station, as compared with neighboring areas. A numerical simulation with 5 km grid spacings cannot simulate the local-scale snowfall distribution around the mountainous areas.

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当地地形对关东平原降雪分布的影响：案例研究

2024 年 2 月 5 日，一个经过日本南海岸的副热带气旋给东京带来了 8 厘米的积雪，而在距离东京约 50 公里的筑波，积雪覆盖率为 0 厘米。我们利用网格间距为 1 千米的数值天气模型，研究了造成积雪不均匀分布的机制。我们的数值模拟结果表明，关东平原的东海岸有沿海锋。另一方面，一个相对温暖的区域从包括筑波山在内的山区背风面广泛扩散。与山区引起的重力波有关的强大下行气流使山区背风面绝热升温。这种绝热升温加速了对流层低层的降雪融化，而山脉背风面的融化层较高。同时，绝热加热降低了相对湿度，减少了降水总量。因此，与邻近地区相比，包括筑波观测站在内的山区背风面降雪量要少得多。5 千米网格间距的数值模拟无法模拟山区周围局部范围的降雪分布。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Sola 地学-气象与大气科学

CiteScore

3.50

自引率

21.10%

发文量

审稿时长

>12 weeks

期刊介绍： SOLA (Scientific Online Letters on the Atmosphere) is a peer-reviewed, Open Access, online-only journal. It publishes scientific discoveries and advances in understanding in meteorology, climatology, the atmospheric sciences and related interdisciplinary areas. SOLA focuses on presenting new and scientifically rigorous observations, experiments, data analyses, numerical modeling, data assimilation, and technical developments as quickly as possible. It achieves this via rapid peer review and publication of research letters, published as Regular Articles. Published and supported by the Meteorological Society of Japan, the journal follows strong research and publication ethics principles. Most manuscripts receive a first decision within one month and a decision upon resubmission within a further month. Accepted articles are then quickly published on the journal’s website, where they are easily accessible to our broad audience.