Quantitative evaluation of graupel shape observed by new particle imaging radiosonde, Rainscope – A case study of a convective cloud on 25 June, 2022

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

Sola Pub Date : 2024-05-10 DOI:10.2151/sola.2024-025

Yurika Hara, Kenji Suzuki, Tetsuya Kawano

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引用次数: 0

Abstract

In this study, we quantitatively evaluated the shape and fall velocity of precipitation particles in convective clouds observed by Rainscope to better understand graupel formation processes. Rainscope is a newly developed particle imaging radiosonde that provides much clearer precipitation particle images than those obtained by a conventional videosonde. In addition, it can measure particle fall velocities in clouds. Rainscope was launched into a convective cloud with active lightning and gusts on 25 June, 2022. The particle images captured by Rainscope provide detailed information on particle shapes, surface conditions, and contours, facilitating the quantitative evaluation of particle shape. The observed circularity, defined as a function of the particle circumference, and aspect ratio* indicate that graupel just above the freezing level, which coexisted with frozen particles, differs from graupel with an ice crystal as an embryo. The particle fall velocity of graupel in the lower layer was smaller than that of frozen particles and larger than that of general graupel, which forms from an ice crystal. Therefore, graupel in the lower layer likely originated from a frozen particle, which was formed by freezing a raindrop lifted by updrafts and then rimed.

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新型粒子成像雷达探测仪 Rainscope 观测到的灰砾形状的定量评估 - 2022 年 6 月 25 日对流云的案例研究

在这项研究中，我们定量评估了利用 Rainscope 观测到的对流云中降水粒子的形状和下落速度，以便更好地了解灰凝胶的形成过程。Rainscope 是一种新开发的粒子成像辐射计，与传统的视频探空仪相比，它能提供更清晰的降水粒子图像。此外，它还可以测量云中颗粒的下落速度。2022 年 6 月 25 日，Rainscope 被发射到带有活跃闪电和阵风的对流云中。Rainscope 拍摄的粒子图像提供了有关粒子形状、表面状况和轮廓的详细信息，有助于对粒子形状进行定量评估。观测到的圆度（定义为颗粒周长的函数）和长宽比*表明，刚刚超过冰冻水平的颗粒与冰冻颗粒共存，与以冰晶为胚胎的颗粒不同。下层石榴石的颗粒下落速度小于冰冻颗粒，而大于由冰晶形成的一般石榴石。因此，下层的石榴石很可能是由冰冻颗粒形成的，而冰冻颗粒是由上升气流抬升的雨滴冻结后形成的。

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.