Zhu, Jingxuan, Zhang, Shuliang, Yang, Qiqi, Shen, Qi, Zhuo, Lu and Dai, Qiang
2021.
Comparison of rainfall microphysics characteristics derived by numerical weather prediction modelling and dual‐frequency precipitation radar.
Meteorological Applications
28
(3)
, e2000.
10.1002/met.2000
|
![[thumbnail of Meteorological Applications - 2021 - Zhu - Comparison of rainfall microphysics characteristics derived by numerical weather.pdf]](https://orca.cardiff.ac.uk/style/images/fileicons/application_pdf.png) |
PDF
- Published Version
Available under License Creative Commons Attribution Non-commercial No Derivatives. Download (19MB) |
Abstract
<p>The understanding of large-scale rainfall microphysical characteristics plays a significant role in meteorology, hydrology and natural hazards managements. Traditional instruments for estimating raindrop size distribution (DSD), including disdrometers and ground dual-polarization radars, are available only in limited areas. However, the development of space-based radars and mesoscale numerical weather prediction models would allow for DSD estimation on a large scale. This study investigated the performance of the weather research and forecasting (WRF) model and the global precipitation measurement mission (GPM) dual-frequency precipitation radar for DSD retrieval under different conditions. The DSD parameters (D<sub>m</sub> and N<sub>w</sub>), rain rate (R), rainfall kinetic energy (KE) and radar reflectivity (Z) were estimated in Chilbolton, United Kingdom, by using long-term disdrometer observations for validation. The rainfall kinetic energy–rain rate (KE–R) and radar reflectivity–rain rate (Z–R) relationships were explored using a disdrometer, the WRF model and GPM. It was found that the DSD parameter distribution trends of the three approaches are similar although the WRF model has larger D<sub>m</sub> and smaller N<sub>w</sub> values. In terms of the rainfall microphysical relationship, GPM performs better when both Ku- and Ka-band precipitation radars (KuPR and KaPR) observe precipitation simultaneously (R > 0.5 mm h<sup>−1</sup>), while the WRF model shows high accuracy in light rain (R < 0.5 mm h<sup>−1</sup>). The fusion of GPM and WRF model is recommended for the improved understanding of rainfall microphysical characteristics in ungauged areas.</p>
| Item Type: | Article |
|---|---|
| Date Type: | Publication |
| Status: | Published |
| Schools: | Earth and Environmental Sciences |
| Publisher: | Royal Meteorological Society |
| ISSN: | 1350-4827 |
| Date of First Compliant Deposit: | 15 November 2022 |
| Date of Acceptance: | 30 April 2021 |
| Last Modified: | 16 May 2023 02:57 |
| URI: | https://orca.cardiff.ac.uk/id/eprint/153231 |
Citation Data
Cited 3 times in Scopus. View in Scopus. Powered By Scopus® Data
Actions (repository staff only)
 |
Edit Item |
Altmetric
Altmetric
Cardiff University Information Services