基于多个被动微波数据的欧亚大陆雪深历史和实时估计

IF 6.4 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Li-Yun Dai , Li-Juan Ma , Su-Ping Nie , Si-Yu Wei , Tao Che
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引用次数: 0

摘要

目前的雪深数据集表明,欧亚大陆的空间格局存在很大差异,数据集的滞后更新不符合气象服务部门的操作要求。本研究开发了一种基于交叉传感器校准微波亮度温度的欧亚大陆日积雪深度动态反演方法,以提高反演精度,满足作战工作的要求。这些亮度温度是由风云三号(FY-3)卫星上的微波辐射计成像仪和美国国防气象卫星计划系列卫星上的特殊传感器微波成像仪/探测器探测到的,它们使用最少的传感器来提供最长的数据,从而在传感器间校准过程中引入最小的误差。首先,在三个传感器收集的亮度温度之间进行传感器间校准。然后建立了雪深与微波亮度温度梯度之间的时空动态关系,克服了雪特性变化带来的巨大不确定性。这种关系可以在FY-3卫星数据中用于操作服务,以获得实时雪深。1988年至2021年生成的每日雪深数据集呈现出与现场观测到的雪深相似的雪深空间模式。相对于现场雪深,总体偏差和均方根误差分别为-2.04和6.49 cm,与采用静态算法的Advanced Microwave Scanning Radiometer 2雪深产品相比,有助于大幅提高精度。进一步的分析显示,从1988年到2021年,年平均雪深和月平均雪深总体呈下降趋势,表明自2000年左右以来显著下降。月平均雪深的减少在浅雪月份比在深雪月份更早开始。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Historical and real-time estimation of snow depth in Eurasia based on multiple passive microwave data

Current snow depth datasets demonstrate large discrepancies in the spatial pattern in Eurasia, and the lagging updates of datasets do not meet the operational requirements of the meteorological service department. This study developed a dynamic retrieval method for daily snow depth over Eurasia based on cross-sensor calibrated microwave brightness temperatures to enhance retrieval accuracy and meet the requirements of operational work. These brightness temperatures were detected by microwave radiometer imager carried on the FengYun 3 (FY-3) satellite and the special sensor microwave imager/sounder carried on the USA Defense Meteorological Satellite Program series satellites, which use the fewest sensors to provide the longest data and consequently introduce minimal errors during inter-sensor calibration. Firstly, inter-sensor calibration was conducted amongst brightness temperatures collected by the three sensors. A spatiotemporal dynamic relationship between snow depth and microwave brightness temperature gradient was then established, overcoming the large uncertainties induced by varying snow characteristics. This relationship can be utilised in FY-3 satellite data for operational service to obtain real-time snow depth. The generated daily snow depth dataset from 1988 to 2021 presents similar spatial patterns of snow depth to those observed in situ. Against in situ snow depth, the overall bias and root mean square error are −2.04 and 6.49 cm, respectively, facilitating considerable improvements in accuracy compared with the Advanced Microwave Scanning Radiometer 2 snow depth product, which adopts the static algorithm. Further analysis shows an overall decreasing trend from 1988 to 2021 for annual and monthly mean snow depths, demonstrating a noticeable reduction since around 2000. The reduction in monthly mean snow depth started earlier in shallow snow months than in deep snow months.

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来源期刊
Advances in Climate Change Research
Advances in Climate Change Research Earth and Planetary Sciences-Atmospheric Science
CiteScore
9.80
自引率
4.10%
发文量
424
审稿时长
107 days
期刊介绍: Advances in Climate Change Research publishes scientific research and analyses on climate change and the interactions of climate change with society. This journal encompasses basic science and economic, social, and policy research, including studies on mitigation and adaptation to climate change. Advances in Climate Change Research attempts to promote research in climate change and provide an impetus for the application of research achievements in numerous aspects, such as socioeconomic sustainable development, responses to the adaptation and mitigation of climate change, diplomatic negotiations of climate and environment policies, and the protection and exploitation of natural resources.
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