Improving urban temperature measurements and two applications

IF 3.9 Q2 ENVIRONMENTAL SCIENCES
Julien Anet , Moritz Burger , Curdin Spirig , Ivo Suter
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Abstract

More extreme, frequent and longer heat waves negatively affect people all around the world, and especially inhabitants of urban areas which face even higher temperatures due to the urban heat island effect. A precondition to develop adaptation strategies to counteract adverse effects of heat in cities is to gain knowledge about the urban temperature distribution. One approach that has been applied in various cities is the implementation of dense urban temperature measurement networks. Since financial resources are usually limited, such networks consist of cost-effective measurement devices whose (daytime) data quality is prone to errors due to radiative influences. This was also the case in Zürich, Switzerland, where an urban temperature network with 272 measurement stations was operated from 2019 to 2021. In this study, we present a radiation correction method to enhance the data quality for practical use. Applying the proposed correction method led to a reduction in mean RMSE from 1.47 K to 0.57 K and in the overall mean bias from +0.88 K to +0.04 K. Following from that, we use the corrected database for two application cases: i) As a spatially and temporally high-resolution validation dataset for the physics-based large eddy simulation model PALM and ii) as input data for a geostatistical land use regression model. The analysis shows that the daytime radiation correction is crucial to detect the negative bias of the PALM model, which is most pronounced in the highly built-up area of Zürich, and to enhance the quality of the daytime land use regression. The developed radiation correction presented in this study can also be applied for other urban temperature networks that are facing similar challenges.

Abstract Image

改进城市温度测量和两种应用
更极端、更频繁和更长时间的热浪对世界各地的人们都产生了不利影响,尤其是城市地区的居民,由于城市热岛效应,他们面临着更高的温度。制定应对城市热浪不利影响的适应战略的先决条件是了解城市温度分布。已在多个城市应用的一种方法是实施密集的城市温度测量网络。由于财政资源通常有限,此类网络由成本效益高的测量设备组成,其(白天)数据质量容易受到辐射影响而出现误差。瑞士苏黎世的情况也是如此,从 2019 年到 2021 年,苏黎世运行了一个由 272 个测量站组成的城市温度网络。在本研究中,我们提出了一种辐射校正方法,以提高数据质量,供实际使用。应用所提出的校正方法后,平均均方根误差从 1.47 K 减小到 0.57 K,总体平均偏差从 +0.88 K 减小到 +0.04 K。在此基础上,我们将校正后的数据库用于两个应用案例:i) 作为基于物理的大涡度模拟模型 PALM 的空间和时间高分辨率验证数据集;ii) 作为地质统计土地利用回归模型的输入数据。分析表明,日间辐射校正对于检测 PALM 模型的负偏差(在苏黎世高度密集区最为明显)和提高日间土地利用回归的质量至关重要。本研究中提出的辐射校正方法也可用于面临类似挑战的其他城市气温网络。
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
City and Environment Interactions
City and Environment Interactions Social Sciences-Urban Studies
CiteScore
6.00
自引率
3.00%
发文量
15
审稿时长
27 days
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