Analysis and Optimization of Thermal Environment in Old Urban Areas from the Perspective of “Function–Form” Differentiation

High-density urban areas have spatial characteristics, such as complex functions, population gathering, and complex forms, that lead to more severe urban heat island effects. Systematically evaluating the thermal environmental benefits of urban spatial forms to optimize the urban physical environmen...

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Bibliographic Details
Published inSustainability Vol. 15; no. 7; p. 6172
Main Authors Zeng, Suiping, Zhang, Jiahao, Tian, Jian
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.04.2023
Subjects
Analysis
Business districts
Climate change
Coefficients
Environment
Heterogeneity
High density
High temperature
Influence
Land surface temperature
Metropolitan areas
Morphology
Neighborhoods
Optimization
Parameters
Research methodology
Spatial heterogeneity
Sustainable urban development
Temperature
Thermal environments
Urban areas
Urban climatology
Urban environments
Urban heat islands
Urban planning
China
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Summary:High-density urban areas have spatial characteristics, such as complex functions, population gathering, and complex forms, that lead to more severe urban heat island effects. Systematically evaluating the thermal environmental benefits of urban spatial forms to optimize the urban physical environment is important. In this study, Tianjin’s central urban area, which is a typical representative of high-density urban areas, was selected to invert the multi-period land surface temperature by relying on the existing two- and three-dimensional morphological data set of communities. The multi-scale geographically weighted regression model was used to fit the regression relationship between the urban land surface temperature and spatial morphological parameters. From this, the influencing factors of different types of existing community spaces and their spatial stabilities were explored. The results show the following: (1) The summer surface temperature varies greatly in the central urban area, and the high-temperature areas are mainly distributed in the industrial, residential, and commercial districts. (2) The MGWR model has the better model-fitting ability. The positive influence coefficients of temperature include ISP and BD, while the negative influence coefficients are BSD, BH, NDVI, and SVF. (3) There is significant spatial heterogeneity in the impact coefficients among the blocks that can be targeted to mitigate the heat island effect. This study provides ideas for optimizing the spatial morphological parameters of surface temperature in urban centers. Future challenges include increasing the spatial morphological parameter selection range, dissecting the interactive relationships between spatial morphological parameters and their effectiveness on the surface temperature, and refining the study’s spatial and temporal granularity.
ISSN:2071-1050
2071-1050
DOI:10.3390/su15076172