Attribution of Urban Diurnal Thermal Environmental Change: Importance of Global–Local Effects

Yu, Wenbo; Yang, Jun; Cong, Nan; Ren, Jiayi; Yu, Huisheng; Xiao, Xiangming; Xia, Jianhong

doi:10.1109/jstars.2023.3308045

Cited by 8 publications

(4 citation statements)

References 72 publications

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“…Third, the shape and size of built-up areas and surrounding green patches also have impacts on the LST of different built-up age cohorts. Urban areas exhibit a variable LST pattern that can be linked to albedo variations [85][86][87]; the increase in building density and floor area ratio will also cause LST to rise with urban construction [61,[88][89][90]. In contrast to previous studies, our results show that landscape plays a leading role in determining the LST pattern among built-up age cohorts (Figure 5).…”

Section: Temporal Stability Of the Spatial Pattern Of Lstcontrasting

confidence: 77%

Evolution and Built-Up Age Dependency of Urban Thermal Environment

Li,

Liu,

Liu

et al. 2024

Remote Sensing

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The urban heat island (UHI) represents an anthropogenic modification to the earth’s surface, and its relationship with urban development, built-up age dependency in particular, is poorly understood. We integrated global artificial impervious areas to analyze the impacts of built-up age and urban development intensity (UDI) on land surface temperatures (LSTs) in Hefei, the capital of Anhui Province of China, from 2000 to 2019. A key finding was that the built-up areas with different built-up ages were strongly associated with LST, and this relationship does not change significantly over time, suggesting temporal stability of spatial patterns of LSTs. This finding puts forward a challenge to the application of the classic concept of space-for-time in LST studies because the premise of space-for-time is that spatial and temporal variation are equivalent. This result reveals the vital importance of annual development activities on the urban thermal environment. Another highlighted result was LST sensitivity to UDI, an effective measure of the impact of urbanization on LST, which increased significantly from 0.255 °C per 10% UDI to 0.818 °C per 10% UDI. The more than doubling of LST sensitivity to UDI should be a major concern for city administration. These findings have crucial theoretical and practical significance for the regulation of LSTs and UHI.

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Section: Temporal Stability Of the Spatial Pattern Of Lstcontrasting

confidence: 77%

Evolution and Built-Up Age Dependency of Urban Thermal Environment

Li,

Liu,

Liu

et al. 2024

Remote Sensing

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“…Research concerning urban morphology-LST relationships has predominantly centered on their correlation. [37], [25], [38], [39]. Guo et al (2020) investigated indices such as landscape patterns, the proportion of construction land (PCL), the proportion of woodland and grass (PWG), and the 2 > IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing < normalized difference built-up index (NDBI), identifying a strong correlation between NDBI and LST.…”

Section: Introductionmentioning

confidence: 99%

XGBoost-Based Analysis of the Relationship Between Urban 2-D/3-D Morphology and Seasonal Gradient Land Surface Temperature

Ma,

Yang,

Zhang

et al. 2024

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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The escalation of greenhouse gas emissions has led to a continuous rise in land surface temperature (LST). Studies have highlighted the substantial influence of urban morphology on LST; however, the impact of different dimensional indicators and their gradient effects remain unexplored. Selecting the urban area of Shenyang as a case, we chose various indicators representing different dimensions. By employing XGBoost for regression analysis, we aimed to explore the effects of urban 2D and 3D morphology on seasonal LST and its gradient effect. The following results were obtained: (1) The spatial pattern of LST in spring and winter in Shenyang was higher in the suburbs than in the center. (2) The correlation patterns of the indicators in spring and winter were similar, except for the proportion of woodland and grass (PWG), digital elevation model (DEM), and sky view factor (SVF), which exhibited opposing trends in summer and autumn. (3) Vegetation and construction had the highest influence on LST in the 2D index, followed by building forms and natural landscapes in the 3D urban morphology. (4) The influence of each indicator varied significantly across different gradients. Among all the indicators, the landscape index, social development, building forms, and skyscape had the highest impacts on urban areas. Vegetation and built-up areas had a greater influence on suburban areas. The findings of this study can assist in adjusting urban morphology and provide valuable recommendations for targeted improvements in thermal environments, thereby contributing to urban sustainable development.

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“…By moderating energy and water exchanges between land and the atmosphere, urban trees exert considerable influence on the climate system, operating at both local and regional scales [9], [10]. Extensive research conducted at local and urban scales has consistently demonstrated the diverse environmental benefits of urban trees, including the mitigation of microclimatic conditions [5], [11], [12], [13], reduction of heat island intensity [2], [6], [14], alleviation of air pollution [1], [3], and preservation of biodiversity [15], [16]. Moreover, urban trees have been widely acknowledged for their protective effects on human health and mental well-being, attributed to their facilitation of physical activity, support for social interaction, promotion of community awareness, and stress alleviation capabilities [1], [8], [17], [18].…”

Section: Introductionmentioning

confidence: 99%

Urban Trees Expansion and Exposure Improvement in China: Insights From Satellite Observations (1985–2023)

Liu,

Cai

2024

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Urban tree cover plays a pivotal role in bolstering the sustainability, livability, and resilience of cities. However, the changes in urban tree cover and exposure under the backdrop of urbanization in China remain unclear. This study investigates the spatial distribution and temporal trends of urban tree cover expansion and exposure change from 1985 to 2023. Our findings highlight significant progress in enhancing urban tree cover, with the average tree cover in Chinese urban areas reaching 11.9% in 2023, representing a remarkable 116% increase from 5.5% in 1985. However, this positive trend contrasts with persistent deficiencies in forest resources, as reflected by the fact that urban forest cover in Chinese cities was only 4.1% in 2023, compared to 0.1% in 1985. Furthermore, our study revealed substantial heterogeneity in the spatiotemporal variations of urban tree cover. Only five cities exhibited a decreasing trend in tree cover during the study period, with coastal cities demonstrating significantly higher tree cover compared to inland cities. Additionally, we observed that urban tree cover and expansion rates decreased significantly with increasing latitude. Moreover, nationwide, there has been a sustained and accelerated improvement in urban tree exposure levels, with average tree exposure increasing from 0.66% in 1985 to 7.45% in 2020. Sixtynine percent of cities experienced positive changes in tree exposure levels, while only 1% exhibited negative changes. These findings offer valuable insights for policymakers, planners, and stakeholders to foster greener, more resilient, and sustainable urban environments in China.

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Attribution of Urban Diurnal Thermal Environmental Change: Importance of Global–Local Effects

Cited by 8 publications

References 72 publications

Evolution and Built-Up Age Dependency of Urban Thermal Environment

Evolution and Built-Up Age Dependency of Urban Thermal Environment

XGBoost-Based Analysis of the Relationship Between Urban 2-D/3-D Morphology and Seasonal Gradient Land Surface Temperature

Urban Trees Expansion and Exposure Improvement in China: Insights From Satellite Observations (1985–2023)

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