The impact of building height on urban thermal environment in summer: A case study of Chinese megacities

Wang, Meiya; Xu, Hong‐Guang

doi:10.1371/journal.pone.0247786

Cited by 30 publications

(14 citation statements)

References 39 publications

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“…Under such conditions, less incident radiation will likely be absorbed on the urban surfaces (horizontal and/or vertical), leading to cooler urban surfaces. Wang and Xu (2021) also indicate that land surface temperature decreases significantly with building height differences and brings a cooling effect.…”

Section: Discussionmentioning

confidence: 88%

Fine-Scale Urban Heat Patterns in New York City Measured by ASTER Satellite – The Role of Complex Spatial Structures

Nath¹,

Özdoğan²,

Ni‐Meister³

2021

Preprint

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Urban areas have very complex spatial structures. These spatial structures are primarily composed of a complex network of built environments, which evolve rapidly as the cities expand to meet the growing population’s demand and economic development. Therefore, studying the impact of spatial structures on urban heat patterns is extremely important for sustainable urban planning and growth. We investigated the relationship between surface temperature obtained by the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER, at 90 m spatial resolution) on the current EOS-Terra platform and different urban components based on the classification of high-resolution QuickBird imagery. We further investigated the relationships between surface temperature and building footprint and land use information acquired from the New York City (NYC) Department of City Planning. The ASTER image reveals fine-scale urban heat patterns in the NYC metropolitan region. The dark and medium-dark impervious surfaces, along with bright surfaces, generate higher surface temperatures. Even with highly reflective urban materials, the presence of impervious materials leads to an increased surface temperature. At the same time, trees and shadows are effective in reducing urban heat. The data aggregated to the census tract reveals high-temperature clusters in Queens, Brooklyn, and the Bronx region of NYC. These clusters are associated with industrial and manufacturing areas and multi-family walk-up buildings as dominant land use. The census tracts with more trees and higher building height variability generate lower surface temperatures, consistent with shadow cast by high-rise buildings and trees. The results of this study can be valuable for urban heat island modeling on the effects of building heights variability and tree shadows on small-scale surface temperature patterns. It can also help identify the risk areas during extreme heat events to protect public health.

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Section: Discussionmentioning

confidence: 88%

Fine-Scale Urban Heat Patterns in New York City Measured by ASTER Satellite – The Role of Complex Spatial Structures

Nath¹,

Özdoğan²,

Ni‐Meister³

2021

Preprint

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“…In addition to the different building arrangements, building height and vegetation affect the air temperature distribution in architectural layouts. Using a remote sensing method, Wang and others found that an increase in building height will produce a cooling effect [24]. In addition, some studies have reported that adding a single building construction area and increasing the number of floors can increase the shading effect [25].…”

Section: Discussionmentioning

confidence: 99%

Evaluating the Influence of Different Layouts of Residential Buildings on the Urban Thermal Environment

Chen

Cheng

et al. 2022

Sustainability

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Urban residential building layouts have an impact on air temperature and thermal comfort. Research has shown that poorly designed building layouts can lead to thermal discomfort. Thus, it is crucial to analyze the relationship between residential building layouts and air temperature. We used the ENVI-met 3D microclimate model to simulate six typical residential building layouts and explore the diurnal and seasonal variations in air temperature. In addition, we used the physiological equivalent temperature (PET) as the evaluation index for the thermal comfort of different building layouts. The diurnal results showed that the air temperature of the parallel layout rose faster and fell faster, and these changes were more significant in summer. The results of the air temperature classifications indicated that the frequency of low-air-temperature areas in the parallel layout is approximately 12% smaller than that of the enclosed and semi-enclosed layouts, and the high-air-temperature area frequency is 11% higher than that of the enclosed and semi-enclosed layouts in summer. In winter, the frequency of low-air-temperature areas in the parallel layout is approximately 7% smaller than that of the enclosed and semi-enclosed layouts, and the high-air-temperature area frequency is 5% higher than that of the enclosed and semi-enclosed layouts. In combination with the PET results, we found that the enclosed layout is the optimal configuration. Moreover, in some cases, increased building height and vegetation lead to a reduction in air temperature.

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“…For example, tall buildings in the upwind direction may largely alter the mixing condition of the street, thus having a stronger influence on street-level temperature (Gao et al, 2022). A similar situation applies to the localized shading effect from trees and buildings, which plays a major role in energy re-distribution in the built environment (Park et al, 2021;Wang, M and Yang, J., 2021).…”

Section: Ablation Testmentioning

confidence: 99%

Street-level temperature estimation using Graph Neural Networks: Performance, feature embedding and interpretability

Yu,

Li,

Huang

et al. 2024

Preprint

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**The manuscript has been submitted to Urban Climate for peer review. Estimating street-level air temperature is a challenging task due to the highly heterogeneous urban surfaces, canyon-like street morphology, and the diverse physical processes in the built environment. Though pioneering studies have embarked on investigations via data-driven approaches, many questions remain to be answered. In this study, we leveraged an innovative framework and redefined the street-level temperature estimation problem using Graph Neural Networks (GNN) with spatial embedding techniques. The results showed that GNN models are more capable and consistent of estimating street-level temperature among tested locations, benefiting from its unique strength in handling extensive data over unstructured graph topology. In addition, we conducted an in-depth analysis of feature importance to enhance the model interpretability. Among the urban features analyzed in this study, the time-variant canopy density and meter-level land use data emerge as crucial factors. Our findings highlight GNN’s high potential in capturing the complex dynamics between urban elements and their impacts on microclimate, thus offering valuable insights for comprehensive urban data collection and urban climate modeling in general. Collectively, this study also contributes to urban planning and policy by providing avenues to enhance city resilience against climate change, thereby advancing the agenda for environmental stewardship and urban sustainability.

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The impact of building height on urban thermal environment in summer: A case study of Chinese megacities

Cited by 30 publications

References 39 publications

Fine-Scale Urban Heat Patterns in New York City Measured by ASTER Satellite – The Role of Complex Spatial Structures

Fine-Scale Urban Heat Patterns in New York City Measured by ASTER Satellite – The Role of Complex Spatial Structures

Evaluating the Influence of Different Layouts of Residential Buildings on the Urban Thermal Environment

Street-level temperature estimation using Graph Neural Networks: Performance, feature embedding and interpretability

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