The Urban Heat Island (UHI) effect increases thermal stress in dense urban environments and is associated with elevated public health risks. Street-tree shading is a key passive strategy for reducing pedestrian-level heat exposure. This study quantifies the cooling effects of street trees on sidewalk microclimates in Los Angeles using a GIS-based framework that integrates spatial modeling, microclimate simulation, and field measurements. Field measurements were conducted on representative tree species to evaluate shading performance. Tree shading reduced pedestrian-level solar radiation by 50-70% during peak hours. A quantitative relationship between solar radiation and air temperature was derived, indicating that a reduction of 100 W/m2 corresponds to an approximate decrease of 0.5-0.75 °C in near-ground air temperature. Thermal comfort analysis using the CBE model indicates improved comfort conditions under shaded environments. scenario-based simulations were used to assess tree-planting strategies for a representative urban block. Increasing canopy width was associated with greater overall shading coverage, while increasing tree height primarily affected shading during peak radiation periods. Combined tree-building configurations resulted in more spatially continuous reductions in solar radiation compared to single-factor conditions.
Kang et al. (Tue,) studied this question.
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