Litcius/Paper detail

Locating Urban Area Heat Waves by Combining Thermal Comfort Index and Computational Fluid Dynamics Simulations: The Optimal Placement of Climate Change Infrastructure in a Korean City

Sinhyung Cho, S. Cho, Seungkwon Jung, Jaekyoung Kim

2025Climate8 citationsDOIOpen Access PDF

Abstract

The intensification of extreme temperature events driven by climate change has heightened the vulnerability of urban areas to heatwaves, making it a critical environmental challenge. In this study, we investigate the spatial characteristics of urban heatwave vulnerability in Jungang-dong, Gangneung—a representative mid-sized coastal city in South Korea that experiences a strong urban heat island (UHI) effect due to the prevalent land–sea breeze dynamics, high building density, and low green-space ratio. A representative heatwave day (22 August 2024) was selected using AWS data from the Korea Meteorological Administration (KMA), and hourly meteorological conditions were applied to Computational Fluid Dynamics (CFD) simulations to model the urban microclimates. The thermal stress levels were quantitatively assessed using the Universal Thermal Climate Index (UTCI). The results indicated that, at 13:00, the surface temperatures reached 40 °C and the UTCI values peaked at 43 °C, corresponding to a “Very Strong Heat Stress” level. Approximately 17.4% of the study area was identified as being under extreme thermal stress, particularly in densely built-up zones, roadside corridors with high traffic, and pedestrian commercial areas. Based on these findings, we present spatial analysis results that reflect urban morphological characteristics to guide the optimal allocation of urban cooling strategies, including green (e.g., street trees, urban parks, and vegetated roofs), smart, and engineered infrastructure. These insights are expected to provide a practical foundation for climate adaptation planning and thermal environment improvement in mid-sized urban contexts.

Topics & Concepts

Urban heat islandHeat waveThermal comfortClimate changeEnvironmental scienceIndex (typography)ThermalComputational fluid dynamicsMeteorologyClimatologyComputer scienceGeographyGeologyEngineeringAerospace engineeringOceanographyWorld Wide WebUrban Heat Island MitigationWind and Air Flow StudiesBuilding Energy and Comfort Optimization
Locating Urban Area Heat Waves by Combining Thermal Comfort Index and Computational Fluid Dynamics Simulations: The Optimal Placement of Climate Change Infrastructure in a Korean City | Litcius