Cities are experiencing rapid warming due to the urban heat island (UHI) effect, which causes the city center to have higher air temperatures than the surrounding rural areas. This dissertation studies the effects of building design on the surrounding environment, particularly for heat release.The first paper in this dissertation (Chapter 2) quantifies the anthropogenic heat emissions from buildings and focuses on an archetype office building, the study is considering four U.S. cities with different climates. The results demonstrate that the building envelope is the main contributor to heat emission from a building, accounting for over 60% of the total heat emission in all cities for four-story buildings. Additionally, the study finds that substituting bare terrain with a constructed building increases sensed heat by more than 70% in all cities and building heights. The second paper (Chapter 3) of this dissertation identifies the key design variables that affect heat emissions and energy consumption in buildings. The study considers 15 U.S. cities that represents all 15 climate zones as defined by American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE). 10 design variables known for their impacts on energy consumption were identified via a literature review and used in the analysis. The results show that the window-to-wall ratio (WWR) consistently has a strong correlation with energy consumption in all climate zones. Roof and wall solar reflectance variables showed a very strong correlation with heat emissions from a building. The final paper of this dissertation (Chapter 4) presents the results of a survey distributed to experts in the architectural field, to evaluate the importance of different design variables that are related to heat emission and energy consumption. The survey also assessed the importance of considering heat emission as a design criterion during the design process when compared to energy consumption. These survey results provide new insights into how heat emission can be incorporated into the early design process. The dissertation then highlights the difference found via the survey results from the expert with the simulation results to identify the key design variable that relates to both heat emission and energy consumption.

As the number of heat waves are expected to increase significantly into the future in the U.S. Southwest, new insight is needed into how urban infrastructure can be repositioned to protect people. In the Phoenix metro area infrastructure have largely been deployed over the past half century, during a time when climate change was not a concern. Now, as the county struggles to protect people from heat, there is a need to reassess how existing and new infrastructure can be positioned to reduce health impacts while improving sustainability. Using a neighborhood in Mesa, Arizona as a case study, we assess how changes to transportation infrastructure, building infrastructure, and landscaping can reduce heat exposure. A number of strategies are considered including the optimal deployment of heat refuges, deploying less convective surface materials, and deploying more thermally preferable building materials. The suite of strategies could be considered by cities throughout the Phoenix metro area.