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This dissertation focuses on three studies related to sustainable urban wastewater systems and greywater policy. The research aims to address technical, regulatory, and social gaps in sustainable urban wastewater systems and greywater policy through research and innovation, adopting a holistic, systems perspective to realize the water security, environmental, and social benefits of greywater reuse. The main research question is: How can greywater treatment technologies and greywater reuse policies contribute to sustainable urban water systems based on the SETs (Social-Ecological-Technological Systems) framework?The first study conducted a systematic literature review of urban wastewater, covering historical sources, treatment technologies, recycling, and reuse. It summarized the theoretical framework based on the review and developed a conceptual framework for greywater treatment technologies based on the SETs framework, which can support the development of sustainable cities.
The second study focused on the public perception of greywater reuse in Phoenix, Arizona, USA. Using a mix of qualitative and quantitative research methods, the study found that city residents have a strong positive perception of and support for greywater reuse, suggesting that the barriers and challenges of public perception can be overcome.
The third study examined greywater reuse policies in Arizona and California. It interviewed residents and policymakers and conducted a policy analysis to reveal the implementation benefits, management obstacles, technical restrictions, and challenges of greywater reuse policies in the two states. The study provides recommendations for redesigning greywater policies and improving greywater reuse policies.
The dissertation concludes that greywater reuse policies should be informed by the new knowledge from the three studies to establish sustainable water use practices and design greywater reuse regulations and technologies that encourage safe and responsible greywater reuse in urban design. It emphasizes the need to increase economic data on greywater use and public investment to provide better economic costs and benefits, which can help shift interest towards more supportive greywater policy changes. The dissertation highlights that greywater policy is a key factor affecting the sustainability of urban water systems and that greywater treatment technologies and policies can contribute to sustainable urban water systems by addressing the social, ecological, and technological aspects of urban water challenges, supporting the vision of resilient, inclusive, livable, and sustainable water-smart cities.
ContributorsHu, Die (Author) / Cheng, Chingwen (Thesis advisor) / Coseo, Paul (Thesis advisor) / Boyer, Treavor (Committee member) / Arizona State University (Publisher)
Created2024
Description
Urban-induced heating is a challenge to the livability and health of city dwellers. It is a complex issue that many cities are facing, and a more urgent hazard in hot urban deserts (HUDs) than elsewhere due to already high temperatures and aridity. The challenge compounds in the absence of more localized heat mitigation understanding. In addition, over-reliance on evidence from temperate regions is disconnected from the actualities of extreme bioclimatic dynamics found in HUDs. This dissertation is an integration of a series of studies that inform urban climate relationships specific to HUDs. This three-paper dissertation demonstrates heat mitigation aspirational goals from actualities, depicts local urban thermal drivers in Kuwait, and then tests morphological sensitivity of selected thermal modulation strategies in one neighborhood in Kuwait City.
The first paper is based on a systematic literature review where evidence from morphological mitigation strategies in HUDs were critically reviewed, synthesized and integrated. Metrics, measurements, and methods were extracted to examine the applicability of the different strategies, and a content synthesis identified the levels of strategy success. Collective challenges and uncertainties were interpreted to compare aspirational goals from actualities of morphological mitigation strategies.
The second paper unpacks the relationship of urban morphological attributes in influencing thermal conditions to assess latent magnitudes of heat amelioration strategies. Mindful of the challenges presented in the first study, a 92-day summer field-measurement campaign captured system dynamics of urban thermal stimuli within sub-diurnal phenomena. A composite data set of sub-hourly air temperature measurements with sub-meter morphological attributes was built, statistically analyzed, and modeled. Morphological mediation effects were found to vary hourly with different patterns under varying weather conditions in non-linear associations. Results suggest mitigation interventions be investigated and later tested on a site- use and time-use basis.
The third paper concludes with a simulation-based study to conform on the collective findings of the earlier studies. The microclimate model ENVI-met 4.4, combined with field measurements, was used to simulate the effect of rooftop shade-sails in cooling the near ground thermal environment. Results showed significant cooling effects and thus presented a novel shading approach that challenges orthodox mitigation strategies in HUDs.
The first paper is based on a systematic literature review where evidence from morphological mitigation strategies in HUDs were critically reviewed, synthesized and integrated. Metrics, measurements, and methods were extracted to examine the applicability of the different strategies, and a content synthesis identified the levels of strategy success. Collective challenges and uncertainties were interpreted to compare aspirational goals from actualities of morphological mitigation strategies.
The second paper unpacks the relationship of urban morphological attributes in influencing thermal conditions to assess latent magnitudes of heat amelioration strategies. Mindful of the challenges presented in the first study, a 92-day summer field-measurement campaign captured system dynamics of urban thermal stimuli within sub-diurnal phenomena. A composite data set of sub-hourly air temperature measurements with sub-meter morphological attributes was built, statistically analyzed, and modeled. Morphological mediation effects were found to vary hourly with different patterns under varying weather conditions in non-linear associations. Results suggest mitigation interventions be investigated and later tested on a site- use and time-use basis.
The third paper concludes with a simulation-based study to conform on the collective findings of the earlier studies. The microclimate model ENVI-met 4.4, combined with field measurements, was used to simulate the effect of rooftop shade-sails in cooling the near ground thermal environment. Results showed significant cooling effects and thus presented a novel shading approach that challenges orthodox mitigation strategies in HUDs.
ContributorsAlKhaled, Saud R A H (Author) / Coseo, Paul (Thesis advisor) / Brazel, Anthony (Thesis advisor) / Middel, Ariane (Committee member) / Cheng, Chingwen (Committee member) / Arizona State University (Publisher)
Created2019
Description
Green infrastructure serves as a critical no-regret strategy to address climate change mitigation and adaptation in climate action plans. Climate justice refers to the distribution of climate change-induced environmental hazards (e.g., increased frequency and intensity of floods) among socially vulnerable groups. Yet no index has addressed both climate justice and green infrastructure planning jointly in the USA. This paper proposes a spatial climate justice and green infrastructure assessment framework to understand social-ecological vulnerability under the impacts of climate change. The Climate Justice Index ranks places based on their exposure to climate change-induced flooding, and water contamination aggravated by floods, through hydrological modelling, GIS spatial analysis and statistical methodologies. The Green Infrastructure Index ranks access to biophysical adaptive capacity for climate change. A case study for the Huron River watershed in Michigan, USA, illustrates that climate justice hotspots are concentrated in large cities; yet these communities have the least access to green infrastructure. This study demonstrates the value of using GIS to assess the spatial distribution of climate justice in green infrastructure planning and thereby to prioritize infrastructure investment while addressing equity in climate change adaptation.
ContributorsCheng, Chingwen (Author)
Created2016-06-29