Mazdak Arabi Associate Professor Department of Civil and Environmental Engineering Colorado State University Fort Collins, Colorado Email: mazdak.arabi@colostate.edu Voice: (970) 491-4639 Modeling Infrastructure for Water Sustainability Analysis Water is essential for socioeconomic development and maintaining healthy ecosystems. Population growth, together with increasing demands from agriculture, energy and environmental uses intensify competition for freshwater resources. In water stressed regions, climate variability and change exacerbate conflicts among users by altering supply-demand patterns and water quality. Striking a balance between water supply and conflicting demands necessitates assessing potential benefits and costs of various water management strategies. In the western U.S., compliance with water compacts, environmental regulations, and other institutional agreements increasingly discourages development of new water supply facilities and trans-basin transfers. Thus, in-basin strategies are crucial to enhancing the resiliency and reliability of regional water resource systems. In this seminar, a new integrative and adaptive analysis framework for the development of optimal water management at the regional scale under projected future climate, land use and energy scenarios is presented. This framework leads to a better understanding and managing of resources under stress, integrating physical, ecological, and socioeconomic feedbacks. An integrated modeling and optimization framework reconciles regional water resource sustainability, socioeconomic, and institutional criteria to identify solutions that provide the highest level of resiliency at the lowest cost. The framework serves several benefits: (i) it reveals the feasibility of satisfying water demands and water quality targets, under the prevailing governance systems, for any combination of projected climate, land use and energy scenarios; (ii) it exposes components of the hydrologic and governance systems that are key to achieving water quantity and quality targets; and (iii) it determines cost-effective options to enhance the resiliency and reliability of water resources while sustaining desired levels of agricultural production and livelihood of rural communities in the region. A web-based cloud computing infrastructure dubbed eRAMS facilitates wider accessibility and scalability of the modeling, optimization and analysis tools. Key features and software architecture of eRAMS will be discussed.