As industrial operations move to the state, residents find that their drinking water has been promised to companies. In 2019, Corpus Christi, Texas's eighth-largest city, moved forward with plans to build a desalination plant. The facility, which was expected to be completed by 2023, at a cost of a hundred and forty million dollars, would convert seawater into fresh water to be used by the area's many refineries and chemical plants. The former mayor called it "a pretty significant day in the life of our city." In anticipation of the plant's opening, the city committed to provide tens of millions of gallons of water per day to new industrial operations, including a plastics plant co-owned by ExxonMobil and the Saudi Basic Industries Corporation, a lithium refinery for Tesla batteries, and a "specialty chemicals" plant operated by Chemours.

The United Arab Emirates (UAE) relies heavily on seawater desalination to meet over 90% of its drinking water needs. Desalination processes are highly energy intensive and account for approximately 15% of the UAE's electricity consumption, contributing to over 22% of the country's energy-related CO2 emissions. Moreover, these processes face significant sustainability challenges in the face of climate uncertainties such as rising seawater temperatures, salinity, and aerosol optical depth (AOD). AOD greatly affects the operational and economic performance of solar-powered desalination systems through photovoltaic soiling, membrane fouling, and water turbidity cycles. This study proposes a novel pipelined two-stage predictive modelling architecture: the first stage forecasts AOD using satellite-derived time series and meteorological data; the second stage uses the predicted AOD and other meteorological factors to predict desalination performance efficiency losses. The framework achieved 98% accuracy, and SHAP (SHapley Additive exPlanations) was used to reveal key drivers of system degradation. Furthermore, this study proposes a dust-aware rule-based control logic for desalination systems based on predicted values of AOD and solar efficiency. This control logic is used to adjust the desalination plant feed water pressure, adapt maintenance scheduling, and regulate energy source switching. To enhance the practical utility of the research findings, the predictive models and rule-based controls were packaged into an interactive dashboard for scenario and predictive analytics. This provides a management decision-support system for climate-adaptive planning.