Water, occurring naturally will disappear from many large cities around the world by circa 2025. Life needs water.In 2018, NASA’s satellites revealed major shifts in global freshwater due to climate change, human activity, and natural variability; US News identified ten densely populated urban cities in five continents, particularly – Africa, Asia, Australia, Europe, and South America where the resources of surface and/or ground water will diminish and/or disappear by circa 2025. In 2013, NASA stated that 1.8 billion people worldwide will face water scarcity by 2025 in its LandSat report. These climatic predictions are based on research/studies from accumulated data for more than thirty years from LandSat, and the United Nations Environmental Program that evidenced climate trends, interpreted cumulative chronologic climatic data, its relevance to current climatic conditions and corresponding verification of prediction-range vs. event-actuality of the data under consideration. While far from postulation, such permanent drought conditions are undesirable, unsustainable, currently real, and inevitable for the foreseeable future. It causes collateral damage to hydro-electric power generation systems worldwide, whose original design was based on continuously available water sources and proposed the useful functional life of the system. The ability to produce power using massive infrastructure installations of hydro-electric generation systems are now actively at risk. While the water scarcity crisis continues to worsen, a quest to accommodate the growing, burgeoning population in high rise buildings in large cities is increasing. The relationship between water and distinct architectural typologies have existed historically; however, it has now become necessary to develop new architectural solutions that are a departure from the past to resolve the water crises for people living in global cities in tall buildings. To alleviate the scarcity of water in medium to high rise buildings in high-density urban cities, a non-exclusive architectural design solution is explored in this thesis. Using the intersectionality of architectural design and components of structure to communicate with one another, a new architectural building typology is suggested that has a spacio-temporal response to its surrounding ecosystem. This response is hypothesized to perform the functions to capture and conserve water while simultaneously producing electricity through a synthesized architectural form. Secondary architectural design elements and products that support the new typology to succeed its function will be presented and elaborated. This thesis presents a new proposal toward a tall building design typology that signifies possible architectural design solutions that can be improvised and replicated with apposite design changes based on localized ecological conditions and available resources.