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Geothermal energy, with a global installed capacity of 16.7 GW by 2023 and an annual generation of more than 97 TWh, is consolidating its position as a key pillar in the energy transition. From the pioneering Lardarello plant (1913) to The Geysers complex in California—the largest in the world with 1.5 GW of capacity—this energy source has demonstrated its potential to supply baseload electricity 24 hours a day, with a carbon footprint up to 10 times lower than fossil fuels. The article explores how the architectural design of these plants integrates geological, environmental, and technological factors. Systems such as binary cycles—which operate at 90°C and reduce emissions by 95%—allow the exploitation of low-temperature resources, expanding their applicability to non-volcanic regions. However, challenges remain: reservoir exploration is 30-40% uncertain, and initial costs exceed $4,500 per installed kW, according to the U.S. Department of Energy. Iconic cases like The Geysers illustrate innovative solutions. Since 2003, its recharge project with treated wastewater (11 million gallons/day) has revitalized the reservoir, extending its lifespan by decades. This circular economy approach not only optimizes resources but also reduces water conflicts in arid areas. The future points to disruptive designs: Enhanced Geothermal Systems (EGS), which could increase global potential tenfold by enabling dry reservoirs, and urban heating districts with heat pumps, capable of providing heating at -20°C. By 2030, drilling innovations—such as smart drill bits and robotics—could reduce costs by 50%, accelerating adoption. In a world that needs to double clean energy by 2040, geothermal energy is emerging not only as a renewable source, but as an architectural canvas where engineering and sustainability converge to redefine the energy landscape. Its evolution will depend on creatively overcoming technical barriers, transforming the Earth's heat into the cornerstone of a decarbonized era.