Quantum computing's unique capabilities are poised to revolutionize research in the built environment and urban microclimate, leveraging superposition and entanglement to tackle complex problems. By harnessing these principles, quantum computers can optimize building design and energy efficiency, potentially leading to significant reductions in energy consumption. The application of quantum computing in this field may also enable more accurate simulations of urban microclimates, allowing for better planning and management of cities. As quantum computing continues to advance, its potential to disrupt traditional computation and cryptography is becoming increasingly evident1. This has significant implications for various fields, including cybersecurity and data protection. So what matters to practitioners is that quantum computing's emergence demands a reassessment of existing assumptions about computational power and its potential to solve complex problems, ultimately driving innovation in multiple disciplines.