PREreview of The New Era of Architectural Design with the Use of Quantum Technology

The New Era of Architectural Design with the Use of Quantum Technology presents a structured and forward-looking discussion on the intersection of architecture and quantum computing. The manuscript outlines how advances in quantum algorithms, simulations, and computational speed can improve key aspects of the design and construction process, such as material innovation, structural performance, energy optimization, and logistics management.

The text is supported by timely examples, including the PsiQuantum facility, which links theoretical potential to emerging applications. These case studies enhance the credibility of the discussion and demonstrate that quantum integration is no longer speculative but entering the stage of early implementation.

The paper is particularly valuable in how it emphasizes interdisciplinary collaboration. By bringing together architects, engineers, computer scientists, and physicists, the author underlines the complex and cooperative nature of future technological progress in the built environment. This point is especially relevant given the increasing need for sustainable and data-driven design strategies.

The manuscript also addresses real challenges, including supply chain issues, cost factors, and regulatory barriers. These are presented with objectivity and balance. Rather than presenting a purely idealized view, the paper acknowledges obstacles and frames them within the context of long-term development.

Overall, the article encourages readers to consider new approaches to architectural design that respond to emerging scientific capabilities and environmental responsibilities.

Suggestions for Improvement

1. Clarify the role of quantum principles in architecture The manuscript would benefit from a clearer explanation of how quantum concepts such as superposition or entanglement translate into architectural design or simulation processes.

2. Expand architectural relevance in the case studies The PsiQuantum example is relevant but lacks architectural detail. Including information on spatial planning, environmental control, or structural adaptation would improve the connection to design practice.

3. Add visual representation Diagrams illustrating quantum-enhanced workflows or architectural patterns would help convey complex ideas more clearly.

4. Strengthen academic sources Supplementing general references with peer-reviewed architectural or engineering literature would improve scholarly rigor and support key arguments.

5. Include limitations of quantum computing A section on the current constraints of quantum technologies (hardware, error correction, cost) would provide important context for readers less familiar with the field.

6. Incorporate architectural education Since the manuscript encourages new forms of collaboration, a note on training or curriculum development for future professionals would strengthen its practical value.

7. Address ethical considerations Briefly acknowledging issues such as data governance, accessibility, and technological equity would round out the discussion, especially in the context of smart infrastructure.

Conclusion

This manuscript is a timely and relevant contribution to the ongoing dialogue on how architecture can evolve alongside scientific and technological progress. Its emphasis on quantum computing as a tool for material efficiency, structural innovation, and sustainability reflects an understanding of the future demands of the field. With further development in architectural specificity and academic support, this work can serve as a reference point for interdisciplinary research and applied design.

Competing interests

The author declares that they have no competing interests.