Gertik, A., & Karaman, A. (2023). The Fractal Approach in the Biomimetic Urban Design: Le Corbusier and Patrick Schumacher. Sustainability, 15(9), 7682.

A researcher Gertik from Faculty of Architecture, Near East University has yielded a study delving into the intersection of biomimetic design and urban planning. By synthesizing insights from various disciplines, the collaborative research addresses pressing environmental challenges such as biodiversity loss and pollution through nature-inspired design solutions. Focusing on biomimetic products, architecture, and urban design, the study emphasizes the imitation of nature’s dynamics to foster sustainability.

The research scrutinizes the role of fractal parameters in biomimetic design processes, examining how biomimicry can inform conceptual proposals and practical applications in urban design. Through meticulous analysis of biomimetic levels and fractal elements, the study compares the design approaches of influential figures like Le Corbusier and Patrick Schumacher.

One of the key findings is the potential of biomimetic-referenced fractal concepts to create sustainable and ecological urban environments. By emulating nature’s functions and scales, urban designs can integrate fractal forms and parametric designs to optimize resource usage and promote self-sufficiency. The study underscores the importance of understanding and interpreting nature’s internal dynamics to inform holistic city planning.

Furthermore, the research highlights the social and environmental benefits of biomimetic-focused fractal cities, which prioritize biodiversity preservation, energy efficiency, and interconnectivity. By incorporating organic gardens, terrace roof methods, and clean energy solutions, these cities aim to mitigate urban sprawl, reduce carbon emissions, and enhance overall livability.

The study suggests that biomimicry serves as a valuable reference for design disciplines, offering innovative approaches to address contemporary urban challenges. Through thoughtful integration of biomimetic principles and fractal designs, urban environments can evolve into sustainable, harmonious spaces that coexist synergistically with nature. This research lays the groundwork for future advancements in biomimetic urban design, paving the way for more resilient and environmentally conscious cities.

More Information:

https://www.mdpi.com/2071-1050/15/9/7682