Fractal Architecture as a Foundational Design Principle in Biomimetic Materials Engineering

Introducing Bio-Fractal Mimetics: Towards a Paradigm for Optimal Material Design This preprint originates from an undergraduate thesis in materials science, yet its implications may reach far beyond. While exploring biomimetics, I observed a fundamental limitation: most research focuses on mimicking biological shapes, not the structural principles beneath them. Through comprehensive analysis, I found that fractal geometry recurs across natural systems—enhancing efficiency, scalability, and resilience. To go beyond qualitative claims, I proposed a mathematical framework showing that fractal-based structures naturally yield optimal functional dimensions (e.g., 1.7, 2.1, 2.5, 2.8), each suited for a different purpose—exploration, absorption, circulation, etc. I demonstrate that these can be modeled with quadratic functions, implying that every fractal structure contains at least one performance-optimal dimension. This opens a path toward generalizable design laws in nanomaterials and soft systems. What began as a hypothesis from a student’s curiosity has developed into a possible theoretical foundation for next-generation material design.