Intermittent Cauchy walks enable optimal 3D search across target shapes and sizes

Abstract

Target shape, not just size, plays a pivotal role in determining detectability during random search. We analyze intermittent L\'evy walks in three dimensions, and mathematically prove that the widely observed Cauchy strategy (L\'evy exponent μ = 2) uniquely achieves scale-invariant, near-optimal detection across a broad spectrum of target sizes and shapes. In a domain of volume n with boundary conditions, expected detection time for a convex target of surface area optimally scales as n/. Conversely, L\'evy strategies with μ < 2 are slow at detecting targets with large surface area-to-volume ratios, while those with μ > 2 excel at finding large elongated shapes but degrade as targets become wider. Our results further indicate a continuous geometric transition: volume dictates detection near μ = 1, ceding dominance to surface area as μ 2, after which surface area and elongation couple to govern detection. Ultimately, 3D search introduces a pronounced sensitivity to target shape that is absent in lower dimensions. Our work provides a rigorous foundation for the L\'evy flight foraging hypothesis in 3D by establishing the scale-invariant optimality of the Cauchy walk. Furthermore, our results reveal dimensionality-driven shape vulnerabilities and offer testable predictions for biological and engineered systems.

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