Optimal Persistence Reveals Hidden Topology in Complex Energy Landscapes

Abstract

Infinite persistence marks the topological transition. For finite persistence, the canyon-finding rate Gamma(taup) on the p=2 spherical spin glass forms an inverted-U profile, peaking at an optimal taup*. At low temperature (T=0.05), taup* drops from 10 to 5 as N increases through 128, marking the discrete-to-quasi-continuous GOE crossover. For N=1024, the peak is flat between taup=5 and 6 within statistical uncertainties, preventing a more precise determination. For N>=128, the canyon width saturates at xieff=1, consistent with the measured taup*=5 when beta=0.4. At higher temperatures (T>=0.15), taup*=10 and beta(T) scales as 1/T, with temperature dependence entering only through vth = sqrt(2T). For T=0.10 and N>=128, high-resolution scans give taup*=8.0; for N<=64 at the same temperature, coarse scans place taup* in the range 8-10. Thus, optimal persistence reveals the hidden topology of the landscape-a principle expected to be generic in disordered landscapes with entropic bottlenecks.