An exponent-s dynamical Borel-Cantelli lemma and the waiting time problem
Abstract
Galatolo and Kim proved that the dynamical Borel-Cantelli property for decreasing sequences of balls is tightly connected with the waiting time problem. In systems where all such sequences are Borel-Cantelli, the time needed to enter a small ball B for the first time scales as μ(B)-1, and conversely, waiting time estimates yield Borel-Cantelli results for sequences of balls whose radii decrease in a controlled way. We extend this correspondence to the exponent-s setting introduced by Tseng. For s 1, the s-exponent monotone shrinking target property (sMSTP) requires the Borel-Cantelli conclusion only for decreasing sequences of centered balls satisfying the stronger divergence condition Σnμ(Bn)s=∞. We prove that sMSTP forces the lower waiting time exponent, measured on the scale of -μ(B(y,r)), to lie in the interval [1,s] almost everywhere. That a quantitative (s-strong) form of the property bounds the upper exponent by s and that, conversely, an exponent-s waiting time estimate implies the Borel-Cantelli property for decreasing sequences of centered balls whose radii obey the calibrated decay condition matching the critical divergence exponent s. We also obtain the corresponding quantitative orbit approximation statement n nβ\,d(Tnx,y)=0 for β<1/(s\,dμ(y)), show that the universal lower bound with exponent 1 pins the theory to s 1, and discuss sharpness on circle rotations, where by results of Kurzweil, Kim-Seo and Tseng the picture is governed by the Diophantine type of the rotation number.
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