Fourier Dimension in $C^{1+α}$ Parabolic Dynamics (2505.15468v1)

Abstract: We introduce a non-smooth non-linearity condition for $C^{1+\alpha}$ Markov iterated function systems motivated by the proof of power Fourier decay of nonlinear 2D Axiom A equilibrium states, which was inspired by recent advances in exponential mixing for 3D Anosov flows. We verify this condition for a class of $C^{1+\alpha}$ systems using fixed point theory in space of Cantor functions, which gives first examples of truly $C^{1+\alpha}$ IFSs with positive Fourier dimension for their attractors. Moreover, the proof method also applies in smoother parabolic Markov systems including Young tower codings leading also to power Fourier decay for conformal measures for Manneville-Pommeau maps, Lorenz maps arising from the Lorenz system, and Patterson-Sullivan measures for cusped hyperbolic surfaces, generalising the work of Bourgain and Dyatlov to geometrically finite groups with parabolic elements. The lack of smoothness preventing the traditional use of spectral gaps for transfer operators is replaced with multiscale oscillations of the derivatives on Cantor sets allowing us to reduce to exponential sums of products of random variables with finite exponential moments.