Inspired by the recent work Macci et al. (2021), we prove a non-universal non-central Moderate Deviation Principle for the nodal length of arithmetic random waves (Gaussian Laplace eigenfunctions on the standard flat torus) both on the whole manifold and on shrinking toral domains. Second order fluctuations for the latter were established by Marinucci et al. (2016) and Benatar et al. (2020) respectively, by means of chaotic expansions, number theoretical estimates and full correlation phenomena. Our proof is simple and relies on the interplay between the long memory behavior of arithmetic random waves and the chaotic expansion of the nodal length, as well as on well-known techniques in Large Deviation theory (the contraction principle and the concept of exponential equivalence).
Macci, C., Rossi, M., Vidotto, A. (2024). Non-universal moderate deviation principle for the nodal length of arithmetic Random Waves. ALEA, 21(2), 1601-1624 [10.30757/ALEA.v21-60].
Non-universal moderate deviation principle for the nodal length of arithmetic Random Waves
Macci C.;
2024-01-01
Abstract
Inspired by the recent work Macci et al. (2021), we prove a non-universal non-central Moderate Deviation Principle for the nodal length of arithmetic random waves (Gaussian Laplace eigenfunctions on the standard flat torus) both on the whole manifold and on shrinking toral domains. Second order fluctuations for the latter were established by Marinucci et al. (2016) and Benatar et al. (2020) respectively, by means of chaotic expansions, number theoretical estimates and full correlation phenomena. Our proof is simple and relies on the interplay between the long memory behavior of arithmetic random waves and the chaotic expansion of the nodal length, as well as on well-known techniques in Large Deviation theory (the contraction principle and the concept of exponential equivalence).I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
