Related papers: Emergence of non-ergodic multifractal quantum states in geometrical fractals

Emergence of non-ergodic multifractal quantum states in geometrical fractals

URL: http://arxiv.org/abs/2410.18559v2
Date: Mon, 11 Nov 2024 17:09:25 GMT
Title: Emergence of non-ergodic multifractal quantum states in geometrical fractals
Authors: Fabio Salvati, Mikhail I. Katsnelson, Andrey A. Bagrov,
Abstract summary: Eigenstate multifractality, a hallmark of non-interacting disordered metals, is characterized by anomalous slow dynamics. We propose a novel approach to achieve non-ergodic multifractal states without disorder by iteratively introducing defects into a crystal lattice.
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Abstract: Eigenstate multifractality, a hallmark of non-interacting disordered metals which can potentially be observed in many-body localized states as well, is characterized by anomalous slow dynamics and appears relevant for many areas of quantum physics from measurement-driven systems to superconductivity. We propose a novel approach to achieve non-ergodic multifractal (NEM) states without disorder by iteratively introducing defects into a crystal lattice, reshaping it from a plain structure into fractal geometry. By comprehensive analysis of the Sierpi\'nski gasket case, we find a robust evidence of the emergence of NEM states that go beyond the conventional classification of quantum states and designate new pathways for quantum transport studies. We discuss potential experimental signatures of these states.

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