Abstract
Static disorder in a three-dimensional crystal degrades the ideal ballistic dynamics until it produces a localized
regime. This metal-insulator transition is often preceded by coherent diffusion. By studying three paradigmatic
one-dimensional models, namely, the Harper-Hofstadter-Aubry-André and Fibonacci tight-binding chains, along
with the power-banded random matrix model, we show that whenever coherent diffusion is present, transport is
exceptionally stable against decoherent noise. This is completely at odds with what happens for coherently ballistic and localized dynamics, where the diffusion coefficient strongly depends on the environmental decoherence.
A universal dependence of the diffusion coefficient on the decoherence strength is analytically derived: The
diffusion coefficient remains almost decoherence independent until the coherence time becomes comparable to
the mean elastic scattering time. Thus, systems with a quantum diffusive regime could be used to design robust
quantum wires. Moreover, our results might shed light on the functionality of many biological systems, which
often operate at the border between the ballistic and localized regimes.
Original language | English |
---|---|
Pages (from-to) | 042213-042231 |
Number of pages | 19 |
Journal | Physical Review A |
Volume | 109 |
DOIs | |
Publication status | Published - 2024 |
Keywords
- quantum transport