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We present a numerical study of the many-body localization (MBL) phenomenon in the high-temperature limit within an anisotropic Heisenberg model with random local fields. Taking the dynamical spin conductivity () as the test quantity, we investigate the full frequency dependence of sample-to-sample fluctuations and their scaling properties as a function of the system size L28 and the frequency resolution. We identify differences between the general interacting case >0 and the anisotropy =0, the latter corresponding to the standard Anderson localization. Except for the extreme MBL case when the relative sample-to-sample fluctuations became large, numerical results allow for the extraction of the low- dependence of the conductivity. Results for the dc value ₀ indicate a crossover into the MBL regime, i. e. , an exponential-like variation with the disorder strength W. For the same regime, our numerical analysis indicates that the low-frequency exponent exhibits a small departure from 1 only.
Barišić et al. (Wed,) studied this question.
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