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Auteurs principaux: Gräßer, Timo, Hahn, Thomas, Uhrig, Götz S.
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2403.10465
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author Gräßer, Timo
Hahn, Thomas
Uhrig, Götz S.
author_facet Gräßer, Timo
Hahn, Thomas
Uhrig, Götz S.
contents A recently developed dynamic mean-field theory for disordered spins (spinDMFT) is shown to capture the spin dynamics of nuclear spins very well. The key quantities are the spin autocorrelations. In order to compute the free induction decay (FID), pair correlations are needed in addition. They can be computed on spin clusters of moderate size which are coupled to the dynamic mean fields determined in a first step by spinDMFT. We dub this versatile approach non-local spinDMFT (nl-spinDMFT). It is a particular asset of nl-spinDMFT that one knows from where the contributions to the FID stem. We illustrate the strengths of nl-spinDMFT in comparison to experimental data for CaF$_2$. Furthermore, spinDMFT provides the dynamic mean fields explaining the FID of the nuclear spins of $^{13}$C in adamantane up to some static noise. The spin Hahn echo in adamantane is free from effects of static noise and agrees excellently with the spinDMFT results without further fitting.
format Preprint
id arxiv_https___arxiv_org_abs_2403_10465
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Microscopic understanding of NMR signals by dynamic mean-field theory for spins
Gräßer, Timo
Hahn, Thomas
Uhrig, Götz S.
Statistical Mechanics
Quantum Physics
A recently developed dynamic mean-field theory for disordered spins (spinDMFT) is shown to capture the spin dynamics of nuclear spins very well. The key quantities are the spin autocorrelations. In order to compute the free induction decay (FID), pair correlations are needed in addition. They can be computed on spin clusters of moderate size which are coupled to the dynamic mean fields determined in a first step by spinDMFT. We dub this versatile approach non-local spinDMFT (nl-spinDMFT). It is a particular asset of nl-spinDMFT that one knows from where the contributions to the FID stem. We illustrate the strengths of nl-spinDMFT in comparison to experimental data for CaF$_2$. Furthermore, spinDMFT provides the dynamic mean fields explaining the FID of the nuclear spins of $^{13}$C in adamantane up to some static noise. The spin Hahn echo in adamantane is free from effects of static noise and agrees excellently with the spinDMFT results without further fitting.
title Microscopic understanding of NMR signals by dynamic mean-field theory for spins
topic Statistical Mechanics
Quantum Physics
url https://arxiv.org/abs/2403.10465