Scrambling dynamics in a nuclear spin system produce correlations yielding 33(2) dB signal enhancement and 18(1) dB metrological gain with 40(3) μrad phase sensitivity.
Dipolarly-Coupled Chaotic Quantum Spin Systems
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
We numerically study quantum chaos properties of long-range XXZ dipolar Hamiltonian spin systems. Two geometries are considered: (i) an open chain with 19 spins, (ii) a face-centered cubic lattice with 14 spins. Energy level-spacing distribution indicates that the three-dimensional geometry is highly chaotic, while the one-dimensional system is mildly chaotic for small chains, but has increasing chaoticity for larger chains. We also look at statistical properties of energy eigenvectors, and of one- and two-body local observables. Finally, we present some preliminary results on time-evolution, local spin dynamics and thermalization. Quantum chaos may have important implications for "scrambling" of quantum information, in both condensed matter systems and in astrophysical applications such as black holes.
fields
quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
-
Correlation-enhanced metrology from scrambling dynamics in a solid-state spin system
Scrambling dynamics in a nuclear spin system produce correlations yielding 33(2) dB signal enhancement and 18(1) dB metrological gain with 40(3) μrad phase sensitivity.