A quantum Monte Carlo approach using the correlation density matrix detects dominant correlations in many-body systems without prior knowledge.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
verdicts
UNVERDICTED 3representative citing papers
Strong symmetries in open quantum systems always break spontaneously to weak symmetry or completely, producing gapless Goldstone modes, charge diffusion, and time crystalline order in some cases.
Quantum frustration protects the qubit from Ohmic noise and some sub-Ohmic noise but fails against common 1/f noise, causing spontaneous symmetry breaking and decoherence.
citing papers explorer
-
Detecting the Largest Correlations using the Correlation Density Matrix: a Quantum Monte Carlo Approach
A quantum Monte Carlo approach using the correlation density matrix detects dominant correlations in many-body systems without prior knowledge.
-
Spontaneous symmetry breaking in open quantum systems: strong, weak, and strong-to-weak
Strong symmetries in open quantum systems always break spontaneously to weak symmetry or completely, producing gapless Goldstone modes, charge diffusion, and time crystalline order in some cases.
-
Quantum Frustration as a Protection Mechanism in Non-Topological Majorana Qubits
Quantum frustration protects the qubit from Ohmic noise and some sub-Ohmic noise but fails against common 1/f noise, causing spontaneous symmetry breaking and decoherence.