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Physics#Superconductivity, Quantum Transport, Non-Hermitian Physics🔬 ResearchAnalyzed: Jan 3, 2026 17:08

Non-Hermitian Josephson Junctions and Supercurrent

Published:Dec 31, 2025 09:33
1 min read
ArXiv

Analysis

This paper explores the electronic transport in a specific type of Josephson junction, focusing on the impact of non-Hermitian Hamiltonians. The key contribution is the identification of a novel current component arising from the imaginary part of Andreev levels, particularly relevant in the context of broken time-reversal symmetry. The paper proposes an experimental protocol to detect this effect, offering a way to probe non-Hermiticity in open junctions beyond the usual focus on exceptional points.
Reference

A novel contribution arises that is proportional to the phase derivative of the levels broadening.

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Research Paper#Quantum Physics, Lattice Gauge Theory, Non-Hermitian Systems🔬 ResearchAnalyzed: Jan 3, 2026 09:29

Non-Hermiticity Enhances Quantum Revivals in Lattice Gauge Theory

Published:Dec 30, 2025 19:00
1 min read
ArXiv

Analysis

This paper investigates the impact of non-Hermiticity on the PXP model, a U(1) lattice gauge theory. Contrary to expectations, the introduction of non-Hermiticity, specifically by differing spin-flip rates, enhances quantum revivals (oscillations) rather than suppressing them. This is a significant finding because it challenges the intuitive understanding of how non-Hermitian effects influence coherent phenomena in quantum systems and provides a new perspective on the stability of dynamically non-trivial modes.
Reference

The oscillations are instead *enhanced*, decaying much slower than in the PXP limit.

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Research Paper#Quantum Physics, Topological Physics, Non-Hermitian Physics, Entanglement🔬 ResearchAnalyzed: Jan 3, 2026 16:49

Entanglement Dynamics in Non-Hermitian Topological Systems

Published:Dec 30, 2025 09:35
1 min read
ArXiv

Analysis

This paper investigates the interplay of topology and non-Hermiticity in quantum systems, focusing on how these properties influence entanglement dynamics. It's significant because it provides a framework for understanding and controlling entanglement evolution, which is crucial for quantum information processing. The use of both theoretical analysis and experimental validation (acoustic analog platform) strengthens the findings and offers a programmable approach to manipulate entanglement and transport.
Reference

Skin-like dynamics exhibit periodic information shuttling with finite, oscillatory EE, while edge-like dynamics lead to complete EE suppression.

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Research#Quantum🔬 ResearchAnalyzed: Jan 10, 2026 08:33

Exploiting Non-Hermiticity for Enhanced Quantum Communication

Published:Dec 22, 2025 15:44
1 min read
ArXiv

Analysis

This research explores a novel approach to quantum state transfer, potentially improving efficiency. The focus on non-Hermitian systems suggests a move towards innovative quantum technologies.
Reference

The article's context revolves around the application of non-Hermiticity.

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