B-VQE is a biorthogonal variational quantum eigensolver with exceptional-point detection and importance sampling that simulates non-Hermitian many-body models on NISQ hardware with reported energy errors below 5e-3.
Making sense of non-hermitian hamiltonians.Reports on Progress in Physics, 70(6): 947–1018, May 2007
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
years
2026 3verdicts
UNVERDICTED 3representative citing papers
A non-Hermitian XY model supplies decoupled idle levels for a quantum Otto engine, allowing the non-Hermitian parameter to control operation mode and raise efficiency.
A coefficient-based approach derives analytical phase boundaries and higher winding numbers in 1D non-Hermitian topological superconductors, verified via open-boundary spectra and disorder stability.
citing papers explorer
-
Exceptional-Point-Anchored Variational Quantum Eigensolver for Non-Hermitian Many-Body Phase Diagrams: Bridging Skin-Effect Topology and Entanglement Criticality on NISQ Hardware
B-VQE is a biorthogonal variational quantum eigensolver with exceptional-point detection and importance sampling that simulates non-Hermitian many-body models on NISQ hardware with reported energy errors below 5e-3.
-
Quantum Otto engine with decoupled idle levels in a non-Hermitian XY model
A non-Hermitian XY model supplies decoupled idle levels for a quantum Otto engine, allowing the non-Hermitian parameter to control operation mode and raise efficiency.
-
Higher-winding phases in one-dimensional non-Hermitian topological superconductors
A coefficient-based approach derives analytical phase boundaries and higher winding numbers in 1D non-Hermitian topological superconductors, verified via open-boundary spectra and disorder stability.