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Time-Dependent Pseudo-Hermitian Hamiltonians and a Hidden Geometric Aspect of Quantum Mechanics

Ali Mostafazadeh

2020Entropy30 citationsDOIOpen Access PDF

Abstract

A non-Hermitian operator H defined in a Hilbert space with inner product ⟨ · | · ⟩ may serve as the Hamiltonian for a unitary quantum system if it is η -pseudo-Hermitian for a metric operator (positive-definite automorphism) η . The latter defines the inner product ⟨ · | η · ⟩ of the physical Hilbert space H η of the system. For situations where some of the eigenstates of H depend on time, η becomes time-dependent. Therefore, the system has a non-stationary Hilbert space. Such quantum systems, which are also encountered in the study of quantum mechanics in cosmological backgrounds, suffer from a conflict between the unitarity of time evolution and the unobservability of the Hamiltonian. Their proper treatment requires a geometric framework which clarifies the notion of the energy observable and leads to a geometric extension of quantum mechanics (GEQM). We provide a general introduction to the subject, review some of the recent developments, offer a straightforward description of the Heisenberg-picture formulation of the dynamics for quantum systems having a time-dependent Hilbert space, and outline the Heisenberg-picture formulation of dynamics in GEQM.

Topics & Concepts

SIC-POVMHilbert spaceUnitarityPhysicsQuantum processOpen quantum systemObservableQuantum dynamicsClassical mechanicsPOVMQuantum mechanicsHamiltonian (control theory)Theoretical physicsQuantum operationQuantum dissipationQuantumQuantum statistical mechanicsQuantization (signal processing)MathematicsQuantum stateOperator (biology)Quantum systemMathematical formulation of quantum mechanicsUnitary stateQuantum probabilityUnitary operatorEigenvalues and eigenvectorsSymmetry in quantum mechanicsQuantum geometryPhysical systemFirst quantizationCanonical quantizationProduct (mathematics)Quantum informationCanonical quantum gravityQuantum Mechanics and Non-Hermitian PhysicsQuantum chaos and dynamical systemsSpectral Theory in Mathematical Physics