We propose a procedure to obtain exact analytical solutions to the time-dependent Schrödinger equations involving explicit time-dependent Hermitian Hamitonians from solutions to timeindependent non-Hermitian Hamiltonian systems and the time-dependent Dyson relation together with the time-dependent quasi-Hermiticity relation. We illustrate the working of this method for a simple Hermitian Rabi-type model by relating it to a non-Hermitian time-independent system corresponding to the one-site lattice Yang-Lee model. 03.65.-w,03.65.Aa:
We demonstrate that non-Hermitian Hamiltonian systems with spontaneously
broken PT-symmetry and partially complex eigenvalue spectrum can be made
meaningful in a quantum mechanical sense when introducing some explicit
time-dependence into their parameters. Exploiting the fact that explicitly
time-dependent non-Hermitian Hamitonians are unobservable and not identical to
the energy operators in such a scenario, we show that their corresponding
non-Hermitian energy operators develop a different type of PT-symmetry from the
Hamiltonians that ensures the reality of their energy spectra. For this purpose
we analytically solve the fully time-dependent Dyson equation with all
quantities involved being explicitly time-dependent giving rise to a
time-dependent metric. The key auxiliary equation to be solved for the two
level atomic system considered here is the nonlinear Ermakov-Pinney equation
with time-dependent coefficients.Comment: 12 pages, 2 figure
We provide exact analytical solutions for a two dimensional explicitly timedependent non-Hermitian quantum system. While the time-independent variant of the model studied is in the broken PT-symmetric phase for the entire range of the model parameters, and has therefore a partially complex energy eigenspectrum, its time-dependent version has real energy expectation values at all times. In our solution procedure we compare the two equivalent approaches of directly solving the time-dependent Dyson equation with one employing the Lewis-Riesenfeld method of invariants. We conclude that the latter approach simplifies the solution procedure due to the fact that the invariants of the non-Hermitian and Hermitian system are related to each other in a pseudo-Hermitian fashion, which in turn does not hold for their corresponding time-dependent Hamiltonians. Thus constructing invariants and subsequently using the pseudo-Hermiticity relation between them allows to compute the Dyson map and to solve the Dyson equation indirectly. In this way one can bypass to solve nonlinear differential equations, such as the dissipative Ermakov-Pinney equation emerging in our and many other systems.
We find a new effect for the behaviour of Von Neumann entropy. For this we derive the framework for describing Von Neumann entropy in non-Hermitian quantum systems and then apply it to a simple interacting P T symmetric bosonic system. We show that our model is well defined even in the P T broken regime with the introduction of a time-dependent metric and that it displays three distinct behaviours relating to the P T symmetry of the original time-independent Hamiltonian. When the symmetry is unbroken, the entropy undergoes rapid decay to zero (so-called "sudden death") with a subsequent revival. At the exceptional point it decays asymptotically to zero and when the symmetry is spontaneously broken it decays asymptotically to a finite constant value ("eternal life").
We propose time-dependent Darboux (supersymmetric) transformations that provide a scheme for the calculation of explicitly time-dependent solvable non-Hermitian partner Hamiltonians. Together with two Hermitian Hamilitonians the latter form a quadruple of Hamiltonians that are related by two time-dependent Dyson equations and two intertwining relations in form of a commutative diagram. Our construction is extended to the entire hierarchy of Hamiltonians obtained from time-dependent Darboux-Crum transformations. As an alternative approach we also discuss the intertwining relations for Lewis-Riesenfeld invariants for Hermitian as well as non-Hermitian Hamiltonians that reduce the time-dependent equations to auxiliary eigenvalue equations. The working of our propsals is discussed for a hierarchy of explicitly time-dependent rational, hyperbolic, Airy function and nonlocal potentials.
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