Geometry of variational methods: dynamics of closed quantum systems

We present a systematic geometric framework to study closed quantum systems based on suitably chosen variational families. For the purpose of (A) real time evolution, (B) excitation spectra, (C) spectral functions and (D) imaginary time evolution, we show how the geometric approach highlights the necessity to distinguish between two classes of manifolds: Kähler and non-Kähler. Traditional variational methods typically require the variational family to be a Kähler manifold, where multiplication by the imaginary unit preserves the tangent spaces. This covers the vast majority of cases studied in the literature. However, recently proposed classes of generalized Gaussian states make it necessary to also include the non-Kähler case, which has already been encountered occasionally. We illustrate our approach in detail with a range of concrete examples where the geometric structures of the considered manifolds are particularly relevant. These go from Gaussian states and group theoretic coherent states to generalized Gaussian states.

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A Geometric Approach to Time Evolution Operators of Lie Quantum Systems

International Journal of Theoretical Physics ◽

10.1007/s10773-008-9909-5 ◽

2008 ◽

Vol 48 (5) ◽

pp. 1379-1404 ◽

Cited By ~ 6

Author(s):

José F. Cariñena ◽

Javier de Lucas ◽

Arturo Ramos

Keyword(s):

Time Evolution ◽

Geometric Approach ◽

Quantum Systems ◽

Evolution Operators

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Quantum confinement in 1D systems through an imaginary-time evolution method

Modern Physics Letters A ◽

10.1142/s021773231550176x ◽

2015 ◽

Vol 30 (37) ◽

pp. 1550176 ◽

Cited By ~ 6

Author(s):

Amlan K. Roy

Keyword(s):

Time Evolution ◽

Excited States ◽

Quantum Confinement ◽

Global Minimum ◽

Quantum Systems ◽

Attractive Potential ◽

Imaginary Time ◽

Expectation Values ◽

Expectation Value ◽

Orthogonality Constraint

Quantum confinement is studied by numerically solving time-dependent (TD) Schrödinger equation (SE). An imaginary-time evolution technique is employed in conjunction with the minimization of an expectation value, to reach the global minimum. Excited states are obtained by imposing the orthogonality constraint with all lower states. Applications are made on three important model quantum systems, namely, harmonic, repulsive and quartic oscillators; enclosed inside an impenetrable box. The resulting diffusion equation is solved using finite-difference method. Both symmetric and asymmetric confinement are considered for attractive potential; for others only symmetrical confinement. Accurate eigenvalue, eigenfunction and position expectation values are obtained, which show excellent agreement with existing literature results. Variation of energies with respect to box length is followed for small, intermediate and large sizes. In essence, a simple accurate and reliable method is proposed for confinement in quantum systems.

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Entanglement and entropy squeezing in the system of two qubits interacting with a two-mode field in the context of power low potentials

Scientific Reports ◽

10.1038/s41598-020-76059-5 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

E. M. Khalil ◽

K. Berrada ◽

S. Abdel-Khalek ◽

A. Al-Barakaty ◽

J. Peřina

Keyword(s):

Time Evolution ◽

Coherent States ◽

Population Inversion ◽

Quantum Systems ◽

Current Interest ◽

Potential Wells ◽

Entropy Squeezing ◽

Mode Field ◽

Quantized Fields ◽

Mode Pair

Abstract We study the dynamics of two non-stationary qubits, allowing for dipole-dipole and Ising-like interplays between them, coupled to quantized fields in the framework of two-mode pair coherent states of power-low potentials. We focus on three particular cases of the coherent states through the exponent parameter taken infinite square, triangular and harmonic potential wells. We examine the possible effects of such features on the evolution of some quantities of current interest, such as population inversion, entanglement among subsystems and squeezing entropy. We show how these quantities can be affected by the qubit-qubit interaction and exponent parameter during the time evolution for both cases of stationary and non-stationary qubits. The obtained results suggest insights about the capability of quantum systems composed of nonstationary qubits to maintain resources in comparison with stationary qubits.

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