We introduce a quantum decomposition algorithm (QDA) that decomposes the problem $\frac{\partial \rho}{\partial t}=\mathcal{L}\rho=\lambda \rho$ into a summation of eigenvalues times phase-space variables. One interesting feature of QDA stems from its ability to simulate damped spin systems by means of pure quantum harmonic oscillators adjusted with the eigenvalues of the original eigenvalue problem. We test the proposed algorithm in the case of undriven qubit with spontaneous emission and dephasing.Comment: 11 page
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The hierarchical equations of motion (HEOM), derived from the exact Feynman-Vernon path integral, is...
The theory of quantum stochastic calculus is used to expand the traditional Ghirardi-Rimini-Weber th...
This article is a brief introduction to quantum algorithms for the eigenvalue problem in quantum man...
The Schrieffer-Wolff transformation aims to solve degenerate perturbation problems and give an effec...
Our starting point is a stochastic decomposition scheme to study dissipative dynamics of an open sys...
We consider open quantum systems whose dynamics is governed by a time-independent Markovian Lindblad...
We experimentally implement the Sz.-Nagy dilation algorithm to simulate open quantum dynamics on an ...
Quantum dynamical systems typically deal with huge num-bers of degrees of freedom, particularly func...
Recently J. M. Arrazola et al. [Phys. Rev. A 100, 032306 (2019)] proposed a quantum algorithm for so...
The unavoidable coupling of quantum systems to external degrees of freedom leads to dissipative (non...
We establish an efficient approximation algorithm for the partition functions of a class of quantum ...
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We propose an energy-driven stochastic master equation for the density matrix as a dynamical model f...
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The theory of quantum stochastic calculus is used to expand the traditional Ghirardi-Rimini-Weber th...
This article is a brief introduction to quantum algorithms for the eigenvalue problem in quantum man...