Related papers: Quantum deleting and cloning in a pseudo-unitary system

Quantum deleting and cloning in a pseudo-unitary system

URL: http://arxiv.org/abs/2103.15353v1
Date: Mon, 29 Mar 2021 05:59:27 GMT
Title: Quantum deleting and cloning in a pseudo-unitary system
Authors: Yucheng Chen, Ming Gong, Peng Xue, Haidong Yuan, Chengjie Zhang
Abstract summary: We investigate the quantum deleting and cloning in a pseudo-unitary system. We show that it is possible to delete and clone a class of two different and nonorthogonal states. We simulate the pseudo-unitary operators in conventional quantum mechanics with post-selection.
Score: 20.489044283783358
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In conventional quantum mechanics, quantum no-deleting and no-cloning theorems indicate that two different and nonorthogonal states cannot be perfectly and deterministically deleted and cloned, respectively. Here, we investigate the quantum deleting and cloning in a pseudo-unitary system. We first present a pseudo-Hermitian Hamiltonian with real eigenvalues in a two-qubit system. By using the pseudo-unitary operators generated from this pseudo-Hermitian Hamiltonian, we show that it is possible to delete and clone a class of two different and nonorthogonal states, and it can be generalized to arbitrary two different and nonorthogonal pure qubit states. Furthermore, state discrimination, which is strongly related to quantum no-cloning theorem, is also discussed. Last but not least, we simulate the pseudo-unitary operators in conventional quantum mechanics with post-selection, and obtain the success probability of simulations. Pseudo-unitary operators are implemented with a limited efficiency due to the post-selections. Thus, the success probabilities of deleting and cloning in the simulation by conventional quantum mechanics are less than unity, which maintain the quantum no-deleting and no-cloning theorems.

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