Qiantan Hong scite author profile

Based on a kinematic approach in defining a geometric phase for a density matrix, we define the generalized Loschmidt overlap amplitude (GLOA) for an open system for arbitrary quantum evolution. The GLOA reduces to the Loschmidt overlap amplitude (LOA) with a modified dynamic phase for unitary evolution of a pure state, with the argument of the GLOA well-defined by the geometric phase, thus possessing similar physical interpretation to that of the LOA. The rate function for the GLOA exhibits non-analyticity at a critical time, which corresponds to the dynamical quantum phase transition. We observe that the dynamical quantum phase transition related to GLOA is not destroyed under a finite temperature and weak enough dissipation. In particular, we find that a new type of dynamical quantum phase transition emerges in a dissipation system. The proposed GLOA provides a powerful tool in the investigation of a dynamical quantum phase transition in an arbitrary quantum system, which not only can characterize the robustness of the dynamical quantum phase transition but also can be used to search for new transitions.

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Diagonal entropy in many-body systems: Volume effect and quantum phase transitions

Wang

Sun

Zeng

et al. 2020

Physics Letters A

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We investigate the diagonal entropy of the ground state of quantum many-body systems. Diagonal entropy is concerning about only the diagonal form of the ground state reduced density matrix, which can be obtained more easily in comparison to the whole reduced density matrix. We show that the diagonal entropy can be represented as a volume term plus a logarithm term on the number of spins and a constant term. Remarkably, the diagonal entropy provides signatures of all quantum phase transitions for the studied XY-model. The quantum phase transitions characterized by diagonal entropy agree well with the phase diagram. Besides, by combining the entanglement entropy and diagonal entropy, we naturally find the relative entropy of quantum coherence. Our findings show that the diagonal entropy contains rich physics and is worth exploring in studying various quantum systems.

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A Universal Quantum Computing Virtual Machine

Hong¹,

Ge²,

Wang³

et al. 2018

Preprint

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A medium-scale quantum computer with full universal quantum computing capability is necessary for various practical aims and testing applications. Here we report a 34-qubit quantum virtual machine (QtVM) based on a medium server. Our QtVM can run quantum assembly language with graphic interfaces. The QtVM is implemented with single qubit rotation gate, single to multiple controlled NOT gates to realize the universal quantum computation. Remarkably, it can realize a series of basic functions, such as, the "if" conditional programming language based on single-shot projective measurement results, "for" iteration programming language, build in arithmetic calculation. The measurement can be single-shot and arbitrary number of multi-shot types. In addition, there is in principle no limitation on number of logic gates implemented for quantum computation. By using QtVM, we demonstrate the simulation of dynamical quantum phase transition of transverse field Ising model by quantum circuits, where 34 qubits with one million gates are realized. We also show the realization of programmable Shor algorithm for factoring 15 and 35.

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Qiantan Hong

Dynamical quantum phase transition for mixed states in open systems

Diagonal entropy in many-body systems: Volume effect and quantum phase transitions

A Universal Quantum Computing Virtual Machine

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