Related papers: Q$^2$Chemistry: A quantum computation platform for quantum chemistry

Q$^2$Chemistry: A quantum computation platform for quantum chemistry

URL: http://arxiv.org/abs/2208.10978v1
Date: Tue, 23 Aug 2022 13:50:46 GMT
Title: Q$^2$Chemistry: A quantum computation platform for quantum chemistry
Authors: Yi Fan, Jie Liu, Xiongzhi Zeng, Zhiqian Xu, Honghui Shang, Zhenyu Li, and Jinlong Yang
Abstract summary: We present Q$2$Chemistry, for developing quantum algorithms and quantum inspired classical algorithms in the field of quantum chemistry. Q$2$Chemistry generates quantum circuits according to a specific quantum algorithm already implemented in the package or newly developed by the users. The generated circuits can be dispatched to either a physical quantum computer, if available, or to the internal virtual quantum computer realized by simulating quantum circuit on classical supercomputers.
Score: 7.362240457595957
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Quantum computer provides new opportunities for quantum chemistry. In this article, we present a versatile, extensible, and efficient software package, named Q$^2$Chemistry, for developing quantum algorithms and quantum inspired classical algorithms in the field of quantum chemistry. In Q$^2$Chemistry, wave function and Hamiltonian can be conveniently mapped into the qubit space, then quantum circuits can be generated according to a specific quantum algorithm already implemented in the package or newly developed by the users. The generated circuits can be dispatched to either a physical quantum computer, if available, or to the internal virtual quantum computer realized by simulating quantum circuit on classical supercomputers. As demonstrated by our benchmark simulations with up to 72 qubit, Q$^2$Chemistry achieves excellent performance in simulating medium scale quantum circuits. Application of Q$^2$Chemistry to simulate molecules and periodic systems are given with performance analysis.

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