Yangchao Shen scite author profile

In classical computational chemistry, the coupled-cluster ansatz is one of the most commonly used ab initio methods, which is critically limited by its non-unitary nature. The unitary modification as an ideal solution to the problem is, however, extremely inefficient in classical conventional computation. Here, we provide the first experimental evidence that indeed the unitary version of the coupled cluster ansatz can be reliably performed in physical quantum system, a trapped ion system. We perform a simulation on the electronic structure of a molecular ion (HeH + ), where the ground-state energy surface curve is probed, energies of excited-states are studied and the bond-dissociation is simulated non-perturbatively. Our simulation takes advantages from quantum computation to overcome the intrinsic limitations in classical computation and our experimental results indicate that the method is promising for preparing molecular ground-states for quantum simulation.PACS numbers: 03.67. Ac, 31.15.Dv, 37.10.Ty, 42.50.Dv The central problem in quantum chemistry and molecular physics is to determine the electronic structure and the ground-state energy of atoms and molecules by solving the quantum many-body equations, which is generally intractable due to the exponential scaling to the size of the system. Quantum simulation [1][2][3][4][5][6] can provide the solution for such "exponential catastrophe" problem. The key ingredient of quantum molecular simulation consists of (i) ground (excited) -state preparation and (ii) energy estimation of the corresponding state [3,4]. Recently, the assessed costs for the energy estimation for a well-prepared ground-state in quantum computation have been immensely reduced [7][8][9][10][11], indicating that chemistry simulation can be one of the main applications of a quantum computer in near future. However, it is still remaining major obstacle to efficiently and reliably find the molecular ground state, which belongs to the class of extremely hard problems called Quantum Merlin Arthur, the quantum analog of NP-hard problem [12,13]. Recently various theoretical schemes for the ground-state problem have been proposed and proof-of principle experimental demonstrations have been performed including the adiabatic [14][15][16] and algorithmic preparations [17][18][19][20].For the ground-state problem, the developments of conventional quantum chemistry can be adopted to quantum computation. In computational chemistry, it has been the main focus to circumvent the problem by approximating the many-body Schrödinger equation and a series of theoretical and numerical methods have been developed. The coupled-cluster method is one of the most prominent ab initio methods for finding a molecular ground state and it is considered to be the current gold standard [21][22][23][24]. However, the coupled-cluster ansatz is built with non-unitary operation, which leads to drawbacks such as lacking a variational bound on the ground-state energy [22][23][24][25][26]. The unitary version of the coupled-clust...

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Global entangling gates on arbitrary ion qubits

Zhang

et al. 2019

Nature

122

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A quantum algorithm can be decomposed into a sequence consisting of single qubit and 2-qubit entangling gates. To optimize the decomposition and achieve more efficient construction of the quantum circuit, we can replace multiple 2-qubit gates with a single global entangling gate. Here, we propose and implement a scalable scheme to realize the global entangling gates on multiple 171 Yb + ion qubits by coupling to multiple motional modes through external fields. Such global gates require simultaneously decoupling of multiple motional modes and balancing of the coupling strengths for all the qubit-pairs at the gate time. To satisfy the complicated requirements, we develop a trapped-ion system with fully-independent control capability on each ion, and experimentally realize the global entangling gates. As examples, we utilize them to prepare the Greenberger-Horne-Zeilinger (GHZ) states in a single entangling operation, and successfully show the genuine multi-partite entanglements up to four qubits with the state fidelities over 93.4%. * luyao physics@163.com † kimkihwan@mail.tsinghua.edu.cn [1] Peter W Shor. Polynomial-time algorithms for prime factorization and discrete logarithms on a quantum computer. SIAM J.

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Quantum optical emulation of molecular vibronic spectroscopy using a trapped-ion device

Shen

Zhang

et al. 2018

Chem. Sci.

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Yangchao Shen

Quantum implementation of the unitary coupled cluster for simulating molecular electronic structure

Global entangling gates on arbitrary ion qubits

Quantum optical emulation of molecular vibronic spectroscopy using a trapped-ion device

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