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Quantum computing of the $^6$Li nucleus via ordered unitary coupled cluster

The variational quantum eigensolver (VQE) is an algorithm to compute ground and excited state energy of quantum many-body systems. A key component of the algorithm and an active research area is the construction of a parametrized trial wave function—a so-called variational ansatz. The wave function...

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Detalles Bibliográficos
Autores principales: Kiss, Oriel, Grossi, Michele, Lougovski, Pavel, Sanchez, Federico, Vallecorsa, Sofia, Papenbrock, Thomas
Lenguaje:eng
Publicado: 2022
Materias:
Acceso en línea:https://dx.doi.org/10.1103/PhysRevC.106.034325
http://cds.cern.ch/record/2836035
Descripción
Sumario:The variational quantum eigensolver (VQE) is an algorithm to compute ground and excited state energy of quantum many-body systems. A key component of the algorithm and an active research area is the construction of a parametrized trial wave function—a so-called variational ansatz. The wave function parametrization should be expressive enough, i.e., represent the true eigenstate of a quantum system for some choice of parameter values. On the other hand, it should be trainable, i.e., the number of parameters should not grow exponentially with the size of the system. Here, we apply VQE to the problem of finding ground and excited state energies of the odd-odd nucleus <math><mmultiscripts><mi>Li</mi><mprescripts/><none/><mn>6</mn></mmultiscripts></math>. We study the effects of ordering fermionic excitation operators in the unitary coupled clusters ansatz on the VQE algorithm convergence by using only operators preserving the <math><msub><mi>J</mi><mi>z</mi></msub></math> quantum number. The accuracy is improved by two orders of magnitude in the case of descending order. We first compute optimal ansatz parameter values using a classical state-vector simulator with arbitrary measurement accuracy and then use those values to evaluate energy eigenstates of <math><mmultiscripts><mi>Li</mi><mprescripts/><none/><mn>6</mn></mmultiscripts></math> on a superconducting quantum chip from IBM. We post-process the results by using error mitigation techniques and are able to reproduce the exact energy with an error of <math><mrow><mn>3.8</mn><mo>%</mo></mrow></math> and <math><mrow><mn>0.1</mn><mo>%</mo></mrow></math> for the ground state and for the first excited state of <math><mmultiscripts><mi>Li</mi><mprescripts/><none/><mn>6</mn></mmultiscripts></math>, respectively.