VQE calculations on a NISQ era trapped ion quantum computer using a multireference unitary coupled cluster ansatz: application to the BeH$_2$ insertion problem
- URL: http://arxiv.org/abs/2504.07037v1
- Date: Wed, 09 Apr 2025 16:52:37 GMT
- Title: VQE calculations on a NISQ era trapped ion quantum computer using a multireference unitary coupled cluster ansatz: application to the BeH$_2$ insertion problem
- Authors: Palak Chawla, Disha Shetty, Peniel Bertrand Tsemo, Kenji Sugisaki, Jordi Riu, Jan Nogue, Debashis Mukherjee, V. S. Prasannaa,
- Abstract summary: We report the ground state energy of the BeH$ Forte$ molecule in a geometry where strong correlation effects are significant.<n>In order to carry out our intended 12-qubit computation on a noisy intermediate scale quantum era trapped ion hardware, we perform a series of resource reduction techniques.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: In this study, we employ the variational quantum eigensolver algorithm with a multireference unitary coupled cluster ansatz to report the ground state energy of the BeH$_2$ molecule in a geometry where strong correlation effects are significant. We consider the two most important determinants in the construction of the reference state for our ansatz. Furthermore, in order to carry out our intended 12-qubit computation on a noisy intermediate scale quantum era trapped ion hardware (the commercially available IonQ Forte-I), we perform a series of resource reduction techniques to a. decrease the number of two-qubit gates by 99.84% (from 12515 to 20 two-qubit gates) relative to the unoptimized circuit, and b. reduce the number of measurements via the idea of supercliques, while losing 2.69% in the obtained ground state energy (with error mitigation and post-selection) relative to that computed classically for the same resource-optimized problem setting.
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