Applications of restricted near-term superconducting qubit architectures: Using quantum control to reach quantum advantage
COFFEE_KLATCH · Invited
Abstract
While universal quantum computers certainly will have to be fault tolerant, there is the alternative line of thinking to demonstrate quantum advantage on near-term hardware, with limited number of gates, qubits, and connectivity. This can be achieved by careful co-design of hardware, algorithms, and controls.
I will describe a specific application of this idea, a quantum subroutine to the classical variational Cluster algorithm for the Fermi Hubbard model [1] . This approach can simulate an infinite Hubbard lattice at nonzero temperature with limited resources [2].
One way to make this algorithm maximally effective is the judicious use of one-shot implementations of important gate. To this end, we introduce the iFREDKIN [3] - a three qubit gate that is important in this type of application and that can be implemented in one shot in superconducting qubits with the aid of pulse shaping [4]. We will show further application of exchange-based gates in 1d architectures [5].
inspired by classical computational physics, we will show how to benchmark conservation laws efficiently [6].
[1] P.-L. Dallaire-Demers and F. K. Wilhelm, Phys. Rev. A. 93, 032303 (2016)
[2] P.-L. Dallaire-Demers and F. K. Wilhelm, Phys. Rev. A. 94, 062304 (2016)
[3] P.J. Liebermann, P.-L. Dallaire-Demers, F.K. Wilhelm, arXiv:1701.07870
[4] S. Machnes, D.J. Tannor, F. K. Wilhelm and E. Assémat, arXiv:1507.04261
[5] F. Motzoi, M. P. Kaicher, and F. K. Wilhelm, Phys. Rev. Lett. 119, 160503 (2017)
[6] T. Chasseur, F. Motzoi, M. Kaicher, P.-L. Dallaire-Demers, F.K. Wilhelm, arXiv:1710.04563
I will describe a specific application of this idea, a quantum subroutine to the classical variational Cluster algorithm for the Fermi Hubbard model [1] . This approach can simulate an infinite Hubbard lattice at nonzero temperature with limited resources [2].
One way to make this algorithm maximally effective is the judicious use of one-shot implementations of important gate. To this end, we introduce the iFREDKIN [3] - a three qubit gate that is important in this type of application and that can be implemented in one shot in superconducting qubits with the aid of pulse shaping [4]. We will show further application of exchange-based gates in 1d architectures [5].
inspired by classical computational physics, we will show how to benchmark conservation laws efficiently [6].
[1] P.-L. Dallaire-Demers and F. K. Wilhelm, Phys. Rev. A. 93, 032303 (2016)
[2] P.-L. Dallaire-Demers and F. K. Wilhelm, Phys. Rev. A. 94, 062304 (2016)
[3] P.J. Liebermann, P.-L. Dallaire-Demers, F.K. Wilhelm, arXiv:1701.07870
[4] S. Machnes, D.J. Tannor, F. K. Wilhelm and E. Assémat, arXiv:1507.04261
[5] F. Motzoi, M. P. Kaicher, and F. K. Wilhelm, Phys. Rev. Lett. 119, 160503 (2017)
[6] T. Chasseur, F. Motzoi, M. Kaicher, P.-L. Dallaire-Demers, F.K. Wilhelm, arXiv:1710.04563
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Presenters
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Frank Wilhelm
- Theoretical Physics, Saarland University
- Physics, Univ des Saarlandes
- Saarland University
- Theoretical physics, Saarland university
- Theoretical Physics, Universität des Saarlandes