Speaker
Description
Quantum simulations offer a promising path toward understanding fermionic quantum many-body systems without the limitations of exponential scaling. In this talk, I will present ongoing efforts to simulate various quantum algorithms designed to address nuclear systems within the shell model framework.
I will begin by discussing hybrid variational algorithms, highlighting our estimates of the quantum resources required for a range of nuclear systems [1,2]. I will then explore predictions for nuclear entanglement properties [3] and how these can be leveraged in quantum computing applications [4].
Finally, I may introduce our recent proposal for an adiabatic quantum algorithm tailored to solving the nuclear shell model [5].
[1] A. Pérez-Obiol et al., Sci. Rep. 13, 12291 (2023), arXiv:2302.03641.
[2] M. Carrasco-Codina et al., arXiv:2507.13819.
[3] A. Pérez-Obiol et al., Eur. Phys. J. A 59, 240 (2023), arXiv:2307.05197.
[4] A. Pérez-Obiol et al., arXiv:2409.04510.
[5] E. Costa et al., arXiv:2411.06954 (accepted in SciPost).
