Related papers: Scaling of energy and power in a large quantum battery-charger model

Scaling of energy and power in a large quantum battery-charger model

URL: http://arxiv.org/abs/2208.10190v4
Date: Fri, 28 Oct 2022 04:45:25 GMT
Title: Scaling of energy and power in a large quantum battery-charger model
Authors: Lei Gao, Chen Cheng, Wen-Bin He, Rubem Mondaini, Xi-Wen Guan and Hai-Qing Lin
Abstract summary: We investigate a multi-qubit quantum battery-charger model, focusing on its potential emulation on a superconducting qubit chip. By checking a diverse set of system configurations, we classify the system size scalings of $E_Brm max$ and $P_Brm max$. Our work provides an overall guide for expected features in experiments of quantum batteries emulated in superconducting qubit platforms.
Score: 7.927685242174114
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We investigate a multi-qubit quantum battery-charger model, focusing on its potential emulation on a superconducting qubit chip. Using a large-spin representation, we first obtain the analytical form of the energy $E_B(t)$, power $P_B(t)$ and their maximum values, $E_B^{\rm max}$ and $P_B^{\rm max}$, of the battery part by means of the antiferromagnetic Holstein-Primakoff (AFM-HP) transformation within the low-energy approximation. In this case, our results show that superextensive scaling behavior of $P_B^{\rm max}$ ensues. By further combining these with the ones obtained via exact diagonalization (ED), we classify the dynamics of various physical quantities, including the entanglement between the battery and charger parts for system sizes encompassing over 10,000 qubits. Finally, by checking a diverse set of system configurations, including either a fixed battery size with growing number of charger qubits, or when both parts simultaneously grow, we classify the system size scalings of $E_B^{\rm max}$ and $P_B^{\rm max}$, relating it with the entanglement entropy in the system. In agreement with the analytical results, robust superextensive behavior of $P_B^{\rm max}$ is also observed in this case. Our work provides an overall guide for expected features in experiments of quantum batteries emulated in superconducting qubit platforms, in particular ones that exhibit long-range couplings.

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