Related papers: Optimal energy storage in the Tavis-Cummings quantum battery

Optimal energy storage in the Tavis-Cummings quantum battery

URL: http://arxiv.org/abs/2312.13444v2
Date: Mon, 8 Jan 2024 17:19:50 GMT
Title: Optimal energy storage in the Tavis-Cummings quantum battery
Authors: Hui-Yu Yang, Hai-Long Shi, Qing-Kun Wan, Kun Zhang, Xiao-Hui Wang, and Wen-Li Yang
Abstract summary: The Tavis-Cummings (TC) model serves as a natural physical realization of a quantum battery. In this study, we introduce the invariant subspace method to effectively represent the quantum dynamics of the TC battery.
Score: 11.061126692312946
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The Tavis-Cummings (TC) model, which serves as a natural physical realization of a quantum battery, comprises $N_b$ atoms as battery cells that collectively interact with a shared photon field, functioning as the charger, initially containing $n_0$ photons. In this study, we introduce the invariant subspace method to effectively represent the quantum dynamics of the TC battery. Our findings indicate that in the limiting case of $n_0\!\gg\! N_b$ or $N_b\!\gg\! n_0$, a distinct SU(2) symmetry emerges in the dynamics, thereby ensuring the realization of optimal energy storage. We also establish a negative relationship between the battery-charger entanglement and the energy storage capacity. As a result, we demonstrate that the asymptotically optimal energy storage can be achieved in the scenario where $N_b\!=\!n_0\!\gg\! 1$. Our approach not only enhances our comprehension of the algebraic structure inherent in the TC model but also contributes to the broader theoretical framework of quantum batteries. Furthermore, it provides crucial insights into the relation between energy transfer and quantum correlations.

Related papers

Large collective power enhancement in dissipative charging of a quantum battery [0.0]
We consider a model for a quantum battery consisting of a collection of $N$ two-level atoms driven by a classical field and decaying to a common reservoir. In the extensive regime, where the energy $E$ scales as $N$ and the fluctuations $Delta E/E to 0$, our dissipative charging protocol yields a power proportional to $N2$, a scaling that cannot be achieved in this regime by Hamiltonian protocols.
arXiv Detail & Related papers (2024-12-13T22:02:46Z)
Optimal energy storage and collective charging speedup in the central-spin quantum battery [10.375556905286519]
Quantum batteries (QBs) exploit principles of quantum mechanics to accelerate the charging process and aim to achieve optimal energy storage. In this work, we analytically investigate a central-spin QB model in which $N_b$ spin-1/2 battery cells interact with $N_c$ spin-1/2 charger units. Our results highlight the crucial role of emergent SU(2) symmetry in providing an analytical understanding of non-equilibrium charging dynamics in QBs.
arXiv Detail & Related papers (2024-11-02T08:23:52Z)
Topological Quantum Batteries [0.3749861135832073]
We propose an innovative design for quantum batteries (QBs) that involves coupling two-level systems to a topological photonic waveguide. We analytically explore the thermodynamic performances of QBs. Our findings offer valuable guidance for improving quantum battery performance through structured reservoir engineering.
arXiv Detail & Related papers (2024-05-06T17:50:35Z)
Neutron-nucleus dynamics simulations for quantum computers [49.369935809497214]
We develop a novel quantum algorithm for neutron-nucleus simulations with general potentials. It provides acceptable bound-state energies even in the presence of noise, through the noise-resilient training method. We introduce a new commutativity scheme called distance-grouped commutativity (DGC) and compare its performance with the well-known qubit-commutativity scheme.
arXiv Detail & Related papers (2024-02-22T16:33:48Z)
Quantum Algorithms for Simulating Nuclear Effective Field Theories [40.83664249192338]
We use state-of-the-art Hamiltonian-simulation methods to estimate the qubit and gate costs to simulate low-energy effective field theories (EFTs) of nuclear physics. We demonstrate how symmetries of the low-energy nuclear Hamiltonians can be utilized to obtain tighter error bounds on the simulation algorithm.
arXiv Detail & Related papers (2023-12-08T20:09:28Z)
Variational-quantum-eigensolver-inspired optimization for spin-chain work extraction [39.58317527488534]
Energy extraction from quantum sources is a key task to develop new quantum devices such as quantum batteries. One of the main issues to fully extract energy from the quantum source is the assumption that any unitary operation can be done on the system. We propose an approach to optimize the extractable energy inspired by the variational quantum eigensolver (VQE) algorithm.
arXiv Detail & Related papers (2023-10-11T15:59:54Z)
Quantum battery based on dipole-dipole interaction and external driving field [2.3274138116397727]
We propose an efficient charging quantum battery achieved by considering an extension Dicke model with dipole-dipole interaction and an external driving field. The maximum stored energy and maximum charging power are investigated by varying the number of atoms. In addition, the maximum charging power approximately satisfies a superlinear scaling relation $P_rm maxvarproptobeta Nalpha$, where the quantum advantage $alpha=1.6$ can be reached via optimizing the parameters.
arXiv Detail & Related papers (2023-05-05T05:49:39Z)
Vacuum enhanced charging of a quantum battery [0.0]
We show how a purely quantum effect related to the vacuum of the electromagnetic field can enhance the charging of a quantum battery. In particular, we demonstrate how an anti-Jaynes Cummings interaction can be used to increase the stored energy of an effective two-level atom.
arXiv Detail & Related papers (2023-01-31T13:54:14Z)
Studying chirality imbalance with quantum algorithms [62.997667081978825]
We employ the (1+1) dimensional Nambu-Jona-Lasinio (NJL) model to study the chiral phase structure and chirality charge density of strongly interacting matter. By performing the Quantum imaginary time evolution (QITE) algorithm, we simulate the (1+1) dimensional NJL model on the lattice at various temperature $T$ and chemical potentials $mu$, $mu_5$.
arXiv Detail & Related papers (2022-10-06T17:12:33Z)
Mesoscopic quantum superposition states of weakly-coupled matter-wave solitons [58.720142291102135]
We establish quantum features of an atomic soliton Josephson junction (SJJ) device. We show that the SJJ-model in quantum domain exhibits unusual features due to its effective nonlinear strength proportional to the square of total particle number. We have shown that the obtained quantum state is more resistant to few particle losses from the condensates if tiny components of entangled Fock states are present.
arXiv Detail & Related papers (2020-11-26T09:26:19Z)
Method of spectral Green functions in driven open quantum dynamics [77.34726150561087]
A novel method based on spectral Green functions is presented for the simulation of driven open quantum dynamics. The formalism shows remarkable analogies to the use of Green functions in quantum field theory. The method dramatically reduces computational cost compared with simulations based on solving the full master equation.
arXiv Detail & Related papers (2020-06-04T09:41:08Z)

This list is automatically generated from the titles and abstracts of the papers in this site.