Related papers: Generation and optimization of entanglement between atoms chirally coupled to spin cavities

Generation and optimization of entanglement between atoms chirally coupled to spin cavities

URL: http://arxiv.org/abs/2403.00264v2
Date: Sun, 05 Jan 2025 14:28:27 GMT
Title: Generation and optimization of entanglement between atoms chirally coupled to spin cavities
Authors: Jia-Bin You, Jian Feng Kong, Davit Aghamalyan, Wai-Keong Mok, Kian Hwee Lim, Jun Ye, Ching Eng Png, Francisco J. García-Vidal,
Abstract summary: We explore the generation and optimization of entanglement between atoms chirally coupled to finite 1D spin chains.<n>Small even-sized cavities chirally coupled to atoms expediting entanglement generation by approximately $50%$ faster than non-chiral coupling.<n>Controlled disorder within the cavity significantly enhances and expedites entanglement generation, achieving higher concurrences up to four times faster than those attained in ordered systems.
Score: 0.39984500192099387
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We explore the generation and optimization of entanglement between atoms chirally coupled to finite 1D spin chains, functioning as {\it spin cavities}. By diagonalizing the spin cavity Hamiltonian, we identify a parity effect that influences entanglement, with small even-sized cavities chirally coupled to atoms expediting entanglement generation by approximately $50\%$ faster than non-chiral coupling. Applying a classical driving field to the atoms reveals oscillations in concurrence, with resonant dips at specific driving strengths due to the resonances between the driven atom and the spin cavity. Extending our study to systems with energetic disorder, we find that high concurrence can be achieved regardless of disorder strength when the inverse participation ratio of the resulting eigenstates is favorable. Finally, we demonstrate that controlled disorder within the cavity significantly enhances and expedites entanglement generation, achieving higher concurrences up to four times faster than those attained in ordered systems.

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