Non-equilibrium universality in two-mode squeezing in Floquet-engineered power-law interacting spin models
ORAL
Abstract
We investigate phase transitions in the nonequilibrium dynamics of power-law interacting spin-1/2 XXZ models, which have recently been shown to allow scalable generation of entanglement in the form of two-mode squeezing.
Here, we focus on the transition from dynamics characterized by Heisenberg limited squeezing to partially collective behavior in 1D (spin ladder) and 2D (spin bilayer) systems for a range of power-law interaction exponents. We identify universal scaling of the generated squeezing in terms of system parameters, and identify distinct phases as a function of dimensionality, powerlaw exponent, and aspect ratio of the system.
This study offers a comprehensive framework for engineering collective quantum states in experimental platforms that realize power-law spin models, advancing applications in quantum sensing and simulation.
Here, we focus on the transition from dynamics characterized by Heisenberg limited squeezing to partially collective behavior in 1D (spin ladder) and 2D (spin bilayer) systems for a range of power-law interaction exponents. We identify universal scaling of the generated squeezing in terms of system parameters, and identify distinct phases as a function of dimensionality, powerlaw exponent, and aspect ratio of the system.
This study offers a comprehensive framework for engineering collective quantum states in experimental platforms that realize power-law spin models, advancing applications in quantum sensing and simulation.
*The computing for this project was performed at the High Performance Computing Center at Oklahoma State University supported in part through the National Science Foundation grant OAC-1531128.
–
Presenters
-
Thomas Bilitewski
- Oklahoma State University