Quantum many-body dynamics for fermionic t-J model simulated with atom arrays

The fermionic t-J model has been widely recognized as a canonical model in understanding various strongly correlated phases like cuprate high-Tc superconductivity. Simulating this model with controllable quantum platforms offers new possibilities to probe high-Tc physics, yet suffering challenges. Here we propose a novel scheme to realize the t-J model in a programmable Rydberg-dressed tweezer array. By properly engineering the Rydberg-dressed dipole-dipole interaction and inter-tweezer couplings, a highly tunable fermionic t-J model with next-nearest-neighbour hopping terms is achieved. We particularly explore quantum many-body dynamics in the large J/t limit, a regime far beyond the conventional optical lattices and cuprates. Notably, we predict a nontrivial self-pinning effect enforced by local quantum entanglement that characterizes a novel type of Hilbert space fragmentation. This effect leads to the breakdown of Krylov restricted thermalization. Our prediction opens a new horizon in exploring exotic quantum many-body dynamics with t-J model in tweezer arrays, and shall also make a step towards simulating the high-Tc physics in cold atom systems.