We study weak ergodicity breaking in a one-dimensional, nonintegrable spin-1 XY model. We construct for it an exact, highly excited eigenstate, which despite its large energy density, can be represented analytically by a finite bond-dimension matrix product state (MPS) with area-law entanglement. Upon a quench to a finite Zeeman field, the state undergoes periodic dynamics with perfect many-body revivals, in stark contrast to other generic initial states which instead rapidly thermalize. This dynamics can be completely understood in terms of the evolution of entangled virtual spin-1/2 degrees of freedom, which in turn underpin the presence of an extensive tower of strong-eigenstate thermalization hypothesis (ETH)-violating many-body eigenstates. The resulting quantum many-body scars are therefore of novel origin. Our results provide important analytical insights into the nature and entanglement structure of quantum many-body scars.
Optical driving of materials has emerged as a promising tool to control their macroscopic properties. In this work we present a microscopic mechanism for efficiently photo-inducing superconductivity. We investigate an attractive electron-electron interaction mediated by a boson that couples to an electronic transition between two bands separated by a band gap. While this attraction is small in equilibrium, we find that it can be increased by several orders of magnitude when the bosons are driven into a nonthermal state. Moreover, not only is the induced attraction enhanced when the bosons are driven, but this enhancement is further amplified when the boson is near-resonant to the electronic interband excitation energy, making this mechanism a potentially ideal candidate for efficient photo-induced superconductivity. We first use exact diagonalisation calculations of a two-site model to prove that pairing is indeed resonantly enhanced out-of equilibrium. We then investigate the potential of this mechanism to increase the superconducting transition temperature, and find by investigating the gap equation that pairing is resonantly amplified when the bosons are in a nonthermal state. We argue that our proposed mechanism provides a simple prescription for designing new platforms that enable photo-induced superconductivity at significant temperatures and moderate driving strengths, and estimate a transition temperature Tc ≈ 5K for a SrTiO3graphene heterostructure.
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