Tese de Doutorado #343 – Natália Salomé Móller – 29/06/2018
LOCAL QUENCHES ON QUANTUM MANY BODY SYSTEMS
Autor: Natália Salomé Móller
Banca Examinadora
Prof. Raphael Campos Drumond (orientador)
DM/UFMG
Profa. Maria Carolina de Oliveira Aguiar
DF/UFMG
Prof. Leonardo Teixeira Neves
DF/UFMG
Prof. Tommaso Macri
DF/UFRN
Prof. Romain Pierre Marcel Bachelard
DF/UFSCAR
Orientação
Prof. Raphael Campos Drumond
DM/UFMG
Resumo do Trabalho
We have studied local quenches on quantum many body systems. We have investigated the variation of von Neumann entropy of subsystem reduced states of general many- body lattice spin systems due to local quantum quenches. We obtain Lieb-Robinson-like bounds that are independent of the subsystem volume. More specifically, the bound exponentially increases with time but exponentially decreases with the distance between the subsystem and the region where the quench takes place. The fact that the bound is independent of the subsystem volume leads to stronger constraints (than previously known) on the propagation of information throughout many-body systems. In particular, it shows that bipartite entanglement satisfies an effective “light cone”, regardless of system size.
We have also find a new phenomenon for the quantum Ising model, which we have called Shielding Property. Namely, whatever the fields on each spin and exchange couplings between neighbouring spins are, if the field in one particular site is null, the reduced states of the subchains to the right and to the left of this site are exactly the Gibbs states of each subchain alone. Therefore, even if there is a strong exchange coupling between the extremal sites of each subchain, the Gibbs states of the each subchain behave as if there is no interaction between them. In general, if a lattice can be divided into two disconnected regions separated by an interface of sites with zero applied field, we can guarantee a similar result if the surface contains a single site. When we have more sites in the interface, the system satisfy the shielding property for the ground state under some conditions. We show that one particular situation where the system satisfy these required conditions is when it is free of frustration.