Abstract
By employing quantum renormalization group (QRG) method, we investigate quantum phase transitions (QPT) in the Ising transverse field (ITF) model and in the XXZ Heisenberg model, with and without Dzyaloshinskii Moriya (DM) interaction, on a periodic chain of N lattice sites. We adopt a new approach called spin squeezing as an indicator of QPT. Spin squeezing, through analytical expression of a spin squeezing parameter, is calculated after each step of QRG. As the scale of the system becomes larger, (after many QRG steps), the ground state (GS) spin squeezing parameters show an abrupt change at a quantum critical point (QCP). Moreover, in all of the studied models, the first derivative of the spin squeezing parameter with respect to the control parameter is discontinuous, which is a signature of QPT. The spin squeezing parameters develop their saturated values after enough QRG iterations. The divergence exponent of the first derivative of the spin squeezing parameter in the near vicinity of the QCP is associated with the critical exponent of the correlation length.
Highlights
Quantum phase transition (QPT), has been of great interest to the condensed matter physicists in recent decades
Even though the quantum renormalization group (QRG) method reduces the degrees of freedom of the system, but it gives acceptable results comparable with the results of analytical calculations, density matrix RG (DMRG), multi-scale entanglement renormalization ansatz (MERA)[38] and projected entangled pair states (PEPS)[39]
In this work the relation between the spin squeezing and quantum phase transitions (QPT) is addressed based on the QRG procedure
Summary
By employing quantum renormalization group (QRG) method, we investigate quantum phase transitions (QPT) in the Ising transverse field (ITF) model and in the XXZ Heisenberg model, with and without Dzyaloshinskii Moriya (DM) interaction, on a periodic chain of N lattice sites. The notion of spin squeezing has many advantages where the most important one is the simplicity in generating and measuring it, for instance, in atomic interferometry, weak magnetic fields[49,50], spin noise in quantum fluids[51,52], magnetometry with a spinor Bose-Einstein condensate[53], Ramsey spectroscopy, atom clocks and in quantum computing[54,55,56,57,58,59] It improves the precision of experimental measurements[60,61,62]. Our main purpose in this work is to use the QRG method to study the scaling behaviour of the spin squeezing parameter in the vicinity of QCP in some spin-1/2 models. We aim to investigate the behaviour of the spin squeezing parameter in detecting QPTs. We study the renormalization of the spin squeezing parameter in the one-dimensional anisotropic XXZ-Heisenberg model
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