Resumen de Quantum monte carlo study of few-and many-body bose systems in one and two dimensions
In this Thesis, we report a detailed study of the ground-state properties of a set of quantum few- and many-body systems by using Quantum Monte Carlo methods. First, we introduced the Variational Monte Carlo and Diffusion Monte Carlo methods, which are the methods used in this Thesis to obtain the properties of the systems. The first systems we studied consist of few-body clusters in one-dimensional Bose-Bose and Bose-Fermi mixtures. Each mixture is formed by two different species with attractive interspecies and repulsive intraspecies contact interactions. For each mixture, we focused on the study of the dimer, tetramer, and hexamer clusters. We calculated their binding energies and unbinding thresholds. Combining these results with a three-body theory, we extracted the three-dimer scattering length close to the dimer-dimer zero crossing. For both mixtures, the three-dimer interaction turns out to be repulsive. Our results constitute a concrete proposal for obtaining a one-dimensional gas with a pure three-body repulsion. The next system analyzed consists of few-body clusters in a two-dimensional Bose-Bose mixture using two types of interactions. The first case corresponds to a bilayer of dipoles aligned perpendicularly to the planes and, in the second, we model the interactions by finite-range Gaussian potentials. We find that all the considered clusters are bound states and that their energies are universal functions of the scattering lengths, for sufficiently large attraction-to-repulsion ratios. Studying the hexamer energy close to the corresponding threshold, we discovered an effective three-dimer repulsion, which can stabilize interesting many-body phases. Once the existence of bound states in the dipolar bilayer has been demonstrated, we investigated whether halos can occur in this system. A halo state is a quantum bound state whose size is much larger than the range of the attractive interaction between the atoms that form it, showing universal ratios between energy and size. For clusters composed from three up to six dipoles, we find two very distinct halo structures. For large interlayer separation, the halo structure is roughly symmetric. However, for the deepest bound clusters and as the clusters approach the threshold, we discover an unusual shape of the halo states, highly anisotropic. Importantly, our results prove the existence of stable halo states composed of up to six particles. To the best of our knowledge, this is the first time that halo states with such a large number of particles have been predicted and observed in a numerical simulation. The next system we studied is a two-dimensional many-body dipolar fluid confined to a bilayer geometry. We calculated the ground-state phase diagram as a function of the density and the separation between layers. Our simulations show that the system undergoes a phase transition from a gas to a stable liquid as the interlayer distance increases. The liquid phase is stable in a wide range of densities and interlayer values. In the final part of this Thesis, we studied a system of dipolar bosons confined to a multilayer geometry formed by equally spaced two-dimensional layers. We calculated the ground-state phase diagram as a function of the density, the separation between layers, and the number of layers. The key result of our study in the dipolar multilayer is the existence of three phases: atomic gas, solid, and gas of chains, in a wide range of the system parameters. Remarkably, we find that the density of the solid phase decreases several orders of magnitude as the number of layers in the system increases. The results reported in this Thesis show that a dipolar system in a bilayer and multilayer geometries offer stable and highly controllable setups for observing interesting phases of quantum matter, such as halo states, and ultra-dilute liquids and solids.
