Related papers: Spin Orbit and Hyperfine Simulations with Two-Species Ultracold Atoms in a Ring

Spin Orbit and Hyperfine Simulations with Two-Species Ultracold Atoms in a Ring

URL: http://arxiv.org/abs/2406.02130v1
Date: Tue, 4 Jun 2024 09:17:43 GMT
Title: Spin Orbit and Hyperfine Simulations with Two-Species Ultracold Atoms in a Ring
Authors: Allison Brattley, Tomáš Opatrný, Kunal K. Das,
Abstract summary: A collective spin model is used to describe two species of mutually interacting ultracold bosonic atoms confined to a toroidal trap. We show the linear component is an analog of a Zeeman Hamiltonian, and the quadratic component presents a macroscopic simulator for spin-orbit and hyperfine interactions.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: A collective spin model is used to describe two species of mutually interacting ultracold bosonic atoms confined to a toroidal trap. The system is modeled by a Hamiltonian that can be split into two components, a linear part and a quadratic part, which may be controlled independently. We show the linear component is an analog of a Zeeman Hamiltonian, and the quadratic component presents a macroscopic simulator for spin-orbit and hyperfine interactions. We determine a complete set of commuting observables for both the linear and quadratic Hamiltonians, and derive analytical expressions for their respective spectra and density of states. We determine the conditions for generating maximal entanglement between the two species of atoms with a view to applications involving quantum correlations among spin degrees of freedom, such as in the area of quantum information.

Related papers

Tunable Two-Species Spin Models with Rydberg Atoms in Circular and Elliptical States [0.0]
We propose a scheme for constructing versatile quantum simulators using ultracold Rydberg atoms. By exciting different subspaces of internal atomic states, the atoms can be used to simulate two effective spin species.
arXiv Detail & Related papers (2024-11-22T11:09:10Z)
Classification and emergence of quantum spin liquids in chiral Rydberg models [0.0]
We investigate the nature of quantum phases arising in chiral interacting Hamiltonians recently realized in Rydberg atom arrays. We classify all possible fermionic chiral spin liquids with $mathrmU(1)$ global symmetry using parton construction on the honeycomb lattice.
arXiv Detail & Related papers (2023-03-22T18:00:02Z)
Entangled Collective Spin States of Two Species Ultracold atoms in a Ring [0.0]
We study the general quantum Hamiltonian that can be realized with two species of degenerate ultracold atoms in a ring-shaped trap. We examine the spectrum and the states with a collective spin picture in a Dicke state basis. The density of states for the full Hamiltonian shows features as of phase transition in varying between linear and quadratic limits.
arXiv Detail & Related papers (2023-03-15T04:11:59Z)
Quantum vibrational mode in a cavity confining a massless spinor field [91.3755431537592]
We analyse the reaction of a massless (1+1)-dimensional spinor field to the harmonic motion of one cavity wall. We demonstrate that the system is able to convert bosons into fermion pairs at the lowest perturbative order.
arXiv Detail & Related papers (2022-09-12T08:21:12Z)
Spectral form factor in a minimal bosonic model of many-body quantum chaos [1.3793594968500609]
We study spectral form factor in periodically-kicked bosonic chains. We numerically find a nontrivial systematic system-size dependence of the Thouless time.
arXiv Detail & Related papers (2022-03-10T15:56:24Z)
Dispersive readout of molecular spin qudits [68.8204255655161]
We study the physics of a magnetic molecule described by a "giant" spin with multiple $d > 2$ spin states. We derive an expression for the output modes in the dispersive regime of operation. We find that the measurement of the cavity transmission allows to uniquely determine the spin state of the qudits.
arXiv Detail & Related papers (2021-09-29T18:00:09Z)
Relativistic aspects of orbital and magnetic anisotropies in the chemical bonding and structure of lanthanide molecules [60.17174832243075]
We study the electronic and ro-vibrational states of heavy homonuclear lanthanide Er2 and Tm2 molecules by applying state-of-the-art relativistic methods. We were able to obtain reliable spin-orbit and correlation-induced splittings between the 91 Er2 and 36 Tm2 electronic potentials dissociating to two ground-state atoms.
arXiv Detail & Related papers (2021-07-06T15:34:00Z)
Visualizing spinon Fermi surfaces with time-dependent spectroscopy [62.997667081978825]
We propose applying time-dependent photo-emission spectroscopy, an established tool in solid state systems, in cold atom quantum simulators. We show in exact diagonalization simulations of the one-dimensional $t-J$ model that the spinons start to populate previously unoccupied states in an effective band structure. The dependence of the spectral function on the time after the pump pulse reveals collective interactions among spinons.
arXiv Detail & Related papers (2021-05-27T18:00:02Z)
Evolution of a Non-Hermitian Quantum Single-Molecule Junction at Constant Temperature [62.997667081978825]
We present a theory for describing non-Hermitian quantum systems embedded in constant-temperature environments. We find that the combined action of probability losses and thermal fluctuations assists quantum transport through the molecular junction.
arXiv Detail & Related papers (2021-01-21T14:33:34Z)
Engineering entanglement Hamiltonians with strongly interacting cold atoms in optical traps [0.0]
We propose the realization of entanglement Hamiltonians in one-dimensional critical spin systems with strongly interacting cold atoms. We focus on reproducing the universal ratios of the entanglement spectrum for systems in two different geometries. Our results demonstrate the possibility of measuring the entanglement spectra of the Heisenberg and XX models in a realistic cold-atom experimental setting.
arXiv Detail & Related papers (2020-07-10T08:33:00Z)
Quantum Simulation of 2D Quantum Chemistry in Optical Lattices [59.89454513692418]
We propose an analog simulator for discrete 2D quantum chemistry models based on cold atoms in optical lattices. We first analyze how to simulate simple models, like the discrete versions of H and H$+$, using a single fermionic atom. We then show that a single bosonic atom can mediate an effective Coulomb repulsion between two fermions, leading to the analog of molecular Hydrogen in two dimensions.
arXiv Detail & Related papers (2020-02-21T16:00:36Z)

This list is automatically generated from the titles and abstracts of the papers in this site.