Exploring the thermodynamics of spin-1 Bose gases with synthetic magnetization

Abstract: We study the thermodynamic properties of a spin-1 Bose gas across the Bose-Einstein condensation transition. We present the theoretical description of the thermodynamics of a trapped ideal spin-1 Bose gas and we describe the phases that can be obtained in this system as a function of the temperature and of the populations in the different spin components. We propose a simple way to realize a 'synthetic magnetization' that can be used to probe the entire phase diagram while keeping the real magnetization of the… Show more

“…In the case of M = 0, the phase diagram of ground states contains two critical points that separate the polar (P) phase (characterized by N ±1 = 0) from the broken axisymmetry (BA) phase (N 0 , N ±1 > 0), and the BA phase from the antiferromagnetic (AFM) phase (N ±1 = N/2) [50]. In the thermodynamic limit, the two critical points for Ĥ1 /c are q c = 2 and q c = −2, respectively.…”

Critical quantum thermometry and its feasibility in spin systems

“…In the case of M = 0, the phase diagram of ground states contains two critical points that separate the polar (P) phase (characterized by N ±1 = 0) from the broken axisymmetry (BA) phase (N 0 , N ±1 > 0), and the BA phase from the antiferromagnetic (AFM) phase (N ±1 = N/2) [50]. In the thermodynamic limit, the two critical points for Ĥ1 /c are q c = 2 and q c = −2, respectively.…”

Critical quantum thermometry and its feasibility in spin systems

Generation of optical potentials for ultracold atoms using a superluminescent diode

Bloch oscillations along a synthetic dimension of atomic trap states