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Paper detail

Universality in one-dimensional fermions at finite temperature: Density, pressure, compressibility, and contact

We present finite-temperature, lattice Monte Carlo calculations of the particle number density, compressibility, pressure, and Tan's contact of an unpolarized system of short-range, attractively interacting spin-1/2 fermions in one spatial dimension, i.e., the Gaudin-Yang model. In addition, we compute the second-order virial coefficients for the pressure and the contact, both of which are in excellent agreement with the lattice results in the low-fugacity regime. Our calculations yield universal predictions for ultracold atomic systems with broad resonances in highly constrained traps. We cover a wide range of couplings and temperatures and find results that support the existence of a strong-coupling regime in which the thermodynamics of the system is markedly different from the noninteracting case. We compare and contrast our results with identical systems in higher dimensions.

preprint2015arXivOpen access
M. D. HoffmanP. D. JavernickA. C. LoheacW. J. PorterE. R. AndersonJ. E. Drut
hep-latnucl-thcond-mat.quant-gas
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M. D. HoffmanP. D. JavernickA. C. LoheacW. J. PorterE. R. AndersonJ. E. Drut

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