Virial expansion for a three-component Fermi gas in one dimension: The quantum anomaly correspondence

Maki, Jeff; Ordóñez, Carlos

doi:10.1103/physreva.100.063604

Cited by 15 publications

(7 citation statements)

References 37 publications

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“…(3) 0 replacing w 0 in Eq. ( 16), has been shown to be important for realistic two-body interactions in one dimension with large scattering length [61], where the three-body interaction and its three-body range correction dominate low-energy physics [61][62][63][64][65][66][67][68].…”

Section: A Bosonic Low-energy Interactionsmentioning

confidence: 99%

Bose-Fermi dualities for arbitrary one-dimensional quantum systems in the universal low energy regime

Valiente

2020

Preprint

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I consider general interacting systems of quantum particles in one spatial dimension. These consist of bosons or fermions, which can have any number of components, arbitrary spin or a combination thereof, featuring low-energy two-and multiparticle interactions. The single-particle dispersion can be Galilean (non-relativistic), relativistic, or have any other form that may be relevant for the continuum limit of lattice theories. Using an algebra of generalized functions, statistical transmutation operators that are genuinely unitary are obtained, putting bosons and fermions in a one-to-one correspondence without the need for a short-distance hard core. In the non-relativistic case, lowenergy interactions for bosons yield, order by order, fermionic dual interactions that correspond to the standard low-energy expansion for fermions. In this way, interacting fermions and bosons are fully equivalent to each other at low energies. While the Bose-Fermi mappings do not depend on microscopic details, the resulting statistical interactions heavily depend on the kinetic energy structure of the respective Hamiltonians. These statistical interactions are obtained explicitly for a variety of models, and regularized and renormalized in the momentum representation, which allows for theoretically and computationally feasible implementations of the dual theories. The mapping is rewritten as a gauge interaction, and one-dimensional anyons are also considered.

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Section: A Bosonic Low-energy Interactionsmentioning

confidence: 99%

Bose-Fermi dualities for arbitrary one-dimensional quantum systems in the universal low energy regime

Valiente

2020

Preprint

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“…It was shown that this system features a scale anomaly, which impacts the thermodynamics [5] and exact universal relations generalizing the Tan contact theorems for three-body forces. The quantum anomaly also affects [6] the high-temperature transport properties of the three-component Fermi gases.…”

Section: Introductionmentioning

confidence: 99%

Efimov-like physics in fraction-dimensional Bose systems with three-body interaction

Hryhorchak¹,

Pastukhov²

2021

Preprint

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A few-body properties of spinless Bose particles interacting via the contact three-body potential in geometries with fractional dimensions 1 < d < 2 are considered. We predict the existence of infinite tower of the Efimov bound states in the four-body sector at three-body resonance. A similar behavior is found in the five-body problem. It is shown that a ratio of the high-energy levels in these two sectors is a universal constant. The consequences of emergence of the Efimov physics on the many-body behavior are briefly discussed.

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“…Motivated by the recent interest in one-dimensional (1D) Fermi and Bose gases in the fine-tuned situation where only three-body interactions are present [1][2][3][4][5][6][7][8][9], we explore here the thermodynamics of fermions with a contact three-body interaction in the region of low fugacity (which corresponds to a dilute regime and therefore high temperatures in units of the energy scale set by the density). We focus on the fermionic case but explore the problem in arbitrary dimension d. To that end, we implement a semiclassical lattice approximation (SCLA) to calculate the virial coefficients b n , and carry out their evaluation up to n = 5 at leading order (LO) in that approximation.…”

Section: Introductionmentioning

confidence: 99%

Virial coefficients of trapped and untrapped three-component fermions with three-body forces in arbitrary spatial dimensions

et al. 2020

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Virial expansion for a three-component Fermi gas in one dimension: The quantum anomaly correspondence

Cited by 15 publications

References 37 publications

Bose-Fermi dualities for arbitrary one-dimensional quantum systems in the universal low energy regime

Bose-Fermi dualities for arbitrary one-dimensional quantum systems in the universal low energy regime

Efimov-like physics in fraction-dimensional Bose systems with three-body interaction

Virial coefficients of trapped and untrapped three-component fermions with three-body forces in arbitrary spatial dimensions

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