Quantum anomaly and thermodynamics of one-dimensional fermions with antisymmetric two-body interactions

Quantum anomaly and thermodynamics of one-dimensional fermions with antisymmetric two-body interactions

A system of two-species, one-dimensional fermions, with an attractive two-body interaction of the derivative-delta type, features a scale anomaly. In contrast to the well-known two-dimensional case with contact interactions, and its one-dimensional cousin with three-body interactions (studied recent...

Full description

Saved in:
Bibliographic Details
Published in:Annals of physics Vol. 429; p. 168466
Main Authors: Camblong, H.E., Chakraborty, A., Daza, W.S., Drut, J.E., Lin, C.L., Ordóñez, C.R.
Format: Journal Article
Language:English
Published: Elsevier Inc 01-06-2021
Subjects:
Contact interactions
Dimensional transmutation
Quantum anomaly
Tan’s contact
Contact interactions
Quantum anomaly
Tan’s contact
Dimensional transmutation
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A system of two-species, one-dimensional fermions, with an attractive two-body interaction of the derivative-delta type, features a scale anomaly. In contrast to the well-known two-dimensional case with contact interactions, and its one-dimensional cousin with three-body interactions (studied recently by some of us and others), the present case displays dimensional transmutation featuring a power-law rather than a logarithmic behavior. We use both the Schrödinger equation and quantum field theory to study bound and scattering states, showing consistency between both approaches. We show that the expressions for the reflection (R) and the transmission (T) coefficients of the renormalized, anomalous derivative-delta potential are identical to those of the regular delta potential. The second-order virial coefficient is calculated analytically using the Beth–Uhlenbeck formula, and we make comments about the proper ϵB→0 (where ϵB is the bound-state energy) limit. We show the impact of the quantum anomaly (which appears as the binding energy of the two-body problem, or equivalently as Tan’s contact) on the equation of state and on other universal relations. Our emphasis throughout is on the conceptual and structural aspects of this problem. •The 1D derivative-delta two-body potential provides a model for a fermion gas.•The derivative-delta interaction has a classical SO(2,1) conformal symmetry.•The scale symmetry breaks as a quantum anomaly, with dimensional transmutation.•The scale anomaly generates a bound state and non-trivial, anomalous scattering.•The anomaly, driven by Tan’s contact, gives an equation of state and virial relations.
ISSN:0003-4916
1096-035X
DOI:10.1016/j.aop.2021.168466