Exact effective action for (1+1)-dimensional fermions in an Abelian background at finite temperature and chemical potential
Abstract
In this paper we study the effects of a nonzero chemical potential in (1+1)-dimensional quantum field models at finite temperature. We particularly consider massless fermions in an Abelian gauge field background and calculate the effective action by evaluating the n-point functions. We find that the structure of the amplitudes corresponds to a generalization of the structure noted earlier in a calculation without a chemical potential (the associated integrals carry the dependence on the chemical potential). Our calculation shows that the chiral anomaly is unaffected by the presence of a chemical potential at finite temperature. However, unlike in the absence of a chemical potential, odd point functions do not vanish. We trace this to the fact that in the presence of a chemical potential the generalized charge conjugation symmetry of the theory allows for such amplitudes. In fact, we find that all the even point functions are even functions of μ, while the odd point functions are odd functions of μ which is consistent with this generalized charge conjugation symmetry. We show that the origin of the structure of the amplitudes is best seen from a formulation of the theory in terms of left- and right-handed spinors. The calculations are also much simpler in this formulation and it clarifies many other aspects of the theory.
- Publication:
-
Physical Review D
- Pub Date:
- September 2008
- DOI:
- 10.1103/PhysRevD.78.065005
- arXiv:
- arXiv:0805.2321
- Bibcode:
- 2008PhRvD..78f5005M
- Keywords:
-
- 11.10.Kk;
- 11.10.Ef;
- 11.10.Wx;
- 11.30.Rd;
- Field theories in dimensions other than four;
- Lagrangian and Hamiltonian approach;
- Finite-temperature field theory;
- Chiral symmetries;
- High Energy Physics - Theory
- E-Print:
- Phys.Rev.D78:065005,2008