Physics:Gross–Neveu model

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Short description: Quantum theory in 1+1 dimensions

The Gross–Neveu (GN) model is a quantum field theory model of Dirac fermions interacting via four-fermion interactions in 1 spatial and 1 time dimension. It was introduced in 1974 by David Gross and André Neveu[1] as a toy model for quantum chromodynamics (QCD), the theory of strong interactions. It shares several features of the QCD: GN theory is asymptotically free thus at strong coupling the strength of the interaction gets weaker and the corresponding [math]\displaystyle{ \beta }[/math] function of the interaction coupling is negative, the theory has a dynamical mass generation mechanism with [math]\displaystyle{ \mathbb{Z}_2 }[/math] chiral symmetry breaking, and in the large number of flavor ([math]\displaystyle{ N \to \infty }[/math]) limit, GN theory behaves as t'Hooft's large [math]\displaystyle{ N_c }[/math] limit in QCD.[2]

It consists of N Dirac fermions [math]\displaystyle{ \psi_1, \psi_2, \cdots, \psi_N }[/math]. The Lagrangian density is

[math]\displaystyle{ \mathcal{L}=\bar \psi_a \left(i\partial\!\!\!/-m \right) \psi^a + \frac{g^2}{2N}\left[\bar \psi_a \psi^a\right]^2 }[/math].

Einstein summation notation is used, [math]\displaystyle{ \psi^a }[/math] is a two component spinor object and [math]\displaystyle{ g }[/math] is the coupling constant. If the mass [math]\displaystyle{ m }[/math] is nonzero, the model is massive classically, otherwise it enjoys a chiral symmetry.

This model has a U(N) global internal symmetry. If one takes N=1 (which permits only one quartic interaction) and makes no attempt to analytically continue the dimension, the model reduces to the massive Thirring model (which is completely integrable).[3]

It is a 2-dimensional version of the 4-dimensional Nambu–Jona-Lasinio model (NJL), which was introduced 14 years earlier as a model of dynamical chiral symmetry breaking (but no quark confinement) modeled upon the BCS theory of superconductivity. The 2-dimensional version has the advantage that the 4-fermi interaction is renormalizable, which it is not in any higher number of dimensions.

Features of the theory

Gross and Neveu studied this model in the large [math]\displaystyle{ N }[/math] limit, expanding the relevant parameters in a 1/N expansion. After demonstrating that this and related models are asymptotically free, they found that, in the subleading order, for small fermion masses the bifermion condensate [math]\displaystyle{ \overline{\psi}_a \psi^a }[/math] acquires a vacuum expectation value (VEV) and as a result the fundamental fermions become massive. They find that the mass is not analytic in the coupling constant g. The vacuum expectation value spontaneously breaks the chiral symmetry of the theory.

More precisely, expanding about the vacuum with no vacuum expectation value for the bilinear condensate they found a tachyon. To do this they solve the renormalization group equations for the propagator of the bifermion field, using the fact that the only renormalization of the coupling constant comes from the wave function renormalization of the composite field. They then calculated, at leading order in a 1/N expansion but to all orders in the coupling constant, the dependence of the potential energy on the condensate using the effective action techniques introduced the previous year by Sidney Coleman at the Erice International Summer School of Physics. They found that this potential is minimized at a nonzero value of the condensate, indicating that this is the true value of the condensate. Expanding the theory about the new vacuum, the tachyon was found to be no longer present and in fact, like the BCS theory of superconductivity, there is a mass gap.

They then made a number of general arguments about dynamical mass generation in quantum field theories. For example, they demonstrated that not all masses may be dynamically generated in theories which are infrared-stable, using this to argue that, at least to leading order in 1/N, the 4-dimensional [math]\displaystyle{ \phi^4 }[/math] theory does not exist. They also argued that in asymptotically free theories the dynamically generated masses never depend analytically on the coupling constants.

Generalizations

Gross and Neveu considered several generalizations. First, they considered a Lagrangian with one extra quartic interaction

[math]\displaystyle{ \mathcal{L}= \bar \psi_a \left(i\partial\!\!\!/-m \right) \psi^a + \frac{g^2}{2N}(\left[ \bar \psi_a \psi^a\right]^2-\left[ \bar \psi_a \gamma_5 \psi^a\right]^2) }[/math]

chosen so that the discrete chiral symmetry [math]\displaystyle{ \psi\rightarrow\gamma_5\psi }[/math] of the original model is enhanced to a continuous U(1)-valued chiral symmetry [math]\displaystyle{ \psi\rightarrow e^{i\theta\gamma_5}\psi }[/math]. Chiral symmetry breaking occurs as before, caused by the same VEV. However, as the spontaneously broken symmetry is now continuous, a massless Goldstone boson appears in the spectrum. Although this leads to no problems at the leading order in the 1/N expansion, massless particles in 2-dimensional quantum field theories inevitably lead to infrared divergences and so the theory appears to not exist.

Two further modifications of the modified theory, which remedy this problem, were then considered. In one modification one increases the number of dimensions. As a result, the massless field does not lead to divergences. In the other modification, the chiral symmetry is gauged. As a result, the Golstone boson is eaten by the Higgs mechanism as the photon becomes massive, and so does not lead to any divergences.

See also

References

  1. Gross, David J. and Neveu, André (1974). "Dynamical symmetry breaking in asymptotically free field theories". Phys. Rev. D 10 (10): 3235–3253. doi:10.1103/PhysRevD.10.3235. Bibcode1974PhRvD..10.3235G. 
  2. Pannullo, L.; Lenz, J.; Wagner, M.; Wellegehausen, B.; Wipf, A. (2020). "Inhomogeneous Phases in the 1+1 Dimensional Gross--Neveu Model at Finite Number of Fermion Flavors". Acta Physica Polonica B Proceedings Supplement 13 (1): 127. doi:10.5506/aphyspolbsupp.13.127. ISSN 1899-2358. 
  3. L. Fei, S. Giombi, I. R. Klebanov and G. Tarnopolsky (2016). "Yukawa CFTs and emergent supersymmetry". arXiv:1607.05316 [hep-th].CS1 maint: multiple names: authors list (link)