Quantum Mechanics of Dynamical Zero Mode in $QCD_{1+1}$ on the
  Light-Cone

A. C. Kalloniatis; A. C. Kalloniatis; A. Dhar; D. G. Robertson; F. Lenz; G. Bhanot; H. C. Pauli; H. C. Pauli; K. G. Wilson; K. Harada; K. Hornbostel; K. Sundermeyer; M. Burkardt; M. Maeno; Motoi Tachibana; P. A. M. Dirac; P. Gaete; R. J. Perry; R. J. Perry; S. Pinsky; S. Pinsky; S. Pinsky; W. M. Zhang; W. M. Zhang; W. M. Zhang

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Quantum Mechanics of Dynamical Zero Mode in $QCD_{1+1}$ on the Light-Cone

Authors: A. C. Kalloniatis
A. C. Kalloniatis
A. Dhar
D. G. Robertson
F. Lenz
G. Bhanot
H. C. Pauli
H. C. Pauli
K. G. Wilson
K. Harada
K. Hornbostel
K. Sundermeyer
M. Burkardt
M. Maeno
Motoi Tachibana
P. A. M. Dirac
P. Gaete
R. J. Perry
R. J. Perry
S. Pinsky
S. Pinsky
S. Pinsky
W. M. Zhang
W. M. Zhang
W. M. Zhang
Publication date: 6 April 1995
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Motivated by the work of Kalloniatis, Pauli and Pinsky, we consider the theory of light-cone quantized

QCD_{1+1}

on a spatial circle with periodic and anti-periodic boundary conditions on the gluon and quark fields respectively. This approach is based on Discretized Light-Cone Quantization (DLCQ). We investigate the canonical structures of the theory. We show that the traditional light-cone gauge

A_- = 0

is not available and the zero mode (ZM) is a dynamical field, which might contribute to the vacuum structure nontrivially. We construct the full ground state of the system and obtain the Schr\"{o}dinger equation for ZM in a certain approximation. The results obtained here are compared to those of Kalloniatis et al. in a specific coupling region.Comment: 19 pages, LaTeX file, no figure

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