TY - JOUR

T1 - Wave functions and properties of massive states in three-dimensional supersymmetric Yang-Mills theory

AU - Hiller, John R.

AU - Trittmann, Uwe

PY - 2001/10/29

Y1 - 2001/10/29

N2 - We apply supersymmetric discrete light-cone quantization (SDLCQ) to the study of supersymmetric Yang-Mills theory on (Formula presented) One of the compact directions is chosen to be lightlike and the other to be spacelike. Since the SDLCQ regularization explicitly preserves supersymmetry, this theory is totally finite, and thus we can solve for bound-state wave functions and masses numerically without renormalizing. We present an overview of all the massive states of this theory, and we see that the spectrum divides into two distinct and disjoint bands. In one band the SDLCQ approximation is valid only up to intermediate coupling. There we find a well defined and well behaved set of states, and we present a detailed analysis of these states and their properties. In the other band, which contains a completely different set of states, we present a much more limited analysis for strong coupling only. We find that, while these states have a well defined spectrum, their masses grow with the transverse momentum cutoff. We present an overview of these states and their properties.

AB - We apply supersymmetric discrete light-cone quantization (SDLCQ) to the study of supersymmetric Yang-Mills theory on (Formula presented) One of the compact directions is chosen to be lightlike and the other to be spacelike. Since the SDLCQ regularization explicitly preserves supersymmetry, this theory is totally finite, and thus we can solve for bound-state wave functions and masses numerically without renormalizing. We present an overview of all the massive states of this theory, and we see that the spectrum divides into two distinct and disjoint bands. In one band the SDLCQ approximation is valid only up to intermediate coupling. There we find a well defined and well behaved set of states, and we present a detailed analysis of these states and their properties. In the other band, which contains a completely different set of states, we present a much more limited analysis for strong coupling only. We find that, while these states have a well defined spectrum, their masses grow with the transverse momentum cutoff. We present an overview of these states and their properties.

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U2 - 10.1103/PhysRevD.64.105027

DO - 10.1103/PhysRevD.64.105027

M3 - Article

AN - SCOPUS:0035890933

VL - 64

JO - Physical review D: Particles and fields

JF - Physical review D: Particles and fields

SN - 1550-7998

IS - 10

M1 - 105027

ER -