We use lattice techniques to calculate the continuum string tensions of SU(N) gauge theories in 2+1 dimensions. We attempt to control all systematic errors at a level that allows us to perform a precise test of the analytic prediction of Karabali, Kim and Nair. We find that their prediction is within 3% of our values for all N and that the discrepancy decreases with increasing N. When we extrapolate our results to N=oo we find that there remains a discrepancy of ~ 1%, which is a convincing ~6 sigma effect. Thus, while the Karabali-Nair analysis is remarkably accurate at N=oo, it is not exact
We report a method to select optimal smearing parameters before production runs and discuss the adva...
We use a massively parallel supercomputer to simulate a 483.56 lattice with SU (2) pure gauge theory...
We calculate the spectrum of light glueballs and the string tension in a number of SO(N) lattice gau...
AbstractWe use lattice techniques to calculate the continuum string tensions of SU(N) gauge theories...
We calculate the energy spectrum of closed strings in SU(N) gauge theories with N=2,3,4,6,8 in 2+1 d...
We calculate energies and tensions of closed k-strings in (2+1)-dimensional SU(N) gauge theories wit...
We calculate the string tension and part of the mass spectrum of SU(4) and SU(6) gauge theories in 2...
We calculate the low-lying glueball spectrum and various string tensions in SU(N) lattice gauge theo...
We calculate energies and tensions of closed k-strings in (2+1)-dimensional SU(N) gauge theories wit...
We calculate the string tension and part of the mass spectrum of SU(4) and SU(6) gauge theories in 2...
We calculate the k = 2 string tension in SU(4) and SU(5) gauge theories in 3 + 1 dimensions, and com...
We calculate the string tension and part of the mass spectrum of SU(4) and SU(6) gauge theories in 2...
We calculate the string tensions of k-strings in SU(N) gauge theories in both 3 and 4 dimensions. We...
We study the spectrum of the confining strings in four-dimensional SU(N) gauge theories. We compute,...
Using a three-level algorithm we perform a high-precision lattice computation of the static force up...
We report a method to select optimal smearing parameters before production runs and discuss the adva...
We use a massively parallel supercomputer to simulate a 483.56 lattice with SU (2) pure gauge theory...
We calculate the spectrum of light glueballs and the string tension in a number of SO(N) lattice gau...
AbstractWe use lattice techniques to calculate the continuum string tensions of SU(N) gauge theories...
We calculate the energy spectrum of closed strings in SU(N) gauge theories with N=2,3,4,6,8 in 2+1 d...
We calculate energies and tensions of closed k-strings in (2+1)-dimensional SU(N) gauge theories wit...
We calculate the string tension and part of the mass spectrum of SU(4) and SU(6) gauge theories in 2...
We calculate the low-lying glueball spectrum and various string tensions in SU(N) lattice gauge theo...
We calculate energies and tensions of closed k-strings in (2+1)-dimensional SU(N) gauge theories wit...
We calculate the string tension and part of the mass spectrum of SU(4) and SU(6) gauge theories in 2...
We calculate the k = 2 string tension in SU(4) and SU(5) gauge theories in 3 + 1 dimensions, and com...
We calculate the string tension and part of the mass spectrum of SU(4) and SU(6) gauge theories in 2...
We calculate the string tensions of k-strings in SU(N) gauge theories in both 3 and 4 dimensions. We...
We study the spectrum of the confining strings in four-dimensional SU(N) gauge theories. We compute,...
Using a three-level algorithm we perform a high-precision lattice computation of the static force up...
We report a method to select optimal smearing parameters before production runs and discuss the adva...
We use a massively parallel supercomputer to simulate a 483.56 lattice with SU (2) pure gauge theory...
We calculate the spectrum of light glueballs and the string tension in a number of SO(N) lattice gau...