%0 Generic %1 de2017nonperturbatively %A De, Asit K. %A Sarkar, Mugdha %D 2017 %K qed %R 10.1007/JHEP10(2017)125 %T Non-perturbatively gauge-fixed compact $U(1)$ lattice gauge theory %U http://arxiv.org/abs/1709.04831 %X An extensive study of the compact $U(1)$ lattice gauge theory with a higher derivative gauge-fixing term and a suitable counter-term has been undertaken to determine the nature of the possible continuum limits for a wide range of the parameters, especially at strong gauge couplings ($g>1$), adding to our previous study at a single gauge coupling $g=1.3$ DeSarkar2016. Our major conclusion is that a continuum limit of free massless photons (with the redundant pure gauge degrees of freedom decoupled) is achieved at any gauge coupling, not necessarily small, provided the coefficient $\kappa$ of the gauge-fixing term is sufficiently large. In fact, the region of continuous phase transition leading to the above physics in the strong gauge coupling region is found to be analytically connected to the point $g=0$ and $ınfty$ where the classical action has a global unique minimum, around which weak coupling perturbation theory in bare parameters is defined, controlling the physics of the whole region. A second major conclusion is that, local algorithms like Multihit Metropolis fail to produce faithful field configurations with large values of the coefficient $\kappa$ of the higher derivative gauge-fixing term and at large lattice volumes. A global algorithm like Hybrid Monte Carlo, although at times slow to move out of metastabilities, generally is able to produce faithful configurations and has been used extensively in the current study.

@misc{de2017nonperturbatively, abstract = {An extensive study of the compact $U(1)$ lattice gauge theory with a higher derivative gauge-fixing term and a suitable counter-term has been undertaken to determine the nature of the possible continuum limits for a wide range of the parameters, especially at strong gauge couplings ($g>1$), adding to our previous study at a single gauge coupling $g=1.3$ \cite{DeSarkar2016}. Our major conclusion is that a continuum limit of free massless photons (with the redundant pure gauge degrees of freedom decoupled) is achieved at any gauge coupling, not necessarily small, provided the coefficient $\tilde{\kappa}$ of the gauge-fixing term is sufficiently large. In fact, the region of continuous phase transition leading to the above physics in the strong gauge coupling region is found to be analytically connected to the point $g=0$ and $\tilde{\kappa} \rightarrow \infty$ where the classical action has a global unique minimum, around which weak coupling perturbation theory in bare parameters is defined, controlling the physics of the whole region. A second major conclusion is that, local algorithms like Multihit Metropolis fail to produce faithful field configurations with large values of the coefficient $\tilde{\kappa}$ of the higher derivative gauge-fixing term and at large lattice volumes. A global algorithm like Hybrid Monte Carlo, although at times slow to move out of metastabilities, generally is able to produce faithful configurations and has been used extensively in the current study.}, added-at = {2020-04-19T17:59:22.000+0200}, author = {De, Asit K. and Sarkar, Mugdha}, biburl = {https://www.bibsonomy.org/bibtex/2e54cefa33c818b11097c4b300277dd99/cmcneile}, description = {Non-perturbatively gauge-fixed compact $U(1)$ lattice gauge theory}, doi = {10.1007/JHEP10(2017)125}, interhash = {924bd76baf1267f669a50a2e8576bafe}, intrahash = {e54cefa33c818b11097c4b300277dd99}, keywords = {qed}, note = {cite arxiv:1709.04831Comment: 25 pages, 18 figures, version accepted for publication in JHEP}, timestamp = {2020-04-19T17:59:22.000+0200}, title = {Non-perturbatively gauge-fixed compact $U(1)$ lattice gauge theory}, url = {http://arxiv.org/abs/1709.04831}, year = 2017 }