Quantum field theoretical study of an effective spin model in coupled optical cavity arrays

Atoms trapped in microcavities and interacting through the exchange of virtual photons can model an anisotropic Heisenberg spin-1/2 lattice. We do the quantum field theoretical study of such a system using the Abelian bosonization method followed by the renormalization group analysis. We present interesting physics due to the presence of exchange anisotropy. An infinite order Kosterliz-Thouless-Berezinskii transition is replaced by second order XY transition even an infinitesimal a small anisotropy in exchange coupling is introduced. We predict a quantum phase transition between Mott insulating and photonic superfluid phase due to detuning between the cavity and laser frequency, a large detuning favours the photonic superfluid phase. We also do the analysis of Jaynes and Cumming Hamiltonian to support results of quantum field theoretical study.