Mott insulators exhibit interesting quantum phase transitions. Typical Mott insulators are Heisenberg antiferromagnet such as, for example, the compound La2CuO4, whose ground state is a Néel state. In a Néel state, the SU (2) symmetry of the Hamiltonian is broken. A quantum phase transition to a paramagnetic state occurs by varying a certain characteristic parameter g of the system. In many Mott insulators, the paramagnetic phase breaks the lattice symmetries, leading to a valence bond solid (VBS) or a Peierls states. Also other exotic paramagnetic states are possible such as, for example, the so-called resonating valence bond (RVB) state. Such a pattern of quantum phase transition does not fit in the Landau-Ginzburg paradigm. Possible effective field theories include a compact U (1) gauge field, where topological defects like magnetic monopoles arise. We propose to study these gauge theories, which exhibit many interesting features of high-energy physics models, such as confinement and chiral symmetry breaking.

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