We study the quantum phase transition from a Dirac spin liquid to an antiferromagnet driven by condensing monopoles with spin quantum numbers. We describe the transition in field theory by tuning a fermion interaction to condense a spin-Hall mass, which in turn allows the appropriate monopole operators to proliferate and confine the fermions. We compute various critical exponents at the quantum critical point (QCP), including the scaling dimensions of monopole operators by using the state-operator correspondence of conformal field theory. We find that the degeneracy of monopoles in QED3 is lifted and yields a non-trivial monopole hierarchy at the QCP. In particular, the lowest monopole dimension is found to be smaller than that of QED3 using a large N f expansion where 2N f is the number of fermion flavors. For the minimal magnetic charge, this dimension is 0.39N f at leading order. We also study the QCP between Dirac and chiral spin liquids, which allows us to test a conjectured duality to a bosonic CP 1 theory. Finally, we discuss the implications of our results for quantum magnets on the Kagome lattice.
We consider the Skyrme model modified by the addition of mass terms which explicitly break chiral symmetry and pick out a specific point on the model's target space as the unique true vacuum. However, they also allow the possibility of false vacua, local minima of the potential energy. These false vacuum configurations admit metastable skyrmions, which we call false skyrmions. False skyrmions can decay due to quantum tunnelling, consequently causing the decay of the false vacuum. We compute the rate of decay of the false vacuum due to the existence of false skyrmions.
We consider the decay of "false kinks," that is, kinks formed in a scalar
field theory with a pair of degenerate symmetry-breaking false vacua in 1+1
dimensions. The true vacuum is symmetric. A second scalar field and a peculiar
potential are added in order for the kink to be classically stable. We find an
expression for the decay rate of a false kink. As with any tunneling event, the
rate is proportional to $\exp(-S_E)$ where $S_E$ is the Euclidean action of the
bounce describing the tunneling event. This factor varies wildly depending on
the parameters of the model. Of interest is the fact that for certain
parameters $S_E$ can get arbitrarily small, implying that the kink is only
barely stable. Thus, while the false vacuum itself may be very long-lived, the
presence of kinks can give rise to rapid vacuum decay.Comment: 21 pages, 13 figure
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