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Anomalous Dimensions of Monopole Operators at the Transitions between Dirac and Topological Spin Liquids

Éric Dupuis, Rufus Boyack, William Witczak‐Krempa

2022Physical Review X22 citationsDOIOpen Access PDF

Abstract

Monopole operators are studied in a large family of quantum critical points between Dirac spin liquids and topological quantum spin liquids (QSLs): chiral and Z 2 QSLs. These quantum phase transitions are described by conformal field theories (CFTs): quantum electrodynamics in 2 1 dimensions with 2N flavors of two-component massless Dirac fermions and a four-fermion interaction term. For the transition to a chiral spin liquid, it is the Gross-Neveu interaction (QED 3 -GN), while for the transitions to Z 2 QSLs, it is a superconducting pairing term with general spin and valley structure (generalized QED 3 -Z 2 GN). Using the state-operator correspondence, we obtain monopole scaling dimensions to subleading order in 1=N. For monopoles with a minimal topological charge q 1=2, the scaling dimension is 2N 0.26510 at leading order, with the quantum correction being 0.118911(7) for the chiral spin liquid, and 0.102846(9) for the simplest Z 2 case (the expression is also given for a general pairing term). Although these two anomalous dimensions are nearly equal, the underlying quantum fluctuations possess distinct origins. The analogous result in QED 3 is also obtained, and we find a subleading contribution of -0.0381385, which is slightly different from the value -0.0383 first obtained in the literature. The scaling dimension of a QED 3 -GN monopole with minimal charge is very close to the scaling dimensions of other operators predicted to be equal by a conjectured duality between QED 3 -GN with 2N 2 flavors and the CP 1 model. Additionally, nonminimally charged monopoles with equal charges on both sides of the duality have similar scaling dimensions. By studying the large-q asymptotics of the scaling dimensions in QED 3 , QED 3 -GN, and QED 3 -Z 2 GN, we verify that the constant Oq 0 coefficient precisely matches the universal nonperturbative prediction for CFTs with a global U(1) symmetry. Finally, we identify numerous open questions regarding the fate of monopoles and their hierarchies at transitions to spin liquids and ordered phases.

Topics & Concepts

PhysicsMagnetic monopoleScaling dimensionQuantum mechanicsSpin (aerodynamics)Dirac fermionScalingDirac (video compression format)FermionMathematical physicsQuantum field theoryGeometryNeutrinoMathematicsThermodynamicsTopological Materials and PhenomenaAdvanced Condensed Matter PhysicsQuantum many-body systems
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