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{cal N}=(1,0) Anomaly Multiplet Relations in Six Dimensions

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arxiv 1912.13475 v1 pith:UNXMTF5H submitted 2019-12-31 hep-th

{cal N}=(1,0) Anomaly Multiplet Relations in Six Dimensions

classification hep-th
keywords anomaliesconformalanomalyrelationsmultipletsuperconformaltheoriescorrelators
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We consider conformal and 't Hooft anomalies in six-dimensional ${\cal N}=(1,0)$ superconformal field theories, focusing on those conformal anomalies that determine the two- and three-point functions of conserved flavor and $SU(2)_R$ currents, as well as stress tensors. By analyzing these correlators in superspace, we explain why the number of independent conformal anomalies is reduced in supersymmetric theories. For instance, non-supersymmetric CFTs in six dimensions have three independent conformal $c$-anomalies, which determine the stress-tensor two- and three-point functions, but in superconformal theories the three $c$-anomalies are subject to a linear constraint. We also describe anomaly multiplet relations, which express the conformal anomalies of a superconformal theory in terms of its 't Hooft anomalies. Following earlier work on the conformal $a$-anomaly, we argue for these relations by considering the supersymmetric dilaton effective action on the tensor branch of such a theory. We illustrate the utility of these anomaly multiplet relations by presenting exact results for conformal anomalies, and hence current and stress-tensor correlators, in several interacting examples.

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