Abstract
Half-maximal gauged supergravity in seven dimensions coupled to $n$ vector multiplets contains $n+3$ vectors and $3n+1$ scalars parametrized by $\mathbb{R}^+\times SO(3,n)/SO(3)\times SO(n)$ coset manifold. The two-form field in the gravity multiplet can be dualized to a three-form field which admits a topological mass term. Possible non-compact gauge groups take the form of $G_0\times H\subset SO(3,n)$ with a compact group $H$. $G_0$ is one of the five possibilities; $SO(3,1)$, $SL(3,\mathbb{R})$, $SO(2,2)$, $SO(2,1)$ and $SO(2,2)\times SO(2,1)$. We investigate all of these possible non-compact gauge groups and classify their vacua. Unlike the gauged supergravity without a topological mass term, there are new supersymmetric $AdS_7$ vacua in the $SO(3,1)$ and $SL(3,\mathbb{R})$ gaugings. These correspond to new $N=(1,0)$ superconformal field theories (SCFT) in six dimensions. Additionally, we find a class of $AdS_5\times S^2$ and $AdS_5\times H^2$ backgrounds with $SO(2)$ and $SO(2)\times SO(2)$ symmetries. These should correspond to $N=1$ SCFTs in four dimensions obtained from twisted compactifications of six-dimensional field theories on $S^2$ or $H^2$. We also study RG flows from six-dimensional $N=(1,0)$ SCFT to $N=1$ SCFT in four dimensions and RG flows from a four-dimensional $N=1$ SCFT to a six-dimensional SYM in the IR. The former are driven by a vacuum expectation value of a dimension-four operator dual to the supergravity dilaton while the latter are driven by vacuum expectation values of marginal operators.
Highlights
Of M-theory giving rise to the gravity dual of N = (2, 0) superconformal field theories (SCFT) [4,5,6]
In SO(3, 1) and SL(3, R) gaugings, we have found new supersymmetric AdS7 critical points
These should correspond to new N = (1, 0) SCFTs in six dimensions
Summary
By computing the scalar potential, we find that there are two AdS7 critical points with SO(3) symmetry as in the SO(3, 1) gauging for vanishing vector multiplet scalars. We will set g = 16h to bring the supersymmetric AdS7 to σ = 0. The characteristics of these two critical points are the same as in SO(3, 1) gauging, so we will not repeat them here. As in the previous case, the SO(3) singlet is the dilaton. In this case, there are five Goldstone bosons from the SL(3, R) → SO(3) symmetry breaking. We expect that there should be an RG flow from the supersymmetric AdS7 to the non-supersymmetric one. As in the previous case, the flow is driven by a VEV of the operator √dual to the dilaton σ.
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