Group reduction of heterotic supergravity

Abstract

The reduction of ten-dimensional heterotic supergravity with Yang–Mills symmetry group K is performed on an arbitrary n-dimensional group manifold G. The reduction involves a non-vanishing 3-form flux, and the Lie algebra of G must have traceless structure constants to ensure the consistency of the reduction at the level of the action. A large class of gauged supergravities in d = 10 − n with (non)compact gaugings is obtained. The resulting models describe half-maximal gauged supergravities coupled to ( n + dim K ) vector multiplets. We uncover their hidden SO ( n , n + dim K ) duality symmetry, and the SO ( n , n + dim K ) / SO ( n ) × SO ( n + dim K ) coset structure that governs the couplings of the scalar fields. We find that the local gauge symmetry of the d-dimensional theory is K × G ⋉ R n . Differences from the existing gauged supergravities are highlighted. The consistent truncation to pure half-maximal gauged supergravity in any dimension is shown, and the obstacle to performing a chiral truncation of the theory in d = 6 dimensions is found. Among the results obtained are the complete diagonalisation of the fermionic kinetic terms, and other reduction formulae that are applicable to group reductions of supergravities in arbitrary dimensions.