The spinorial geometry of supersymmetric heterotic string backgrounds

Abstract: We determine the geometry of supersymmetric heterotic string backgrounds for which all parallel spinors with respect to the connection∇ with torsion H, the NS⊗NS three-form field strength, are Killing. We find that there are two classes of such backgrounds, the null and the timelike. The Killing spinors of the null backgrounds have stability subgroups K ⋉ R 8 in Spin(9, 1), for K = Spin(7), SU (4), Sp(2), SU (2)×SU (2) and {1}, and the Killing spinors of the timelike backgrounds have stability subgroups G 2 , … Show more

“…Such theories are the common sector of type II supergravities and the heterotic supergravity. One simplification that occurs in the common sector and heterotic supergravities is that all solutions of the KSEs are known and the geometry of the backgrounds has been determined [25]- [27]. In particular, AdS 3 configurations arise naturally in the context of classification of supersymmetric heterotic backgrounds [25]- [27] and their geometry has also been examined 1 in [28].…”

“…One simplification that occurs in the common sector and heterotic supergravities is that all solutions of the KSEs are known and the geometry of the backgrounds has been determined [25]- [27]. In particular, AdS 3 configurations arise naturally in the context of classification of supersymmetric heterotic backgrounds [25]- [27] and their geometry has also been examined 1 in [28]. The AdS backgrounds are also special cases of the heterotic horizons in [29,30] though the latter has been explored only for a closed 3-form field strength H. In addition, there is a no-go theorem for AdS 4 heterotic backgrounds that has been established in [31,32] without assuming supersymmetry but imposing smoothness on the fields and compactness of the transverse 6-dimensional space.…”

“…If the solution of the KSEs is determined by the σ ± spinors, the investigation of the geometry of M 7 can be done as a special case of that of heterotic horizons in [29,30] which utilized the classification results of [25]- [27]. To see this first note that h = − 2 ℓ dz and so the constant k which enters in the description of geometry for the heterotic horizons is…”

“…This is because it is a consequence of the gravitino and dilatino KSEs that these vector fields close to a su(2) algebra [25]- [27]. The metric and torsion are given as in (2.35) but now the formulae are valid up to order α ′2 .…”

Geometry and supersymmetry of heterotic warped flux AdS backgrounds

“…Such theories are the common sector of type II supergravities and the heterotic supergravity. One simplification that occurs in the common sector and heterotic supergravities is that all solutions of the KSEs are known and the geometry of the backgrounds has been determined [25]- [27]. In particular, AdS 3 configurations arise naturally in the context of classification of supersymmetric heterotic backgrounds [25]- [27] and their geometry has also been examined 1 in [28].…”

“…One simplification that occurs in the common sector and heterotic supergravities is that all solutions of the KSEs are known and the geometry of the backgrounds has been determined [25]- [27]. In particular, AdS 3 configurations arise naturally in the context of classification of supersymmetric heterotic backgrounds [25]- [27] and their geometry has also been examined 1 in [28]. The AdS backgrounds are also special cases of the heterotic horizons in [29,30] though the latter has been explored only for a closed 3-form field strength H. In addition, there is a no-go theorem for AdS 4 heterotic backgrounds that has been established in [31,32] without assuming supersymmetry but imposing smoothness on the fields and compactness of the transverse 6-dimensional space.…”

“…If the solution of the KSEs is determined by the σ ± spinors, the investigation of the geometry of M 7 can be done as a special case of that of heterotic horizons in [29,30] which utilized the classification results of [25]- [27]. To see this first note that h = − 2 ℓ dz and so the constant k which enters in the description of geometry for the heterotic horizons is…”

“…This is because it is a consequence of the gravitino and dilatino KSEs that these vector fields close to a su(2) algebra [25]- [27]. The metric and torsion are given as in (2.35) but now the formulae are valid up to order α ′2 .…”

Geometry and supersymmetry of heterotic warped flux AdS backgrounds

“…The unique maximally supersymmetric solution preserving all supersymmetries is AdS 5 . Systematic classifications of 1/2-supersymmetric solutions were investigated in [19,20] using spinorial geometry techniques first implemented in the study of higher dimensional solutions in [21][22][23]. Using these methods, a restricted class of half-supersymmetric near-horizon geometries was analysed in [24].…”

Non-existence of supersymmetric AdS 5 black rings

Classification of supersymmetric backgrounds of string theory