Supermembranes with fewer supersymmetries

TL;DR

This paper generalizes supermembrane solutions in 11-dimensional supergravity by replacing the round 7-sphere with Einstein spaces, resulting in solutions with fewer preserved supersymmetries and new lower-dimensional brane solutions.

Contribution

It introduces a method to generate supermembrane solutions with fewer supersymmetries by using Einstein spaces instead of round spheres, expanding the landscape of supergravity solutions.

Findings

More general supermembrane solutions with Einstein spaces

Supersymmetry preservation depends on Einstein space properties

New lower-dimensional string solutions with reduced supersymmetry

Abstract

The usual supermembrane solution of $D=11$ supergravity interpolates between $R^{11}$ and $AdS_4 \times round~S^7$, has symmetry $P_3 \times SO(8)$ and preserves $1/2$ of the spacetime supersymmetries for either orientation of the round $S^7$. Here we show that more general supermembrane solutions may be obtained by replacing the round $S^7$ by any seven-dimensional Einstein space $M^7$. These have symmetry $P_3 \times G$, where $G$ is the isometry group of $M^7$. For example, $G=SO(5) \times SO(3)$ for the squashed $S^7$. For one orientation of $M^7$, they preserve $N/16$ spacetime supersymmetries where $1\leq N \leq 8$ is the number of Killing spinors on $M^7$; for the opposite orientation they preserve no supersymmetries since then $M^7$ has no Killing spinors. For example $N=1$ for the left-squashed $S^7$ owing to its $G_2$ Weyl holonomy, whereas $N=0$ for the right-squashed $S^7$. All these solutions saturate the same Bogomol'nyi bound between the mass and charge. Similar replacements of $S^{D-p-2}$ by Einstein spaces $M^{D-p-2}$ yield new super $p$-brane solutions in other spacetime dimensions $D\leq 11$. In particular, simultaneous dimensional reduction of the above $D=11$ supermembranes on $S^1$ leads to a new class of $D=10$ elementary string solutions which also have fewer supersymmetries.