Parallel spinors on globally hyperbolic Lorentzian four-manifolds

Abstract: We investigate the differential geometry and topology of globally hyperbolic fourmanifolds (M, g) admitting a parallel real spinor ε. Using the theory of parabolic pairs recently introduced in [22], we first formulate the parallelicity condition of ε on M as a system of partial differential equations, the parallel spinor flow equations, for a family of polyforms on any given Cauchy surface Σ ֒→ M . Existence of a parallel spinor on (M, g) induces a system of constraint partial differential equations on Σ, whic… Show more

“…These tuples contain the information about both the real parallel spinor and the underlying globally hyperbolic Lorentzian metric. The following theorem generalizes [23,Theorem 5.4] to the case in which {β t } t∈I is not necessarily constant.…”

“…In this section we briefly review the theory of parallel spinors on globally hyperbolic Lorentzian four-dimensional manifolds as developed in [14,23], where parallel spinors were characterized in terms of a certain type of distribution satisfying a prescribed system of partial differential equations.…”

“…Using this formalism, our first result (see Theorem 3.2) reformulates the evolution problem of a parallel spinor as a system of flow equations for a family of functions {β t } t∈I and a family of coframes {e t } t∈I on an appropriately chosen Cauchy hypersurface Σ ⊂ M . This system of equations yields a generalization of [23,Theorem 5.4] to the case in which the family {β t } t∈I is non-trivial and defines the notion of parallel spinor flow as a family {β t , e t } t∈I satisfying equations (3.6) and (3.7). Using the notion of parallel spinor flow, the constraint equations of the initial value problem of a parallel spinor can be shown to be equivalent to a differential system, the parallel Cauchy differential system [23], for a pair (e, Θ), where e is a coframe and Θ is a symmetric two-tensor on Σ.…”

“…This system of equations yields a generalization of [23,Theorem 5.4] to the case in which the family {β t } t∈I is non-trivial and defines the notion of parallel spinor flow as a family {β t , e t } t∈I satisfying equations (3.6) and (3.7). Using the notion of parallel spinor flow, the constraint equations of the initial value problem of a parallel spinor can be shown to be equivalent to a differential system, the parallel Cauchy differential system [23], for a pair (e, Θ), where e is a coframe and Θ is a symmetric two-tensor on Σ. One of the salient features of this formulation is that the Riemannian h metric induced by (M, g) on Σ is given by the canonical metric for which e = (e u , e l , e n ) becomes an orthonormal coframe, that is, h e = e u ⊗ e u + e l ⊗ e l + e n ⊗ e n .…”

“…Another important feature of parallel spinorial flows is that they admit a canonical notion of leftinvariance in terms of which we can define the notion of left-invariance of parallel spinors. The classification of all left-invariant parallel Cauchy pairs on simply connected three-dimensional Lie groups was completed in [23]. We use this result to obtain the classification of all associated leftinvariant parallel spinor flows.…”

Parallel spinor flows on three-dimensional Cauchy hypersurfaces

“…These tuples contain the information about both the real parallel spinor and the underlying globally hyperbolic Lorentzian metric. The following theorem generalizes [23,Theorem 5.4] to the case in which {β t } t∈I is not necessarily constant.…”

“…In this section we briefly review the theory of parallel spinors on globally hyperbolic Lorentzian four-dimensional manifolds as developed in [14,23], where parallel spinors were characterized in terms of a certain type of distribution satisfying a prescribed system of partial differential equations.…”

“…Using this formalism, our first result (see Theorem 3.2) reformulates the evolution problem of a parallel spinor as a system of flow equations for a family of functions {β t } t∈I and a family of coframes {e t } t∈I on an appropriately chosen Cauchy hypersurface Σ ⊂ M . This system of equations yields a generalization of [23,Theorem 5.4] to the case in which the family {β t } t∈I is non-trivial and defines the notion of parallel spinor flow as a family {β t , e t } t∈I satisfying equations (3.6) and (3.7). Using the notion of parallel spinor flow, the constraint equations of the initial value problem of a parallel spinor can be shown to be equivalent to a differential system, the parallel Cauchy differential system [23], for a pair (e, Θ), where e is a coframe and Θ is a symmetric two-tensor on Σ.…”

“…This system of equations yields a generalization of [23,Theorem 5.4] to the case in which the family {β t } t∈I is non-trivial and defines the notion of parallel spinor flow as a family {β t , e t } t∈I satisfying equations (3.6) and (3.7). Using the notion of parallel spinor flow, the constraint equations of the initial value problem of a parallel spinor can be shown to be equivalent to a differential system, the parallel Cauchy differential system [23], for a pair (e, Θ), where e is a coframe and Θ is a symmetric two-tensor on Σ. One of the salient features of this formulation is that the Riemannian h metric induced by (M, g) on Σ is given by the canonical metric for which e = (e u , e l , e n ) becomes an orthonormal coframe, that is, h e = e u ⊗ e u + e l ⊗ e l + e n ⊗ e n .…”

“…Another important feature of parallel spinorial flows is that they admit a canonical notion of leftinvariance in terms of which we can define the notion of left-invariance of parallel spinors. The classification of all left-invariant parallel Cauchy pairs on simply connected three-dimensional Lie groups was completed in [23]. We use this result to obtain the classification of all associated leftinvariant parallel spinor flows.…”

Parallel spinor flows on three-dimensional Cauchy hypersurfaces

Spinor flows with flux, I: short-time existence and smoothing estimates