Construction of initial data sets for Lorentzian manifolds with lightlike parallel spinors
Bernd Ammann, Klaus Kroencke, Olaf M\"uller

TL;DR
This paper develops a method to solve the constraint equations for initial data sets of Lorentzian manifolds with lightlike parallel spinors, linking Riemannian metrics with parallel spinors to solutions of these equations.
Contribution
It introduces a new approach to solve the constraint equations using curves in the moduli space of Riemannian metrics with parallel spinors.
Findings
Any curve in the moduli space yields a solution on M×(a,b)
Closed curves in the moduli space produce solutions on M×S^1
Provides a constructive method to generate initial data sets
Abstract
Lorentzian manifolds with parallel spinors are important objects of study in several branches of geometry, analysis and mathematical physics. Their Cauchy problem has recently been discussed by Baum, Leistner and Lischewski, who proved that the problem locally has a unique solution up to diffeomorphisms, provided that the intial data given on a space-like hypersurface satisfy some constraint equations. In this article we provide a method to solve these constraint equations. In particular, any curve (resp. closed curve) in the moduli space of Riemannian metrics on with a parallel spinor gives rise to a solution of the constraint equations on (resp. ).
Peer Reviews
No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.
Videos
No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.
Construction of initial data sets for Lorentzian manifolds with lightlike parallel spinors
Bernd Ammann B.A. has been partially supported by SFB 1085 Higher Invariants, Regensburg, funded by the DFG.
Klaus Kröncke
Olaf Müller
Abstract
Lorentzian manifolds with parallel spinors are important objects of study in several branches of geometry, analysis and mathematical physics. Their Cauchy problem has recently been discussed by Baum, Leistner and Lischewski, who proved that the problem locally has a unique solution up to diffeomorphisms, provided that the intial data given on a space-like hypersurface satisfy some constraint equations. In this article we provide a method to solve these constraint equations. In particular, any curve (resp. closed curve) in the moduli space of Riemannian metrics on with a parallel spinor gives rise to a solution of the constraint equations on (resp. ).
Keywords: Parallel spinor, Lorentzian manifolds, Riemannian manifolds, special holonomy, moduli spaces
1 Introduction
1.1 Parallel spinors
Let be a connected -dimensional oriented and time-oriented Lorentzian manifold with a fixed spin structure. The bundle of complex spinors will be denoted by . The spinor bundle carries a natural Hermitian form of split signature, a compatible connection, and Clifford multiplication. In the present article we search for manifolds with a parallel spinor, i.e. a (non-trivial) parallel section of . Understanding Lorentzian manifolds with parallel spinors is interesting for several reasons.
The first reason is that Riemannian manifolds with parallel spinors provide interesting structures. We want to briefly sketch some of them: Parallel spinors provide a powerful technique to obtain Ricci-flat metrics on compact manifolds: All known closed Ricci-flat manifolds carry a non-vanishing parallel spinor on a finite covering. Parallel spinors are also linked to “stability”, defined in the sense that the given compact Ricci-flat metric cannot be deformed to a positive scalar curvature metric. This condition in turn is linked to dynamical stability of a Ricci-flat metric under Ricci flow: A compact Ricci-flat metric is dynamically stable under the Ricci flow if and only if it cannot be deformed to a positive scalar curvature metric ([20] and [23, Theorem 1.1]).
Infinitesimal stability was proven for metrics with a parallel spinor in [39] and local stability (for manifolds with irreducible holonomy) in [15]. Manifolds with parallel spinors provide interesting moduli spaces, see [3]. Furthermore parallel spinors help to understand the space of metrics with non-negative scalar curvature. The stability property explained above implies that every homotopy class in the space of positive scalar curvature metrics which is known to be non-trivial also remains non-trivial in the space of metrics with non-negative scalar curvature, see [35]. It is interesting and challenging to see to which extent it is possible to find Lorentzian analogues to these results.
A second reason to be interested in parallel spinors on arbitrary semi-Riemannian manifolds is that their existence implies that the holonomy is special [27, 28], [11], [22], [13], [8]. Thus the construction of Lorentzian manifolds with parallel spinors provides examples of manifolds with special holonomy.
A third reason is that parallel spinors are relevant in many fields of theoretical physics. For example parallel spinors on Lorentzian manifolds are often viewed as generators for the odd symmetries in a supersymmetric theory (see e.g. [16]). Parallel spinors are also important in several physical theories of Kaluza-Klein type, i.e. involving additional compactified dimensions. Mathematically we model them by a semi-Riemannian submersion from a high-dimensional Lorentzian manifold to a macroscopically visible 3+1-dimensional space-time . In this context one has to make sure that spectral and other analytic properties of Dirac operators on are comparable to the corresponding properties on . This requires the existence of harmonic spinors on the fibers , . If the scalar curvature assumed to be non-negative, these harmonic spinors are parallel which in turn implies that the fibers are Ricci-flat. Varying yields a family of metrics on with parallel spinors. One thus obtains a map B\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M), where \mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) is the (pre-)moduli space of metrics with a parallel spinor on some covering of , which is also a central ingredient in this article.
1.2 The Cauchy problem for parallel light-like spinors
Important progress about Lorentzian manifolds with parallel spinors was recently achieved by H. Baum, T. Leistner and A. Lischewski [10, 30, 29], see also [9] for associated lecture notes. In particular, these authors showed the well-posedness of an associated Cauchy problem which we will now describe in more detail and which will be the main topic of the present article.
Let again be a time- and space-oriented Lorentzian spin manifold, and let be the Hermitian product on with split signature. The Clifford multiplication on will be denoted by .
Note that for any spinor on a Lorentzian manifold one defines the Lorentzian Dirac current of by requiring that
[TABLE]
holds for all . Recall that on Lorentzian manifolds the Clifford action of vector fields on spinors is symmetric, in contrast to the Riemannian case, where it is anti-symmetric.
If is parallel, then is parallel as well. One can show that is a future oriented causal vector [9, Sec. 1.4.2, Prop. 2]. Thus is either time-like or light-like everywhere. In the time-like case, the Lorentzian manifold locally splits as a product , where is a Riemannian manifold with a parallel spinor. So with respect to a suitable Cauchy hypersurface the understanding of such metrics directly relies on the corresponding results on Riemannian manifolds.
In this article we are concerned with the case, that is a parallel spinor with a light-like Dirac-current . This problem was studied in [10], [30], and [29].
Let be a spacelike hypersurface in this Lorentzian manifold with induced metric . For a future-oriented (time-like) normal vector field with we define the Weingarten map . We use the symbol instead of , as the latter one will be used for the Weingarten map of hypersurfaces in , which will play a central role in our article. The Hermitian product and the Clifford multiplication on induce a positive definite Hermitian product and a Clifford multiplication on which can be characterized by the formulas
[TABLE]
for all , , . The spin structure on induces a spin structure on the spacelike hypersurface . Let be the associated spinor bundle of . With standard tools about Clifford modules, one sees that there is a bundle monomorphism over the identity of such that the Clifford multiplication and the Hermitian product on are mapped to and on . The bundle monomorphism is a bundle isomorphism if and only if is even. However note that is not parallel, i.e. the connection is not preserved under . More precisely is a linear pointwise expression in . From now on we identify with its image in under , taking the connection from . As already mentioned above we will also consider hypersurfaces of and the spinor bundle of . However the relation between spinors on and on is a bit easier than between spinors on and on . One can work with an embedding into which preserves the scalar product . We can even choose the embedding such that the Clifford multiplications coincide, however in the literature another embedding is often used which does no longer preserve the Clifford multiplication. In our application in Section 5 it depends on the parity of which embedding is more convenient for us, see also Subsection 2.3 and Appendix B for further information about hypersurfaces and spinors. Thus we want to use for the Clifford multiplication on in contrast to which is used for the Clifford multiplication on .
For any spinor we associate — see e.g. [29, (1.7)] — its Riemannian Dirac current by requiring
[TABLE]
By Lemma 20 in Appendix A we see, that the spinor satisfies if and only if we have for any
[TABLE]
Now, if we assume that carries a non-vanishing parallel spinor, then this spinor induces a spinor on such that
[TABLE]
where is defined as above and where
[TABLE]
see [10, (4) and following] or [29, (1.6) and (1.8)].
Note that the constraint equations (1)–(5) are not independent from each others. We comment on this in Appendix A.
Conversely, if is given as an abstract Riemannian spin manifold, and if , and satisfy (2), (3) and (4) with and defined by (1) and (5), then there is a Lorentzian manifold with as a Cauchy hypersurface and a parallel spinor, such that is the induced Riemannian metric, the Weingarten map and is induced by a parallel spinor on , see [29, Consequence of Theorems 2 and 3]. This was proven by solving the associated wave equations by using the technique of symmetric hyperbolic systems. A simpler approach, going back to a remark by P. Chrusciel was later given in [36, Chap. 4].
The question arises on how to solve these constraint equations. In the present article we will describe a new method to obtain solutions of these constraint equations. We will see how any smooth curve in the (pre-)moduli space of closed -dimensional Riemannian manifolds with a parallel spinor together with a scaling function yields a solution to the constraint equations, see our Main Construction 15 in Section 6. And thus the well-definedness of the Cauchy problem implies the existence of an associated -dimensional Lorentzian with a parallel spinor. Such a relation between families of metrics with special holonomy and solutions of the constraint equations was already conjectured by Leistner and Lischewski, see [29]. We essentially show that the conditions in [29, Table 1] is satisfied if and only if the divergence condition (31) in our Appendix D is satisfied.
We also derive versions of this construction to obtain initial data on a compact Cauchy hypersurface (without boundary). A first idea is to use a smooth closed curve in the (pre-)moduli space of closed -dimensional Riemannian manifolds with a parallel spinor together with a scaling function. However this will in general not lead to a solution of the original constraint equation, but to a twisted version thereof, see Main Construction 17. This will lead to a Lorentzian manifold with a parallel twisted spinor. Here the twist bundle is always a complex line bundle with a flat connection.
In special cases – more precisely assuming the “fitting condition” introduced in Section 6 we however obtain solutions of the constraint equations in the original (i.e. untwisted) sense, see Main Construction 16.
We consider it as remarkable that compared to other classical diffeomorphism invariant Cauchy problems in Lorentzian geometry, e.g. the Cauchy problem for Ricci-flat metrics, we get a large quantity of solutions to the constraint equations. Furthermore it is amazing that the solutions in our situation correspond to curves in the moduli space, while the set of solutions of the constraints in classical problems have no similar description. An important input for our article was the smooth manifold structure of the premoduli space \mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) and the fact that the BBGM connection preserves parallel spinors along divergence free Ricci-flat families of metrics. Ricci-flat deformations of a metric thus preserve the dimension of the space of parallel spinors. The infinitesimal version of this should be seen as some kind of Hodge theory: infinitesimal Ricci-flat deformations can be viewed as elements of while infinitesimal deformations with parallel spinors can be viewed as elements of — and on compact manifolds Hodge theory tells us that . Let us also compare the results of this paper to the tightly related recent preprint [2]. While the current paper constructs initial data for Lorentzian manifolds with a parallel spinor, one of the major themes in [2] is to get topological obstructions for a closed spin manifold to be a spacelike hypersurface in a Lorentzian manifold with a parallel spinor. We also mentioned that the special case of -dimensional Lorentzian manifolds (i.e. initial data on -dimensional manifolds) was studied in the recent preprint [32].
The structure of the article is as follows. In Section 2 we fix some conventions, recall and extend known facts about Clifford modules and about spinors on hypersurfaces. We also explain how to differentiate a spinorial expression such as the Levi-Civita derivative of a spinor with respect to the Riemannian metric . The known results for defining this differential along a path of metrics is recalled in Subsection 2.4, this includes the BBGM parallel transport and the associated connection which arises from the universal spinor bundle construction; the concrete calculations are a central tool of the article and are carried out in Section 3. In Section 4 we show that for divergence free Ricci-flat deformations, the BBGMconnection preserves parallel spinors, a result which we consider an interesting outcome of the article independently of the application to the constraint equations, mainly discussed in the article. In Section 5 we use this construction to obtain solutions of the constraint equations (1) – (5). In Section 6 we establish the connection to curves in (pre-)moduli spaces and we also discuss on how to obtain solutions on compact Cauchy hypersurfaces. The article ends with several appendices where we provide some details about facts which are already well-known, but where adequate literature was not available. We hope that these appendices help to make the article sufficiently self-contained.
Acknowledgements. We thank Helga Baum, Thomas Leistner and Andree Lischewski for bringing our attention to this problem and for enlightening talks and discussions. Our special thank goes to Andree Lischewski for sharing the above mentioned conjecture with us, already at an early stage. We also thank both referees for many good and substantial comments.
2 Preliminaries
2.1 Conventions
All Hermitian scalar products in this article are complex linear in the first entry and complex anti-linear in the second one. Let be a Riemannian vector bundle over a compact Riemannian manifold equipped with a metric connection and . Then the Sobolev norm of a section is
[TABLE]
where is the volume element of . As usual, we denote . We will write if we wish to emphasise the dependence of the norm on .
We use the symbol for the symmetrized tensor product, i.e. for a finite-dimensional real vector space the space of symmetric bilinear forms is denoted by . Let be the subset of positive definite symmetric forms on . Applying this fiberwise to the tangent bundle we obtain the vector bundle and the bundle .
Definition 1**.**
On a Riemannian manifold the Einstein operator is the elliptic differential operator , given by
[TABLE]
where is a local orthonormal frame. Here, the curvature tensor is defined with the sign convention such that .
The Einstein operator is linked to the deformation theory of Ricci-flat metrics as follows: Let be a Ricci-flat metric and a smooth family of Ricci-flat metrics through , then
[TABLE]
where is a vector field and , i.e. the essential part of a Ricci-flat deformation is an element in . In particular, if is a family of metrics with a parallel spinor, the essential part of its -derivative is contained in . For more details on the deformation theory of Ricci-flat metrics, see [12, Chapter 12 D].
2.2 Some facts about Clifford modules
In this subsection we briefly summarize some facts about representations of Clifford algebras. The interested reader might consult the first Chapter of the book by Lawson and Michelsohn [26] for further details.
Let be the canonical basis of . The complexified Clifford algebra for with the Euclidean scalar product will be denoted by . In this section all Clifford multiplications are written as , independently on ; we use the convention that does not depend on . In the following section we will then explain that the associated bundle construction then turns this Clifford multiplication both into the Clifford multiplication on and the Clifford multiplication on .
We define the complex volume element as
[TABLE]
where , and . The choices imply . The choice of sign for in the literature varies between different sources, our particular and unconventional choice yields an easy formulation of Lemma 2.
For even, there is a unique irreducible complex represention of . Here and in the following “unique” will always “unique up to isomorphism of representation”. This unique representation will be denoted by . It comes with a grading given by the eigenvalues of .
For odd there are two irreducible representations, and as is central, Schur’s Lemma implies that acts either as the identity or minus the identity which allows us to distinguish the two representations. For odd, we will assume that is the irreducible representation on which acts as the identity. The other representation is called . In the following denotes either or for odd and for even .
The standard inclusion , induces an inclusion . This turns into a -module. In particular, the Clifford action of is the same if is viewed as an element of or . 111Here we do not follow the convention chosen by Bär, Gauduchon and Moroianu [6], where vectors in have two different Clifford actions on , depending on whether it is seen as an element in or -action.
Thus, if is odd, we can choose (and fix from now on) isometric isomorphisms of -modules and . If is even, then we can choose (and fix from now on) an isometric isomorphism of -modules .
Lemma 2**.**
For odd, and are -linear isomorphisms of complex -representations and they satisfy
[TABLE]
for all . For even there are isometric monomorphisms of complex -representations and , satisying
[TABLE]
for all and for any .
Proof.
If is odd, then we see that , thus . This implies . Hence, we obtain (6):
[TABLE]
The verification of (7) is analogous. As these morphisms are -linear, and as is contained in , the morphisms are also -equivariant.
If is even, then we define
[TABLE]
Equations (8) and (9) are obvious. The morphisms are no longer -linear. However commutes with which is defined as the even part of , i.e. the sub-algebra generated by elements of the form with . As a consequence the morphisms are -linear. As is contained in , the morphisms are -equivariant.
To show that the morphisms are isometric (and thus also injective) it suffices to show , where or . We argue only for , as the other case is completely analogous. As and anticommute, is an eigenvector of to the eigenvalue , while is an eigenvector to the eigenvalue . As is self-adjoint, orthogonality follows. ∎
Remark 3*.*
Let be even. Clifford multiplication with anticommutes with all odd elements in , in particular with and vectors . Thus, the map restricts to a vector space isomorphism which anticommutes with Clifford multiplication by vectors in .
2.3 Spinors on hypersurfaces
In this section we want to describe how one can restrict a spinor on an -dimensional Riemannian spin manifold to a spinor on an oriented hypersurface carrying the induced metric . As, this restriction is local, we can assume — by restricting to a tubular neighborhood of and using Fermi coordinates, i.e. normal coordinates in normal directions — that and where .
Conversely, given a family of metrics and spinors , , we want to obtain a spinor on , .
Note that this description does not include the passage from a Lorentzian manifold to a spacelike hypersurface and vice versa, described in the introduction, which plays an important role in the work of Baum, Leistner and Lischewski. For this Lorentzian version analogous techniques are well presented in the lecture notes [9, Sec. 1.5].
For the Riemannian case, which is the goal of this section, a standard reference is [6]. However for the purpose of our article it seems to be more efficient to choose some other convention, following e.g. [1, Sec. 5.3]. To have a fluently readable summary, we do not include detailed proofs in this section. For self-containedness we include them in Appendix B.
In the following let be the vertical bundle of the projection , i.e. , viewed as a bundle over .
For each let be the -principal bundle of positively oriented orthornormal frames on , and let be defined as the corresponding -bundle over . We note . The union of the bundles is an -principal bundle over , which we will denoted by (whose topology and bundle structure is induced by the -reduction of the -principal bundle of all frames over containing ). We get a map , mapping to which yields an isomorphism . Any topological spin structure on yields a -principal bundle with a -equivariant map in the usual way. This map induces
[TABLE]
which is a spin structure on . In particular this induces a bijection from the set of spin structures on (up to isomorphism) to spin structures on (up to isomorphism).
The complex volume elements and then provide associated complex volume elements
[TABLE]
where is any positively oriented basis in resp. .
Using the associated bundle construction, we obtain for odd:
[TABLE]
The grading yields a grading which is the grading by eigenvalues of .
For even we have
[TABLE]
and the grading yields a grading , given by eigenvalues of .
The Clifford multiplications , , induce Clifford multiplications , . As indicated before we use the symbols “” and “” to distinguish properly between the Clifford multiplication of and the one of .
Furthermore the maps , , , and from Lemma 2 induce vector bundle maps over which are isometric injective -linear maps in each fiber. For odd, we obtain fiberwise isomorphisms
[TABLE]
These maps commute with Clifford multiplication by vectors tangent to . They satisfy
[TABLE]
for all .
On the other hand we get for even
[TABLE]
These maps do not commute with Clifford multiplication by vectors tangent to , and they are not surjective in any fiber. However, they satisfy
[TABLE]
for all and for any .
The bundle maps defined above do not preserve the (partially defined) Levi-Civita connections on the bundles. They modify the connection by terms depending on the second fundamental form of in . This is made precise in the following lemma.
Lemma 4**.**
Let be one of the bundle maps defined above. For , and resp. we have
[TABLE]
where the Weingarten map is defined through .
A proof will be given in Appendix B.
In combination with equations (10), (11), (12), and (13) we will see later in this article that families of -parallel spinors will lead to solutions of the generalized imaginary Killing spinor equation (3) which is one of the constraint equations.
2.4 BBGM connection
Let be a compact spin manifold. We denote the space of all Riemannian metrics on by . For every metric we define
[TABLE]
and the disjoint union
[TABLE]
One can equip and naturally with the structure of a Fréchet bundle . This bundle structure is needed to define a connection on this bundle. The oldest references that we used are by Bourguignon and Gauduchon [14] resp. by Bär, Gauduchon and Moroianu [6], this is why we choose the abbreviation BBGM for the four names. However we were told that there was also work by Bismut. The concepts were later properly formalized under the name ’universal spinor bundle’ in [4] and [31], where a finite-dimensional fiber bundle with a partial connection is constructed whose sections correspond to the elements of such that the parallel transport corresponds to the BBGM parallel transport. The connection is given in terms of horizontal spaces , i.e. vector spaces satisfying
[TABLE]
in the sense of topological vector spaces such that
[TABLE]
restricts to an isomorphism . In other words we obtain an injective map of Fréchet spaces by postcomposing with the inclusion of .
The space will smoothly depend on and will be compatible with the vector bundle structure of . We do not require more knowledge about Fréchet manifolds in our article, so we do not introduce this Fréchet structure in more detail.
To describe the horizontal space precisely we give the maps : We assume that . Let be a smooth path of metrics such that and . We consider the cylinder with the metric . Then, similar to [6] we can extend the spinor , defined on , uniquely to a spinor on satisfying where denotes the Levi-Civita connection on the cylinder. Note that may be interpreted as a family, parametrized over , of spinor fields with respect to the family of metrics . The restriction of to , denoted by is a spinor for the metric , and is a smooth path in . We now define
[TABLE]
Lemma 5**.**
The map is well-defined, linear, and smooth in .
The lemma follows from the construction of the universal spinor bundle given in [31]. The strategy in that paper is as follows: Let be the bundle of positive definite symmetric bilinear forms on . A complex vector bundle is constructed, called the universal spinor bundle, which carries a scalar product, a Clifford multiplication with vectors in and partial connection on with respect to . The Clifford multiplication is given by a bilinear map for every . Note that is a scalar product on one single tangent space, namely on , and thus is thus a fiber of the vector bundle . This Clifford multiplication shall satisfy the Clifford relations and shall depend smoothly on . By “partial connection” we mean that for any section of the bundle , the covariant derivative is defined for some if and only (i.e., is vertical for ). This partial connection comes from the vertical connection defined in [31, Definition 2.10], and allows to define a map as above. In particular this shows that does not depend on how we choose , but only its derivative a .
3 Variation of the parallel spinor equation
Let us first recall a result from [4]: For let be the map defined by
[TABLE]
In [4, Sec. 4.3] a similar map was defined, namely which is related to by the formula . It was shown in [4, Lemma 4.12] that this is related to the differential of the map , as follows:
[TABLE]
We define the Wang map as the composition
[TABLE]
so that
[TABLE]
It is easy to see (c. f. [15, Lemma 2.3, 1.]) that
[TABLE]
and
[TABLE]
Lemma 6**.**
If is a parallel spinor on , then the diagram
\bigodot\nolimits^{2}T^{*}M$$\Gamma(\Sigma^{g}M\otimes T^{*}M)$$\Gamma(\Sigma^{g}M\otimes T^{*}M)$$\mathcal{W}_{g,\varphi}$$4\hat{\kappa}_{g,\varphi}+\varphi\otimes\mathop{\mathrm{div}}\nolimits^{g}$$D^{T^{*}M}
commutes. In other words we have for any
[TABLE]
where, for a vector bundle over with connection we define the Dirac operator on by where is the product connection.
Proof.
Let . Then . We now assume that is a local orthonormal frame satisfying at for , and we calculate in
[TABLE]
∎
Very similarly we prove for arbitrary sections and :
[TABLE]
where is defined as .
The following lemma is a straightforward generalization of a Lemma by McKenzie Wang [39, Lemma 3.3 (d) for ], see also [15, Prop. 2.4].
Lemma 7**.**
For and we have
[TABLE]
In particular, if is a parallel spinor, then the diagram
\Gamma(\bigodot\nolimits^{2}T^{*}M)$$\Gamma(\bigodot\nolimits^{2}T^{*}M)$$\Gamma(\Sigma^{g}M\otimes T^{*}M)$$\Gamma(\Sigma^{g}M\otimes T^{*}M)$$\mathcal{W}_{g,\varphi}$$\mathcal{W}_{g,\varphi}$$\Delta_{E}$$(D^{T^{*}M})^{2}
commutes.
Proof.
We can locally write
[TABLE]
where is a local orthonormal frame with respect to with at . We define , , and let be the associated curvature. By using the Clifford relations, we get on the domain of the frame:
[TABLE]
Now we apply to this equation and we use the notation . Then we get from the previous equation at the point
[TABLE]
Moreover,
[TABLE]
and
[TABLE]
By using the relation ,
[TABLE]
By adding up, a lot of terms cancel and we are left with
[TABLE]
so it remains to consider the term . We have
[TABLE]
By the formula which expresses the curvature of in terms of the curvature of , we obtain . Using the relation , we get
[TABLE]
and
[TABLE]
We get
[TABLE]
From the standard identities
[TABLE]
we deduce
[TABLE]
which yields the final result. ∎
4 The BBGM parallel transport preserves parallel spinors
Proposition 8**.**
Let be an interval, be a path of Ricci-flat metrics with a divergence free derivative, , and let be a parallel spinor on . Let, for all , be a spinor on such that . Then is a parallel spinor on for all .
Here should be understood as a derivation with respect to the BBGM connection.
In the proof of Proposition 8, we need a statement about continuous dependence of eigenvalues of the Dirac operator on the metric.
Theorem 9**.**
There exists a family of functions , such that
- •
* for all *
- •
The family is nondecreasing, i.e. whenever .
- •
**
The theorem in the above version is proven in detail in [33, Main Theorem 2], but the statement we need was well-known long before.
To prove the proposition, we will at first prove the same statement under more restrictive assumptions.
Lemma 10**.**
Let be a path of Ricci-flat metrics with a divergence free derivative, , and let be a parallel spinor on . Assume that is constant along . Let be a spinor on such that . Then is a parallel spinor on for all .
Proof of Lemma 10.
Without loss of generality we can assume that is compact. Using Rayleigh-Ritz type arguments, explained e.g. in detail in [33], one can show the existence of continuous functions , such that are the eigenvalues (including the correct multiplicity) of . If the kernel of has constant dimension , then we can assume . Then for
[TABLE]
the operator has no eigenvalue in . Because of this, there are bounded operators
[TABLE]
that invert on the orthogonal complement of the kernel and that are uniformly bounded by . By elliptic theory, see e.g. [26, Chapter III §5] we have isomorphisms
[TABLE]
Because of , there is a constant such that for any and for any we have
[TABLE]
Moreover, by the facts collected in Subsection 2.1. We calculate using Lemma 7
[TABLE]
thus pointwise is a linear expression in and its first derivative. Thus
[TABLE]
where depends on . This implies, using Eq. (20):
[TABLE]
We now differentiate using formulae (16) and (17) and Lemma 6.
[TABLE]
This implies, with Eq. 21:
[TABLE]
where and depend on .
We set . In order to derive one has to be aware that also the evaluating metric depends on . The dependence on the metrics effects in the metric contractions, the volume element and in the covariant derivatives used to define by . Due to compactness of , these effects lead to a number , constant in , such that
[TABLE]
and we get
[TABLE]
As this implies with Grönwall’s inequality that vanishes for all . ∎
Remark 11*.*
In the proof above the derivative should be taken with some care. Here we derive an -dependent family with respect to the metric variation given by . This is the BBGM-derivative in the spinorial part. On the cotangential part, one could also use a BBGM-kind of derivative, but this is not what was used. On the cotangential part, we simply used the derivative in the usual sense, i.e. the derivative of a curve in the vector space .
Proof of Proposition 8.
In a first step we prove the Proposition for analytic families , of Ricci-flat metrics, in other words we assume that the map defined by is analytic.
Then is an analytic family of operators. This implies that the eigenvalues of can be numbered such that is analytic in [21, Appendix A]. Due to Theorem 9, only finitely many have zero sets on a compact interval. Let , and which is a closed discrete subset due to analyticity. (We conjecture that , but we were unable to prove it.) Let be a connected component of . The previous lemma states that the Bourguignon-Gauduchon parallel transport along maps parallel spinor to a parallel spinor for any . Let . Then by continuity,
[TABLE]
is a parallel section of . We use the fact that the dimension of the space of parallel spinors is locally constant (see [3]), thus for any and and (including ) the monomorphism from parallel spinors in to parallel spinors in is an isomorphism. Thus BBGM parallel transport perserves parallel spinors along , and by an induction argument (using that is finite in compact intervals) this also holds along . The proposition is thus proven for analytic families and thus also for piecewise analytic families .
Now, as the Riemannian metrics form an open cone in the vector space of bilinear forms, an arbitrary smooth family can be approximated by piecewise analytic paths in the -norm. We claim that the BBGM parallel transport is continuous in this limit. This can be seen most easily in the universal spinor bundle formulation: There, for being the bundle of symmetric positive definite bilinear forms, a Clifford bundle is constructed such that, for each , is isomorphic as a Clifford bundle to . Furthermore, the vector bundle carries a vertical (w.r.t. ) covariant derivative whose parallel transport is linked to the BBGM parallel transport as follows: Let , be a -curve of Riemannian metrics on . Let and let and , then for any with we have
[TABLE]
The parallel transport along a curve with respect to a connection is given by a first order ordinary differential equation (ODE), satisfying the conditions of the theorem of Picard-Lindelöf. Using the universal spinor bundle formalism we argued that the BBGM-parallel transport is given by such an ODE and that its coefficient functions converge uniformly (i.e. in the -norm) when a path of metrics converges in the -norm to a limit path of metrics.222To be precise: we only need control of the norm
Thus the theorem of Picard-Lindelöf, taking into account that both and are compact, implies that the BBGM parallel transport converges uniformly when we approximate a smooth path of metrics by piecewise analytic paths of metrics in the -norm. Thus the BBGM parallel transport also preserves parallel spinors along the smooth family . ∎
5 Construction of solutions to the constraint equations
In this section we want to use the BBGM connection to construct solutions of the constraint equation on suitable manifolds of the form where is an interval and where is an -dimensional manifold.
Assume that is a family of Ricci-flat metrics with divergence-free derivative and that for some there is a non-trivial parallel spinor on . By rescaling we can achieve that its norm is in every point. We shift it in the -direction parallely with the BBGM parallel transport. By Prop. 8 we obtain a family of -parallel spinors of constant norm on , for every . This yields a fiberwise parallel section of . Recall .
In the following we assume that is a given smooth function and choose . We define , i.e. .
Case is odd, i.e. even. By possibly changing the orientation and using Proposition 25 in Appendix C we can assume that all have the positive parity for the splitting given by the volume element of , i.e. we can assume . For every we use the map from Section 2.3 to get identifications . Again the Clifford multiplication for will be denoted by , and for the one for , we will use . From Equation (10) we get . Using Lemma 4 we obtain
[TABLE]
We set
[TABLE]
Assuming that is tangent to , we obtain
[TABLE]
Thus is an imaginary -Killing spinor with , i.e. it satisfies (3).
The first relation and the defining equation (22) also imply . For tangent to , the real part of vanishes and
[TABLE]
where in we used the skew-symmetry of Clifford multiplication with vectors twice and . On the other hand one , which in particular holds for . We thus get .
Thus for every vector and consequently, the Dirac current of , defined by for every vector (see (1)) is . We obtain
[TABLE]
which is the constraint equation (4) for . Note that here we used (5) as definition for . We thus have obtained solutions of the constraint equations.
Case even, i.e. odd. We use the map defined in Section 2.3 to view as a subbundle of . In particular, then yields a section of constant length of the bundle .
Because of equations (12) and (13) we have . Using Lemma 4 we obtain
[TABLE]
We set
[TABLE]
Then for tangent to ,
[TABLE]
Thus, is an imaginary -Killing spinor with , i.e. it satisfies (3). With the same arguments as in the other case, we can prove that (1), (2), (4), and (5) are satisfied, i.e. we have found a solution to the constraint equations.
Example 12**.**
Let , be a flat metric on and a parallel spinor on it.
- •
Let with . The BBGM parallel transport leaves invariant and we obtain initial data to the Cauchy problem on the metric on either or . The Minkowski metric together with a parallel spinor (or in the case a -quotient of it) is then a solution of the associated Cauchy problem.
- •
Let with . For the submanifolds we have for alle . We take the function , i.e. and . The metric we obtain is now the hyperbolic metric on together with an imaginary Killing spinor with Killing constant . The Lorentzian cone , where , together with a parallel spinor solves solves the associated Cauchy problem. Note that this cone is the quotient by a -action of , defined as the set of all future-oriented time-like vectors in the -dimensional Minkowski space .
Remark 13*.*
In this example we have seen two different ways of reconstructing Lorentzian Ricci-flat metrics on quotients of subsets of Minkowski space together with a parallel spinor. However, our construction allows many more interesting examples.
Example 14**.**
- •
Any imaginary Killing spinor on a complete, connected Riemannian spin manifold arises this way. This was proven by Baum, Friedrich, Grunewald and Kath in **[7, Chap. 7]**, more precisely in Theorem 1 on page 160 and Cor. 1 on page 167 **[7, Chap. 7]**.
- •
This was generalized by Rademacher **[34]**, see also **[18*, Theorem A.4.5]**. Rademacher proved that any generalized imaginary Killing spinor with , arises by our construction. *
- •
Our construction generalizes previous constructions of imaginary Killing spinors, as e.g. **[19, Prop. 4.6 and Cor. 4.7]**.
6 From curves in the moduli space to initial data sets
Let be the identity component of the diffeomorphism group of , acting on the space of structured Ricci-flat metrics by pullback (as usual, a semi-Riemannian manifold is called structured iff its semi-Riemannian universal covering admits a parallel spinor). Furthermore, let \mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M):=\mathcal{M}_{\parallel}(M)/\mathop{\mathrm{Diff}}\nolimits_{0}(M) be the associated premoduli space. It was shown in [3] (using previous work about the special case of simply connected manifolds with irreducible holonomy) that \mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) “naturally” carries the structure of a finite-dimensional smooth manifold. The smooth structure on \mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) can be described by the following properties
- •
\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) carries the quotient topology, if we equip and with the standard Fréchet topology,
- •
any smooth family , yields a smooth map N\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M), ,
- •
in the case one has if and only if is tangent to the -orbit through .
If is an interval, then any smooth curve I\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) can be written as with a family of metrics , see Appendix D.
The main results of this article is a procedure to construct initial data for the constraint equations for Lorentzian metrics with parallel spinors.
Main Construction 15** (Initial data on an open manifold).**
Let be an interval. For any smooth curve I\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) and every positive smooth function we obtain a solution of the initial data equations (3) and (4) on with norm at any .
Here the metric on is given by provided that is chosen such that and the spinor is given by (22) resp. (23). In particular the spinor can be normalized such that it has norm at any . As derived in the preceding section, (3) are then satisfied, as well as (1), (2), (4), and (5).
The situation is slightly more complicated if we want to obtain solutions of the constraint equations on a closed manifold. We start with a closed curve S^{1}\cong\mathbb{R}/L\mathbb{Z}\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M). If we identify with , then every curve \mathbb{R}/L\mathbb{Z}\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M) can be written as [0,L]\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M), with , but in general we will have although and are isometric with respect to an isometry . We then glue with isometrically using the diffeomorphism . This yields a closed Riemannian manifold diffeomorphic to . In order to equip it with a spin structure we have to lift to a map between the corresponding spin structures . This yields a spin structure and a spinor bundle on . Let be given. For any parallel spinor on equation (22) resp. equation (23) yields a generalized imaginary Killing spinor on as in Main Construction 15. The gluing described above allows to view as a parallel spinor on . However, in general will differ from . Let denote the space of parallel spinors on . Then yields a unitary map . The map does neither depend on nor on the parametrization of the curve . We say that satisfies the fitting condition if for a suitable choice of spin structure on . The fitting condition is always satisfied in the following cases:
- (1)
is a -dimensional manifold with holonomy 2. (2)
is an -dimensional manifold with holonomy 3. (3)
is a Riemannian product of manifolds of that kind and of at most one factor diffeomorphic to . 4. (4)
finite quotients of such manifolds
As this statement is not within the core of this article, we only sketch the proof. In the first two cases the spinor bundle is the complexification of the real spinor bundle , and thus . The real spinor representations of and on have a 1-dimensional invariant subrepresentation, thus . Thus is either or , and the -sign can be achieved by a suitable choice of the lift . On it follows from a direct calculation.
The map behaves “well” under taking products and finite quotients, thus the other two statements follow as well.
For manifolds with a least one factor of holonomy or , or also for tori of dimension , however, we expect that generically the fitting condition does not hold. In this case, we expect that the space of closed paths for wich has finite order (in the sense ) is dense in the space of all closed paths with respect to the -topology. This is in fact a consequence of work in progress by Bernd Ammann, Klaus Kröncke and Hartmut Weiß.
Then passing to an -fold cover of obtained from running along the path not just once, but times, we obtain a solution of the constraint equation on .
Main Construction 16** (Initial data on a closed manifold).**
Let . Let \mathbb{R}/L\mathbb{Z}\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M), be a smooth path and let be given such that satisfies the fitting condition. Then for any function we obtain a solution of the initial data equations (3) and (4) on .
It also seems interesting to us to allow a slight generalization of our initial problem, by considering spinc spinors with a flat associated line bundle instead of spinors in the usual sense. Assume that has norm . Identifying with yields a complex line bundle over . On we choose the connection such that local sections with constant are parallel. By pull back we obtain complex line bundles with flat, metric connections on and on . These line bundles will also be denoted by . The bundle resp. is then a spinc-spinor bundle with flat associated bundle . The objects tensored by will be called -twisted. All the results of this article immediately generalize to -twisted spinors. We ask for -twisted parallel spinors, i.e. parallel sections of instead of parallel spinors in the usual sense. This leads to -twisted constraint equations, and the -twisted Cauchy problem can be solved the same way as the untwisted.
Let P\in\mathop{\mathrm{U}}\nolimits\bigl{(}\Gamma_{\parallel}(\Sigma_{g_{0}}M)\bigr{)} be as above. As is unitary, there is a basis of consisting of eigenvectors of for complex eigenvalues of norm .
Main Construction 17** (Spinc-version).**
Let . Let \mathbb{R}/L\mathbb{Z}\to\mathop{\text{\mathcal{M}\kern-1.5pt{od}}}\nolimits_{\parallel}(M), be a smooth path. Let be an eigenvalue of to the eigenvalue . Then for any function we obtain a solution of the -twisted version of the constraint equations (3) and (4) on .
Appendix A Independence of the constraint equations
In this appendix we want to show that the constraint equations (1)–(5) presented in the introduction are not independent equations. We will show that all of them follow from (3) and a rewritten version of (4). In particular, we will see that for a generalized imaginary Killing spinor equation (4) implies (2), unless the vector field vanishes everywhere. In the introduction (1)–(5) are a mixture of definitions and relations. Let us rewrite them in a form which is more suitable to clarify their dependences.
We assume that is a connected Riemannian spin manifold. Let be the associated spinor bundle. Compared to the introduction we slightly simplify our notation: we write here for the Clifford multiplication instead of writing which was used in the introduction in order to distinguish it from other Clifford multiplications.
In the following we have a spinor , i.e. a smooth section , a real-valued smooth function , a vector field and an endomorphism . Be aware that we simplify again the notation, by writing for the endomorphism which was called in the introduction. The equations (1)–(5) turn into
[TABLE]
We want to discuss the independence of the constraint equations (24) to (28). We start with some elementary lemmata.
Lemma 18**.**
If (27) is satisfied for , and defined in some . Then we have (in this ):
[TABLE]
Proof.
[TABLE]
∎
Lemma 19**.**
Let and let (27) be satisfied for , and . We assume that is defined by (1), i.e. (24) holds for instead of at the point . Then and are linearly dependent.
In that sense (27) implies (24) up to a constant. Obviously for globally defined , and , the proportionality factor does not have to be constant. We obtain for some nowhere vanishing function .
Proof.
W.l.o.g. , at . By Lemma 18 it follows that . We calculate for :
[TABLE]
Furthermore
[TABLE]
This implies . ∎
Lemma 20** (In [9, Lemma 5 in Sec. 5.2]).**
*Assume and satisfy (24). Then (25) is equivalent to . *
Proof.
We prove the statement in each , so we consider and . W.l.o.g. . If is an orthonormal basis of , then with is an orthonormal basis of We write
[TABLE]
for some and . Thus
[TABLE]
We conclude
[TABLE]
This implies that if and only if . ∎
Now let , not necessarily symmetric. Recall that our notation is slightly simplified if compared to the introduction: the of the introduction is in this appendix.
Proposition 21** (Dichotomy Proposition).**
Let be a connected Riemannian manifold and let be a field of endomorphisms. We assume that for satisfy (24), (26) and (27) for some .
Then . If , then is constant. If , then and vanish nowhere and .
Here denotes the endomorphism in adjoint to .
Let us compare this propositition to a similar statement by H. Baum and Th. Leistner. In the case that is symmetric, it yields a criterion implying (27).
Lemma 22** ([9, Lemma 5 in Sec. 5.2]).**
Let be a connected Riemannian manifold with a non-zero spinor field and a field of symmetric endomorphisms satisfying (26), and let be defined by (24). Then we have . Furthermore is non-negative and constant. Moreover, if we define as in the proof of Lemma 20, then . If , then (27) holds for .
Note that in the case of an imaginary Killing spinor, i.e. , then is related to the constant defined in [7] for any twistor spinor by . Note that imaginary Killing spinors are both twistor spinors and generalized imaginary Killing spinors, but there are generalized imaginary Killing spinors, which are not twistor spinors and vice versa. According to [7, Chap. 7] an imaginary Killing spinor is of type I, if and only if . Otherwise it is of type II. Any complete Riemannian manifold carrying a type II imaginary Killing spinor (with ) is homothetic to the hyperbolic space [7, Sec. 7.2]. If it is of type I, then it arise from a warped product construction as in our Section 5, see [7, Sec. 7.3].
Proof of Proposition 21.
First we compute
[TABLE]
With we obtain . Obviously this implies that is constant in the case .
We now consider the case . Note that Equation (26) is equivalent to saying that is a parallel section for the connection . This implies: If we have some with , then has to vanish on all of , and thus , the case already solved. So let us assume for all . Note that (27) implies
[TABLE]
We calculate
[TABLE]
i.e. at each point we have or . The sets and are closed and disjoint, thus the connectedness of implies that either or . In the case we obtain , and we are again back in the case already solved. So we conclude and thus . So everything is proven. ∎
Now we discuss our main case of interest, i.e. that is a generalized imaginary Killing spinor which is by definition a solution of with symmetric. We assume to be connected and which implies as we have seen that vanishes nowhere. According to Lemma 22 we obtain the equation and the fact that is a non-negative constant. In the case (denoted by “type I” in [9, Sec. 5.2]) we know further that (27) holds for .
Corollary 23**.**
Let be a connected Riemannian spin manifold. Let be a generalized imaginary Killing spinor, i.e. a solution of (26) for a field of symmetric endomorphisms . Let again be defined by (24). We assume , thus and hence . Then the following are equivalent:
- (a)
* is of type I,* 2. (b)
* satisfies ,* 3. (c)
* satisfies equation (2) (or equivalently (25)),* 4. (d)
Condition (27) holds for .
Proof.
(a) (b) holds by definition of “type I”.
(b) (c) is stated in Lemma 20.
(b) (d) is part of the statement of Lemma 22.
(d) (b) is part of the statement of Proposition 21. ∎
We have seen, in particular, that for a generalized imaginary Killing spinor equation (27) implies (25) for defined by (24), unless the vector field and the endomorphism vanish everywhere.
Appendix B More on Hypersurfaces
In this appendix we prove Lemma 4, i.e. formula (14).
It is known since long that one cannot restrict spinors to a hypersurface in a way preserving the connection. The difference of the connections depends on the second fundamental form or equivalently the Weingarten map. This effect is in some applications very helpful, e.g. in the case of surfaces in Euclidean space, where it leads to the spinorial version of the Weierstrass representation, see [17] for a good presentation or see [25] for an earlier, up to branching point aspects complete, but less conceptual publication, based on [24]. How to restrict spinors to hypersurfaces and the effect on the connection was already discussed in mathematical physics in the Riemannian [37, 38] and Lorentzian [40] context, and in spectral theory [5].
As different convention are used in the literature and as we follow, similar to [1, Prop. 5.3.1], another convention than the well-written exposition [6] we want to give a detailed proof of Lemma 4 in this appendix.
As in Subsection 2.3 and Appendix B we assume that is an -dimensional Riemannian spin manifold, , for a family of metrics , on . Let be the Levi-Civity connection of and the one of . We write for the unit normal vector field of in . For , and we have
[TABLE]
and we have, see e.g. [6, (4.1)] . Note that the second fundamental form has values in the normal bundle. Again, we use for the Clifford multipication on .
For concrete calculations we choose an open subset and for every we choose a positively oriented -orthonormal basis of , smoothly depending on and . Thus is a local section of . In other words: is a frame of the vertical bundle of . Furthermore , is a frame for , i.e. a local section of . We define the associated Christoffel symbols by
[TABLE]
Now let resp. be a spinorial lift of resp. , i.e. a local section of resp. , such that postcomposing resp. with resp. yields resp. . On we can write a spinor , i.e. a section of as , with . We also may view as as an associated bundle to , and with proper identifications we get . The connection defines the standard Levi-Civita connection on , again denoted by . On the other hand, defines a connection on .
Proposition 24**.**
For any and we have
[TABLE]
Proof.
For any we have
[TABLE]
Let denote the canonical basis of . Writing the connection in local coordinates we obtain for
[TABLE]
Obviously we have the following calculation in the Clifford algebra
[TABLE]
and thus we obtain for and the equation
[TABLE]
As the maps in Lemma 4 are constructed from an algebraic map using the associated bundle construction, they are -parallel, i.e.
[TABLE]
for all . Now Lemma 4 follows immediately by setting .
Appendix C Change of orientation
In this appendix we will prove the following proposition.
Proposition 25**.**
*Let be a Riemannian manifold with an orientation , . Let be a spin structure on with associated spinor bundle resp. .
Then there is a spin structure on with the following properties:
Case even: let be the associated spinor bundle, then there is a parallel isometric, complex linear bundle isomorphism , commuting with Clifford multiplication. This map maps to and to .
Case odd: let be one of the associated spinor bundles. Then there is a parallel isometric, complex linear bundle isomorphism , commuting with Clifford multiplication. The same statement holds if we exchange the role of and in the definitions of .*
We define a map by \rho\big{(}(e_{1},e_{2},\ldots,e_{m})\big{)}\mathrel{\raise 0.40903pt\hbox{\rm:}\mkern-5.2mu=}(-e_{1},e_{2},\ldots,e_{m}) for any -oriented orthonormal frame .
As a covering of smooth manifolds we define as the pullback of by the diffeomorphism . Let be the diffeomorphism defined by the following pull-back square:
P_{\mathop{\mathrm{Spin}}\nolimits}(M,g,-\mathcal{O})$$P_{\mathop{\mathrm{Spin}}\nolimits}(M,g,\mathcal{O})$$P_{\mathop{\mathrm{SO}}\nolimits}(M,g,-\mathcal{O})$$P_{\mathop{\mathrm{SO}}\nolimits}(M,g,\mathcal{O})$$\tilde{\rho}$$\rho
However in order to get an appropriate structure as -principal bundle on , some care is necessary, as is not -equivariant. If we define and abbreviate , then we have and thus .
Conjugation with is a Lie group automorphism of and lifts to , as conjugation with in the Clifford algebra sense. For any and we define
[TABLE]
This definition turns into a -principal bundle and the map is then -equivariant.
Let as before be an irreducible representation of the Clifford algebra, and let with the obvious modifications for .
Lemma 26** (Lift to the spinor bundle).**
The map
[TABLE]
is compatible with the equivalence relation given by . Thus it descends to a map
[TABLE]
Proof.
is mapped to
[TABLE]
This pair is equivalent to \bigl{(}\tilde{\rho}(\widetilde{\mathcal{E}}),\sigma(E_{1})\varphi\bigr{)} which is the image of \bigl{(}\widetilde{\mathcal{E}},\varphi\bigr{)}. ∎
Remark 27*.*
For future publications it might be helpful here to briefly discuss, what happens if apply this change of orientation twice. Obviously, by replacing by we get another map . It is easy to check that we then have .
In the following sections of an associated vector bundle — where is a principal -bundle and where is a -representation — are written as an equivalence class of the pair with respect to the action of . Here is a local section of and a locally defined function .
Lemma 28** (Compatibility with the Clifford action).**
[TABLE]
for , .
In particular, this lemma implies that although yields an isomorphism between spinor bundles for different orientations, it does not yet have the properties that we request for .
Proof.
We view as an associated bundle to where either sign yields a possible description. In these descriptions and represent the same vector. Thus
[TABLE]
Here we used that in . ∎
Lemma 29**.**
Let , . Then
[TABLE]
Proof.
The differential of maps to . The connection -form then pulls back according to
[TABLE]
for , a lift of under the projection . We lift this to a connection -form which thus transforms as
[TABLE]
where is a lift of . And this induces the relation (29). ∎
Note that obviously is isometric in each fiber.
Now finally in order to get a map as in the proposition, we will compose with a further bundle isomorphism. We define for any . Obviously, satisfies the Clifford relations, and thus describes a representation of which is due to its dimension irreducible. The classification of such representations implies that this representation is isomorphic to either or (possibly in the case odd) . If is even, then we obtain a complex vector space isomorphism satisfying
[TABLE]
for all and . We can choose to be isometric. Similarly, by checking the effect of Clifford multiplication by the volume element we obtain for odd isometric complex isomorphisms and satisfying (30) for and resp. . The associated map defined by defines parallel, fiberwise isometric complex linear isomorphisms of vector bundles over
[TABLE]
for even and
[TABLE]
for odd, satisfying (30) for and .
The composition now satisfies all properties requested in the proposition.
Remark 30*.*
Let be even. Recall that a spinor is called positive resp. negative if resp. . It is easy to check that and map positive spinors to negative ones and vice versa, while preserves positivity and negativity of spinors.
The proof of Proposition 25 is thus complete.
Appendix D Making paths of metrics divergence free
In this appendix we show the following well-known lemma.
Lemma 31**.**
Let , be a path of Riemannian metrics on a closed manifold . We assume that the dimension of the space of Killing vector fields of does not depend on . Then there exists a family of diffeomorphisms , depending smoothly on , , such that satisfies for all :
[TABLE]
Proof.
We make the following ansatz. Let be a vector field smoothly depending on the parameter . Let be the flow generated by , i.e.
[TABLE]
For this we define . Then
[TABLE]
where denotes the Lie derivative in the direction of . Thus (31) is equivalent to
[TABLE]
Now let be the adjoint of . Then, see [12, Lemma 1.60],
[TABLE]
for all and Riemannian metrics , where . We thus see that (31) is in fact equivalent to
[TABLE]
where we set . By calculation the principal symbol of one sees that is a self-adjoint elliptic operator, thus has discrete (non-negative) spectrum. We have . Thus again by [12, Lemma 1.60] the kernel of is the space of all Killing vector fields of . We furthermore have
[TABLE]
thus (32) has a unique solution that is -orthogonal to any Killing vector field. By assumption, the dimension of is constant. Thus, the spaces form a smooth family of isomorphic vector spaces and we have a smooth family of isomorphisms on . Thus, and hence also and depend smoothly on . This solves the problem. ∎
Note that we apply the above theorem to a family of Ricci-flat metrics. On closed Ricci-flat Riemannian manifolds every Killing vector field is parallel. Furthermore is then parallel if and only if is harmonic. Thus the dimension of the space of Killing vector fields is the first Betti-number and thus independent of .
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1[1] B. Ammann; A Variational Problem in Conformal Spin Geometry , Habilitationsschrift, Universität Hamburg, 2003; URL http://www.mathematik.uni-regensburg.de/ammann/preprints/habil/habil.ps .
- 2[2] B. Ammann, J. Glöckle; Dominant energy condition and spinors on Lorentzian manifolds (2021); preprint, ar Xiv:2103.11032 .
- 3[3] B. Ammann, K. Kröncke, H. Weiss, F. Witt; Holonomy rigidity for Ricci-flat metrics; Math. Z. 291 , 303–311 (2019); URL http://dx.doi.org/10.1007/s 00209-018-2084-3 . · doi ↗
- 4[4] B. Ammann, H. Weiss, F. Witt; A spinorial energy functional: critical points and gradient flow; Math. Ann. 365 , 1559–1602 (2016); URL http://dx.doi.org/10.1007/s 00208-015-1315-8 . · doi ↗
- 5[5] C. Bär; Extrinsic bounds for eigenvalues of the Dirac operator; Ann. Global Anal. Geom. 16 , 573–596 (1998).
- 6[6] C. Bär, P. Gauduchon, A. Moroianu; Generalized Cylinders in Semi-Riemannian and Spin Geometry; Math. Z. 249 , 545–580 (2005).
- 7[7] H. Baum, T. Friedrich, R. Grunewald, I. Kath; Twistors and Killing spinors on Riemannian manifolds ; Teubner-Texte zur Mathematik [Teubner Texts in Mathematics] , vol. 124, B. G. Teubner Verlagsgesellschaft mb H, Stuttgart 1991; with German, French and Russian summaries.
- 8[8] H. Baum, K. Lärz, T. Leistner; On the full holonomy group of Lorentzian manifolds; Math. Z. 277 , 797–828 (2014); URL http://dx.doi.org/10.1007/s 00209-014-1279-5 . · doi ↗
