nLab double field theory

Skip the Navigation Links | Home Page | All Pages | Latest Revisions | Discuss this page |
Contents

Context

String theory

Ingredients

Critical string models

Extended objects

Topological strings

Backgrounds

Phenomenology

Duality

Contents

Idea

The term double field theory has come to be used for field theory (prequantum field theory/quantum field theory) on spacetimes which are T-folds (doubled geometries) hence for “T-duality-equivariant field theory”.

Proposal of formalization in para-Hermitian geometry

The most popular proposal of formalization of double field theory is in the context of para-Hermitian geometry.

Doubled space as para-Hermitian manifold

The use of para-hermitian geometry in Double Field Theory was introduced by Izu Vaisman in (Vai 12), then by David Svoboda (Svo 18).

Definition

An almost para-complex manifold is a manifold MM equipped with a vector bundle endomorphism FEnd(TM)F\in\mathrm{End}(T M) such that F 2=1F^2=1 and its ±1\pm 1 eigenbundles T ±MT^\pm M have same rank.

Definition

The para-complex projectors are the canonical projectors onto T ±MT^\pm M defined by P ±=12(1±F)P_\pm = \frac{1}{2}(1\pm F)

Definition

A ±\pm-para-complex manifold is an almost para-complex manifold (M,F)(M,F) such that T ±MT^\pm M of FF is Frobenius integrable as a distribution. A para-complex manifold is a manifold that is both ++-para-complex and --para-complex.

Remark

A doubled manifold MM equipped with the O(d,d)O(d,d)-structure η\eta carries a natural almost para-hermitian structure. On patches UU with coordinates (x μ,x˜ μ)(x^\mu,\tilde{x}_\mu) we have the canonical para-complex structure

Fx μ=x μ,Fx˜ μ=x˜ μF\frac{\partial}{\partial x^\mu} = \frac{\partial}{\partial x^\mu},\,\, F\frac{\partial}{\partial \tilde{x}_\mu} = - \frac{\partial}{\partial \tilde{x}_\mu}

with eigenbundles

  • T +U=x μT^+U=\big\langle\frac{\partial}{\partial x^\mu}\big\rangle,

  • T U=x˜ μT^-U=\big\langle\frac{\partial}{\partial \tilde{x}_\mu}\big\rangle,

with associated foliations

  • +={x μ=const}\mathcal{F}_+=\{x^\mu = \mathrm{const}\},

  • ={x˜ μ=const}\mathcal{F}_-=\{\tilde{x}_\mu = \mathrm{const}\}.

In analogy with complex geometry, if we define Ω r,s(M)\Omega^{r,s}(M) as the space of sections of Λ r(T +M)Λ s(T M)\Lambda^r(T^+M)\wedge\Lambda^s(T^-M), we have the decomposition

Ω k(M)= k=r+sΩ r,s(M) \Omega^k(M)=\bigoplus_{k=r+s}\Omega^{r,s}(M)

Let us call π r,s:Ω r+s(M)Ω r,s(M)\pi^{r,s}:\Omega^{r+s}(M)\rightarrow\Omega^{r,s}(M) the canonical projector induced by P ±P_\pm.

In analogy with complex geometry, there are para-Dolbeault operators:

  • d +=π r+1,sd:Ω r,s(M)Ω r+1,s(M)\mathrm{d}^+=\pi^{r+1,s}\circ\mathrm{d} : \Omega^{r,s}(M)\longrightarrow \Omega^{r+1,s}(M),

  • d =π r,s+1d:Ω r,s(M)Ω r,s+1(M)\mathrm{d}^-=\pi^{r,s+1}\circ\mathrm{d} : \Omega^{r,s}(M)\longrightarrow \Omega^{r,s+1}(M).

with properties:

  • d=d ++d \mathrm{d} = \mathrm{d}^+ + \mathrm{d}^-,

  • (d ±) 2=0(\mathrm{d}^\pm)^2= 0,

  • d +d +d d +=0\mathrm{d}^+\mathrm{d}^-+\mathrm{d}^-\mathrm{d}^+ =0.

We can also define Lie derivatives on the eigenbundles T ±MT^\pm M by

X ± ±ξ=(d ±ι X ±+ι X ±d ±)ξ \mathcal{L}^\pm_{X_\pm}\xi = (\mathrm{d}^\pm\iota_{X_\pm} + \iota_{X_\pm}\mathrm{d}^\pm)\xi

for any vector X ±Γ(T ±M)X_\pm\in\Gamma(T^\pm M) and ξΩ r,s(M)\xi\in\Omega^{r,s}(M).

Definition

An almost para-hermitian manifold is an almost para-complex manifold MM equipped with a compatible metric, i.e a symmetric tensor ηSym 2(TM)\eta\in\mathrm{Sym}^2(T M) such that η(F,F)=η(,)\eta(F\cdot\,,F\cdot\,)=-\eta(\,\cdot\,,\,\cdot\,).

Remark

The contraction with the metric η\eta defines two isomorphisms

ϕ ±:T ±M(T M) * \phi^\pm : T^\pm M \rightarrow (T^\mp M)^\ast

by

  • ϕ ±(X ±)=X ± \phi^\pm(X_\pm) = X_\pm^\flat and

  • (ϕ ±) 1(ξ ±)=ξ (\phi^\pm)^{-1}(\xi_\pm)=\xi^\sharp

that map a vector in T ±MT^\pm M to a 11-form in (T M) *(T^\mp M)^\ast and vice-versa. We used the notation ,\flat,\sharp for the musical isomorphisms induced by the metric η\eta between TMT M and T *MT^\ast M.

This can be used to define a new couple of isomorphisms

Φ ±:TMT ±M(T ±M) * \Phi^\pm : T M \longrightarrow T^\pm M\oplus(T^\pm M)^\ast

that maps a vector a vector X=X ++X X=X_++X_- with X ±T ±MX_\pm\in T^\pm M into X ++X X_+ + X_-^\flat.

Definition

A para-hermitian manifold is an almost para-hermitian manifold (M,η,F)(M,\eta,F) such that (M,F)(M,F) is a para-complex manifold.

Foliated Courant algebroid and spacetime

Given a ++-para-hermitian manifold (M,η,F)(M,\eta,F), consider the triple (T +M,[,] +,1 T +M)\big(T^+ M,[\,\cdot\,,\,\cdot\,]_+,1_{T^+M}\big) where

  • the skew-symmetric bracket [,] +:=[,]| T +M[\,\cdot\,,\,\cdot\,]_+:=[\,\cdot\,,\,\cdot\,]|_{T^+ M}

  • the anchor 1 T ±M:=1 TM| T ±M1_{T^\pm M}:=1_{T M}|_{T^\pm M} are the restrictions of Lie bracket and identity of TMT M.

Since MM is ++-para-hermitian we have that T +MT^+M is integrable and therefore it is the tangent bundle T +M=T ±T^+M = T\mathcal{F}_\pm of a foliation +\mathcal{F}_+. This means that this triple is just the tangent Lie algebroid of the foliation +\mathcal{F}_+:

(T +M,[,] +,1 T +M)=(T +,[,] T +,1 T +). \big(T^+ M,[\,\cdot\,,\,\cdot\,]_+,1_{T^+ M}\big) = \big(T\mathcal{F}_+,[\,\cdot\,,\,\cdot\,]_{T\mathcal{F}_+},1_{T\mathcal{F}_+}\big).

There is a natural Courant algebroid structure on the bundle T +M(T +M) *T^+ M\oplus(T^+ M)^\ast with skew-symmetric pairing

[X+α,Y+β] +=[X,Y] ++ X +β Y +α+d +(ι Yα) [X+\alpha,Y+\beta]_{+} = [X,Y]_+ + \mathcal{L}_X^+\beta -\mathcal{L}_Y^+\alpha +\mathrm{d}_+(\iota_Y\alpha)

and symmetric pairing

X+α,Y+β +=ι Xβ+ι Yα. \langle X+\alpha,Y+\beta\rangle_+ = \iota_X\beta + \iota_Y\alpha.

The isomorphism Φ +:T +M(T +M) *T +MT M=TM\Phi^+:T^+ M\oplus (T^+ M)^\ast\rightarrow T^+ M\oplus T^- M = T M previously defined induces a Courant algebroid isomorphism and hence a Courant algebroid structure on TMT M. This induces a metric η\eta on MM and a skew-symmetric pairing on TMT M by

[[X ++X ,Y ++Y ]] +:=[X +,Y +]+[ X + +Y Y + +X +d +(η(X ,Y +))] , [[X_++X_-,Y_++Y_-]]_+ := [X_+,Y_+] + \Big[\mathcal{L}_{X_+}^+ Y_-^\flat -\mathcal{L}_{Y_+}^+ X_-^\flat +\mathrm{d}_+\big(\eta(X_-,Y_+)\big)\Big]^\sharp,

where XTMX\in T M is split in X ±=P ±XX_\pm=P_\pm X.

Remark

Since MM is assumed ++-para-hermitian, T +M(T +M) *T^+ M\oplus (T^+ M)^\ast can be written as T +T * +T\mathcal{F}_+\oplus T^\ast\mathcal{F}_+. Therefore we constructed an isomorphism between the Courant algebroid on the whole TMT M and the generalized tangent bundle T +T * +T\mathcal{F}_+\oplus T^\ast\mathcal{F}_+ of the foliation. In other terms para-hermitian geometry of the doubled manifold MM reduces to Generalized Geometry of physical spacetime.

Remark

The same argument can be clearly applied to T MT^-M too.

C-bracket

In previous section we assumed that the +1+1-eigenbundle T +MT^+M is integrable. This is equivalent to assuming that there exists a well defined foliation that can be interpreted as the physical spacetime. However it is possible to construct a more general bracket that does not require such an assumption, but only an almost para-complex structure. Therefore it works even when a global physical spacetime foliation is not defined. This is achieved by Vaisman with the definition of C-bracket by using a generalization of the notion of Levi-Civita connection (look (Vai 2012)).

In the special case of an (integrable) para-hermitian manifold C-bracket is given by

[[X+α,Y+β]] C=[X,Y]+ Xβ Yα+d(η(X+α,Y+β))+[α,β] *+ α *Y β *Xd *(η(X+α,Y+β)) [[ X+\alpha,Y+\beta ]]_{\mathrm{C}} = [X,Y] + \mathcal{L}_X\beta -\mathcal{L}_Y\alpha + \mathrm{d}\big(\eta(X+\alpha,Y+\beta)\big) + [\alpha,\beta]^\ast + \mathcal{L}^\ast_\alpha Y -\mathcal{L}^\ast_\beta X - \mathrm{d}^\ast\big(\eta(X+\alpha,Y+\beta)\big)

where [,][\,\cdot\,,\,\cdot\,], X\mathcal{L}_X and d\mathrm{d} are usual Lie bracket, Lie derivative and differential on T +T\mathcal{F}_+. On the other hand [,] *[\,\cdot\,,\,\cdot\,]^\ast, α *\mathcal{L}^\ast_\alpha and d *\mathrm{d}^\ast are Lie bracket, Lie derivative and differential on T + *T\mathcal{F}_+^\ast induced by the former ones.

Analogy with geometric quantization

The analogy between geometric quantization and DFT was firstly noticed by David Berman.

Given a symplectic manifold (M,ω)(M,\omega) there exist couples of lagrangian foliations +, \mathcal{F}_+,\mathcal{F}_- of MM defined by

X,YT ±,ω(X,Y)=0. \forall X,Y\in T\mathcal{F}_\pm, \: \omega(X,Y)=0.

For example for a symplectic space ( 2d,ω=dx μdp μ)(\mathbb{R}^{2d},\omega=\mathrm{d}x^\mu\wedge\mathrm{d}p_\mu) we can have +={x μ=const}\mathcal{F}_+ = \{x^\mu = \mathrm{const} \} and ={p μ=const}\mathcal{F}_-= \{p_\mu = \mathrm{const} \}. But notice that any symplectic rotation of this choice is a couple of lagrangian foliations that works fine.

Heuristically, in geometrical quantization we make a choice of a couple of lagrangian foliations ±\mathcal{F}_\pm to “select” a physical spacetime +\mathcal{F}_+ from the whole symplectic-covariant theory on MM.

Similarly in DFT, when MM is an (integrable) para-hermitian manifold we make a choice of a couple of lagrangian foliations ±\mathcal{F}_\pm to “select” a physical spacetime +\mathcal{F}_+ from the whole T-duality-covariant theory on MM.

Relation between para-Hermitian geometry and gerbes

Let us start from a bundle gerbe π:PM\pi:P\rightarrow M on a dd-dimensional smooth manifold MM. This is locally isomorphic to P| UU×BU(1)P|_U \cong U\times \mathbf{B}U(1), where BU(1)\mathbf{B}U(1) is the circle 2-group and UU is an open set. If we consider an atlas dU\mathbb{R}^d\rightarrow U, we immediately have an atlas d×BU(1)U×BU(1)\mathbb{R}^d\times \mathbf{B}U(1)\rightarrow U\times \mathbf{B}U(1) which extends the former. In other words the bundle gerbe is locally modelled on the Lie 2-group d×BU(1)\mathbb{R}^d\times \mathbf{B}U(1).

The Lie 2-algebra of d×BU(1)\mathbb{R}^d\times \mathbf{B}U(1) is db𝔲(1)\mathbb{R}^d \oplus \mathbf{b}\mathfrak{u}(1). An atlas for this Lie 2-algebra will be just an ordinary Lie algebra 𝔞\mathfrak{a} and a homomorphism of Lie n-algebras

f:𝔞 db𝔲(1) f: \mathfrak{a} \longrightarrow \mathbb{R}^d \oplus \mathbf{b}\mathfrak{u}(1)

which is surjective in the lowest degree. What choice of 𝔞\mathfrak{a} can we make?

To find a working atlas we can consider the dual homomorphism of Chevalley-Eilenberg algebras, i.e. the injective homomorphism

f *:CE( db𝔲(1))CE(𝔞). f^\ast: \mathrm{CE}(\mathbb{R}^d \oplus \mathbf{b}\mathfrak{u}(1)) \longrightarrow \mathrm{CE}(\mathfrak{a}).

The dg-algebra CE( db𝔲(1))\mathrm{CE}(\mathbb{R}^d \oplus \mathbf{b}\mathfrak{u}(1)) has a degree 22 generator bb which is annihilated by the differential, i.e. db=0\mathrm{d} b=0. Therefore its image ω:=f *b\omega := f^\ast b in 𝔞\mathfrak{a} is a of degree 22 element which satisfies the equation

dω=0. \mathrm{d} \omega = 0 .

Since d\mathbb{R}^d must be a subalgebra of 𝔞\mathfrak{a} and ω\omega must be rotation-invariant, we have no other choice than 𝔞= d( d) *\mathfrak{a}=\mathbb{R}^d \oplus (\mathbb{R}^d)^\ast and

ω=dx˜ μdx μ. \omega = \mathrm{d}\tilde{x}_\mu \wedge \mathrm{d}x^\mu.

where dx˜ μ\mathrm{d}\tilde{x}_\mu and dx μ\mathrm{d}x^\mu are respectively generators of CE(( d) *)\mathrm{CE}((\mathbb{R}^d)^\ast) and CE( d)\mathrm{CE}(\mathbb{R}^d).

The vector space d( d) *\mathbb{R}^d \oplus (\mathbb{R}^d)^\ast equipped with ω=dx˜ μdx μΩ LI 1( d( d) *)\omega = \mathrm{d}\tilde{x}_\mu \wedge \mathrm{d}x^\mu \in \Omega_{\mathrm{LI}}^1(\mathbb{R}^d \oplus (\mathbb{R}^d)^\ast) is nothing but the local space on which para-Hermitian geometry is modelled. On the other side of the atlas map f:𝔞 db𝔲(1)f: \mathfrak{a} \longrightarrow \mathbb{R}^d \oplus \mathbf{b}\mathfrak{u}(1) we have an extended Minkowski spacetime, on which bundle gerbes are modelled.

This relation is introduced in (Alf20).

Relation with non-geometry

Double field theory is supposed to formalize the non-geometric backgrounds of type II string theory.

Examples

References

General

Original articles:

The idea of “doubled spacetime geometry” is a variant of the idea of T-folds, due to

The terminology “section condition” in double field hteory originates with the following article (which is more generally concerned with a kind of exceptional field theory):

  • David S. Berman, Malcolm J. Perry: Generalized Geometry and M theory, J. High Energ. Phys. 2011 74 (2011) [arXiv:1008.1763v4, doi:10.1007/JHEP06(2011)074]

    [p 3:] “One half of the [doubled] space is the usual geometry and the other is its T-dual. Of course one also must define a section on the doubled space to relate it to a particular duality frame in order to retrieve some kind of conventional spacetime picture.”

    [p. 4:] “a kind of section condition describing how one takes a section through the extended space that results in our usual spacetime view. […] there are many possible ways of taking a section through the doubled space and these are of course related by T-duality transformations. The absence of a globally defined section is also possible and it is this possibility that gives rise to so called nongeometric backgrounds such as T-folds where local geometric patches are related by transition function given by T-duality transformations. ”

The coinage of the term “double field theory” for field theory on such doubled geometry goes back to

Review:

Formalization in para-Hermitian geometry

Discussion about para-Hermitian formalism started in

  • Izu Vaisman, On the geometry of double field theory Journal of Mathematical Physics 53, 033509 (2012) (arXiv:1203.0836)

Para-Hermitian formalism further developed and generalized in

  • David Svoboda, Algebroid structures on para-Hermitian manifolds Journal of Mathematical Physics 59, 122302 (2018) (arxiv:1802.08180)

Formalization in higher geometry

Discussion of double field theory using higher differential geometry:

Discussion in the context of L-infinity algebra includes

Discussion of an extended version of Riemannian geometry suitable for the description of double field theory

Comprehensive discussion in higher differential geometry:

Last revised on November 9, 2024 at 11:24:09. See the history of this page for a list of all contributions to it.

EditDiscussPrevious revisionChanges from previous revisionHistory (34 revisions) Cite Print Source