nLab MFivebrane

Contents

Context

Higher spin geometry

spin geometry, string geometry, fivebrane geometry …

Ingredients

Spin geometry

Dynkin label	sp. orth. group	spin group	pin group	semi-spin group
	SO(2)	Spin(2)	Pin(2)
B1	SO(3)	Spin(3)	Pin(3)
D2	SO(4)	Spin(4)	Pin(4)
B2	SO(5)	Spin(5)	Pin(5)
D3	SO(6)	Spin(6)
B3	SO(7)	Spin(7)
D4	SO(8)	Spin(8)		SO(8)
B4	SO(9)	Spin(9)
D5	SO(10)	Spin(10)
B5	SO(11)	Spin(11)
D6	SO(12)	Spin(12)
	$\vdots$	$\vdots$
D8	SO(16)	Spin(16)		SemiSpin(16)
	$\vdots$	$\vdots$
D16	SO(32)	Spin(32)		SemiSpin(32)

String geometry

string geometry

Fivebrane geometry

Ninebrane geometry

ninebrane 10-group

Group Theory

Idea

A fivebrane spectrum is the Thom spectrum of the universal vector bundle over a fivebrane group. Their limit over the infinite fivebrane group is of particular interest since its generalized homology theory describes fivebrane bordisms.

Definition

Let $Fivebrane(n)\coloneqq O(n)\langle 8\rangle$ be the $7$ -connected cover in the Whitehead tower of the orthogonal group $O(n)$ . Through the canonical projection $p\colon Fivebrane(n)\twoheadrightarrow O(n)$ , there is a pullback:

\gamma_{Fivebrane}^n \coloneqq p^*\gamma_\mathbb{R}^n \twoheadrightarrow BFivebrane(n).

Its Thom spectrum is the Fivebrane spectrum:

MFivebrane(n) \coloneqq\mathbf{Th}\left(\gamma_{Fivebrane}^n\right) =\Sigma^{\infty-n}Th\left(\gamma_{Fivebrane}^n\right).

The desuspension assures the invariance under the Whitney sum with trivial bundles, so $MFivebrane(n)=\mathbf{Th}\left(\gamma_{Fivebrane}^n\oplus\underline{\mathbb{R}^m}\right)$ . It also assures that the canonical inclusion $i\colon Fivebrane(n)\rightarrow Fivebrane(n+1)$ , which pulls back to a canonical vector bundle homomorphism $\gamma_{Fivebrane}^n\oplus\underline{\mathbb{R}}=i^*\gamma_{Fivebrane}^{n+1}\rightarrow\gamma_{Fivebrane}^{n+1}$ , induces a spectrum homomorphism:

\begin{aligned} MFivebrane(n) &=\Sigma^{\infty-n}Th\left(\gamma_{Fivebrane}^n\right) \cong\Sigma^{\infty-(n+1)}Th\left(\gamma_{Fivebrane}^n\oplus\underline{\mathbb{R}}\right) \\ &\rightarrow\Sigma^{\infty-(n+1)}Th\left(\gamma_{Fivebrane}^{n+1}\right) =MFivebrane(n+1). \end{aligned}

Its limit is denoted:

MFivebrane \coloneqq\lim_{n\rightarrow\infty}MFivebrane(n).

Connections

From the canonical projections $Ninebrane(n)\twoheadrightarrow Fivebrane(n)\twoheadrightarrow String(n)$ and $Ninebrane\twoheadrightarrow Fivebrane\twoheadrightarrow String$ , there are canonical spectrum morphisms:

MNinebrane(n)\rightarrow MFivebrane(n)\rightarrow MString(n);

MNinebrane\rightarrow MFivebrane\rightarrow MString.

Fivebrane bordism homology theory

According to Thom's theorem, there is an isomorphism to fivebrane bordism groups:

\Omega_n^{Fivebrane} \cong\pi_n MFivebrane =\lim_{k\rightarrow\infty}\pi_k MFivebrane_{n+k}.

More general, MFivebrane defines a generalized homology theory (formally also denoted $\widetilde{MFivebrane}_*$ ) given by:

\Omega_n^Fivebrane(X) \coloneqq\pi_n^stab(X_+\wedge MFivebrane) \coloneqq\lim_{k\rightarrow\infty}\pi_{n+k}(X_+\wedge MFivebrane_k)

for all topological spaces $X$ with the disjoint union $X_+\coloneqq X+\{*\}$ . Since $\{*\}_+\cong S^0$ is the neutral element of the wedge product, one has $\Omega_n^Fivebrane=\Omega_n^Fivebrane(*)$ . Geometrically, $\Omega_n^Fivebrane(X)$ can also be described by $n$ -dimensional fivebrane manifolds representing cycles and $n+1$ -dimensional fivebrane bordisms representing homologous cycles, which are mapped continuous into $X$ . For a detailed explanation see fivebrane bordism.

A $n$ -dimensional fivebrane manifold $X$ has a fivebrane fundamental class $[X]\in\Omega_n^Fivebrane(X)$ . Let $i\colon X\hookrightarrow\mathbb{R}^{n+k}\hookrightarrow S^{n+k}$ be an embedding (which always exists due to the Whitney embedding theorem), then its Pontrjagin-Thom collapse map is:

S^{n+k}\rightarrow X_+\wedge Th(N_i X)

with the normal bundle $N_i X\coloneqq TS^{n+k}/i^*TX$ . Since the fivebrane structure of $X$ transfers over to its stable normal bundle? ( $N_i X$ for $k\rightarrow\infty$ ), postcomposition yields the map:

S^{n+k}\rightarrow X_+\wedge MFivebrane_k

representing the fivebrane fundamental class $[X]\in\Omega_n^Fivebrane(X)$ . Geometrically, it’s represented by the identity $id\colon X\rightarrow X$ .

Fivebrane cobordism cohomology theory

MFivebrane also defines a generalized cohomology theory given by:

\widetilde{MFivebrane}^n(X) \coloneqq\lim_{k\rightarrow\infty}[\Sigma^k X,MFivebrane_{n+k}]

for all topological spaces $X$ . It can also be described geometrically with fivebrane structures.

Related concepts

flavors of bordism homology theories/cobordism cohomology theories, their representing Thom spectra and cobordism rings:

bordism theory $\;$ M(B,f) (B-bordism):

MFr
MO, MSO, MSpin, MSpin^c, MSpin^h MString, MFivebrane, M2-Orient, M2-Spin, MNinebrane (see also pin⁻ bordism, pin⁺ bordism, pinᶜ bordism, spin bordism, spinᶜ bordism, spinʰ bordism, string bordism, fivebrane bordism, 2-oriented bordism, 2-spin bordism, ninebrane bordism)
MU, MSU, MΩΩSU(n)
MP, MR
MSp
MTO, MTSO
relative bordism theories: MOFr, MUFr, MSUFr
equivariant bordism theory: equivariant MFr, equivariant MO, equivariant MU
global equivariant bordism theory: global equivariant mO, global equivariant mU
algebraic: algebraic cobordism

Last revised on March 10, 2026 at 06:24:51. See the history of this page for a list of all contributions to it.