String topology explained

String topology, a branch of mathematics, is the study of algebraic structures on the homology of free loop spaces. The field was started by .

Motivation

of dimension

. This is the so-called intersection product. Intuitively, one can describe it as follows: given classes

x\inH_p(M)

and

y\inH_q(M)

, take their product

x x y\inH_p+q(M x M)

and make it transversal to the diagonal

M\hookrightarrowM x M

. The intersection is then a class in

H_p+q-d(M)

, the intersection product of

and

. One way to make this construction rigorous is to use stratifolds.

\OmegaX

of a space

. Here the space itself has a product

m\colon\OmegaX x \OmegaX\to\OmegaX

by going first through the first loop and then through the second one. There is no analogous product structure for the free loop space

of all maps from

S¹

since the two loops need not have a common point. A substitute for the map

is the map

\gamma\colon{\rmMap}(S¹\lorS^1,M)\toLM

where

{\rmMap}(S¹\lorS^1,M)

is the subspace of

LM x LM

, where the value of the two loops coincides at 0 and

\gamma

is defined again by composing the loops.

The Chas–Sullivan product

The idea of the Chas–Sullivan product is to now combine the product structures above. Consider two classes

x\inH_p(LM)

and

y\inH_q(LM)

. Their product

x x y

lies in

H_p+q(LM x LM)

. We need a map

i^!\colonH_p+q(LM x LM)\toH_p+q-d({\rmMap}(S¹\lorS^1,M)).

One way to construct this is to use stratifolds (or another geometric definition of homology) to do transversal intersection (after interpreting

{\rmMap}(S¹\lorS^1,M)\subsetLM x LM

as an inclusion of Hilbert manifolds). Another approach starts with the collapse map from

LM x LM

to the Thom space of the normal bundle of

{\rmMap}(S¹\lorS^1,M)

. Composing the induced map in homology with the Thom isomorphism, we get the map we want.

Now we can compose

i^!

with the induced map of

\gamma

to get a class in

H_p+q-d(LM)

, the Chas–Sullivan product of

and

(see e.g.).

Remarks

As in the case of the intersection product, there are different sign conventions concerning the Chas–Sullivan product. In some convention, it is graded commutative, in some it is not.
The same construction works if we replace

by another multiplicative homology theory

is oriented with respect to

Furthermore, we can replace

LⁿM={\rmMap}(S^n,M)

. By an easy variation of the above construction, we get that

l{}h_*({\rmMap}(N,M))

is a module over

	n
l{}h
	*L

is a manifold of dimensions

{\rmev}\colonLM\toM

with fiber

\OmegaM

and the fiber bundle

LE\toLB

for a fiber bundle

E\toB

, which is important for computations (see and).

The Batalin–Vilkovisky structure

There is an action

S^{1 x}LM\toLM

by rotation, which induces a map

	1) ⊗
H
	*(S

H_*(LM)\toH_*(LM)

.Plugging in the fundamental class

[S^1]\in

	1)
H
	1(S

, gives an operator

\Delta\colonH_*(LM)\toH_*+1(LM)

of degree 1. One can show that this operator interacts nicely with the Chas–Sullivan product in the sense that they form together the structure of a Batalin–Vilkovisky algebra on

l{}H_*(LM)

. This operator tends to be difficult to compute in general. The defining identities of a Batalin-Vilkovisky algebra were checked in the original paper "by pictures." A less direct, but arguably more conceptual way to do that could be by using an action of a cactus operad on the free loop space

.^[1] The cactus operad is weakly equivalent to the framed little disks operad^[2] and its action on a topological space implies a Batalin-Vilkovisky structure on homology.^[3]

Field theories

There are several attempts to construct (topological) field theories via string topology. The basic idea is to fix an oriented manifold

and associate to every surface with

incoming and

outgoing boundary components (with

n\geq1

) an operation

	⊗ p
H
	*(LM)

\to

	⊗ q
H
	*(LM)

which fulfills the usual axioms for a topological field theory. The Chas–Sullivan product is associated to the pair of pants. It can be shown that these operations are 0 if the genus of the surface is greater than 0 .

References

Sources

Chas . Moira. Sullivan. Dennis. Dennis Sullivan. 1999 . String Topology . math/9911159v1.
Cohen. Ralph L. . Ralph Louis Cohen. Jones. John D. S. . A homotopy theoretic realization of string topology. Mathematische Annalen. 324. 773–798. 2002. 4 . 1942249. 10.1007/s00208-002-0362-0. math/0107187. 16916132 .
Book: Ralph Louis Cohen

. Ralph Louis . Cohen . Ralph Louis Cohen . John D. S. . Jones . Jun . Yan . The loop homology algebra of spheres and projective spaces . Categorical decomposition techniques in algebraic topology: International Conference in Algebraic Topology, Isle of Skye, Scotland, June 2001 . Gregory . Arone . John . Hubbuck . Ran . Levi . Michael . Weiss . Michael Weiss (mathematician) . . 77–92 . 2004.

Meier. Lennart. Spectral Sequences in String Topology. Algebraic & Geometric Topology. 11 . 2011 . 5. 2829–2860. 10.2140/agt.2011.11.2829. 2846913. 1001.4906. 58893087.
Hirotaka. Tamanoi. Loop coproducts in string topology and triviality of higher genus TQFT operations. Journal of Pure and Applied Algebra. 214. 5. 605–615. 2010. 2577666 . 10.1016/j.jpaa.2009.07.011. 0706.1276. 2147096.

Notes and References

Notes on universal algebra . Voronov . Alexander . 2005 . Amer. Math. Soc. . Graphs and Patterns in Mathematics and Theoretical Physics (M. Lyubich and L. Takhtajan, eds.) . 81–103. Providence, RI .
Book: Cohen . Ralph L. . Hess . Kathryn . Voronov . Alexander A. . 2006 . String topology and cyclic homology . Basel . Birkhäuser . 978-3-7643-7388-7 . The cacti operad.
Getzler . Ezra . 1994 . Batalin-Vilkovisky algebras and two-dimensional topological field theories . Comm. Math. Phys. . 159 . 2 . 265–285 . 10.1007/BF02102639 . hep-th/9212043. 1994CMaPh.159..265G . 14823949 .