string topology

While the singular cohomology of a space has always a product structure, this is not true for the singular homology of a space. Nevertheless, it is possible to construct such a structure for an oriented manifold $M$ of dimension $d$. This is the so-called intersection product. Intuitively, one can describe it as follows: given classes $x\backslash in\; H\_p(M)$ and $y\backslash in\; H\_q(M)$, take their product $x\backslash times\; y\; \backslash in\; H\_\{p+q\}(M\backslash times\; M)$ and make it transversal to the diagonal $M\backslash hookrightarrow\; M\backslash times\; M$. The intersection is then a class in $H\_\{p+q-d\}(M)$, the intersection product of $x$ and $y$. One way to make this construction rigorous is to use stratifolds.

Another case, where the homology of a space has a product, is the (based) loop space $\backslash Omega\; X$ of a space $X$. Here the space itself has a product

:$m\backslash colon\; \backslash Omega\; X\backslash times\; \backslash Omega\; X\; \backslash to\; \backslash Omega\; X$

by going first through the first loop and then through the second one. There is no analogous product structure for the free loop space $LX$ of all maps from $S^1$ to $X$ since the two loops need not have a common point. A substitute for the map $m$ is the map

:$\backslash gamma\backslash colon\; \{\backslash rm\; Map\}(S^1\; \backslash lor\; S^1,\; M)\backslash to\; LM$

where $\{\backslash rm\; Map\}(S^1\; \backslash lor\; S^1,\; M)$ is the subspace of $LM\backslash times\; LM$, where the value of the two loops coincides at 0 and $\backslash gamma$ is defined again by composing the loops.

The idea of the Chas–Sullivan product is to now combine the product structures above. Consider two classes $x\backslash in\; H\_p(LM)$ and $y\backslash in\; H\_q(LM)$. Their product $x\backslash times\; y$ lies in $H\_\{p+q\}(LM\backslash times\; LM)$. We need a map

:$i^!\backslash colon\; H\_\{p+q\}(LM\backslash times\; LM)\backslash to\; H\_\{p+q-d\}(\{\backslash rm\; Map\}(S^1\; \backslash lor\; S^1,M)).$

One way to construct this is to use stratifolds (or another geometric definition of homology) to do transversal intersection (after interpreting $\{\backslash rm\; Map\}(S^1\; \backslash lor\; S^1,\; M)\; \backslash subset\; LM\backslash times\; LM$ as an inclusion of Hilbert manifolds). Another approach starts with the collapse map from $LM\backslash times\; LM$ to the Thom space of the normal bundle of $\{\backslash rm\; Map\}(S^1\; \backslash lor\; S^1,\; M)$. 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 $\backslash gamma$ to get a class in $H\_\{p+q-d\}(LM)$, the Chas–Sullivan product of $x$ and $y$ (see e.g. {{harvtxt|Cohen|Jones|2002}}).

• 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 $H$ by another multiplicative homology theory $h$ if $M$ is oriented with respect to $h$.
• Furthermore, we can replace $LM$ by $L^n\; M\; =\; \{\backslash rm\; Map\}(S^n,\; M)$. By an easy variation of the above construction, we get that $\backslash mathcal\{\}h\_*(\{\backslash rm\; Map\}(N,M))$ is a module over $\backslash mathcal\{\}h\_*L^n\; M$ if $N$ is a manifold of dimensions $n$.
• The Serre spectral sequence is compatible with the above algebraic structures for both the fiber bundle $\{\backslash rm\; ev\}\backslash colon\; LM\backslash to\; M$ with fiber $\backslash Omega\; M$ and the fiber bundle $LE\backslash to\; LB$ for a fiber bundle $E\backslash to\; B$, which is important for computations (see {{harvtxt|Cohen|Jones|Yan|2004}} and {{harvtxt|Meier|2010}}).

There is an action $S^1\backslash times\; LM\; \backslash to\; LM$ by rotation, which induces a map

:$H\_*(S^1)\backslash otimes\; H\_*(LM)\; \backslash to\; H\_*(LM)$.

Plugging in the fundamental class $[S^1]\backslash in\; H\_1(S^1)$, gives an operator

:$\backslash Delta\backslash colon\; H\_*(LM)\backslash to\; H\_\{*+1\}(LM)$

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 $\backslash mathcal\{\}H\_*(LM)$. 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 $LM$.{{cite conference |url=https://bookstore.ams.org/pspum-73 |title= Notes on universal algebra |last1= Voronov |first1= Alexander |date= 2005 |publisher= Amer. Math. Soc. |book-title= Graphs and Patterns in Mathematics and Theoretical Physics (M. Lyubich and L. Takhtajan, eds.) |pages= 81–103|location= Providence, RI }} The cactus operad is weakly equivalent to the framed little disks operad{{cite book |last1= Cohen |first1= Ralph L. |last2= Hess |first2= Kathryn |last3= Voronov |first3= Alexander A. |date= 2006 |title= String topology and cyclic homology |url= http://www.springer.com/birkhauser/mathematics/book/978-3-7643-2182-6 |location= Basel |publisher= Birkhäuser |isbn= 978-3-7643-7388-7 |chapter= The cacti operad}} and its action on a topological space implies a Batalin-Vilkovisky structure on homology.{{cite journal |last1= Getzler |first1= Ezra |date= 1994 |title= Batalin-Vilkovisky algebras and two-dimensional topological field theories |url= https://projecteuclid.org/euclid.cmp/1104254599 |journal= Comm. Math. Phys. |volume= 159 |issue= 2 |pages= 265–285 |doi= 10.1007/BF02102639 |arxiv= hep-th/9212043|bibcode= 1994CMaPh.159..265G |s2cid= 14823949 }}

Image:Pair of pants cobordism (pantslike).svg

There are several attempts to construct (topological) field theories via string topology. The basic idea is to fix an oriented manifold $M$ and associate to every surface with $p$ incoming and $q$ outgoing boundary components (with $n\backslash geq\; 1$) an operation

:$H\_*(LM)^\{\backslash otimes\; p\}\; \backslash to\; H\_*(LM)^\{\backslash otimes\; q\}$

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 ({{harvtxt|Tamanoi|2010}}).

{{Reflist}}

• {{cite arXiv |last1=Chas |first1=Moira|last2=Sullivan|first2=Dennis|authorlink2= Dennis Sullivan|date=1999 |title=String Topology |eprint=math/9911159v1}}
• {{Cite journal|last1=Cohen|first1=Ralph L. | authorlink1=Ralph Louis Cohen|last2= Jones| first2=John D. S. |title=A homotopy theoretic realization of string topology|journal=Mathematische Annalen|volume= 324|pages=773–798|year=2002|issue=4 |mr=1942249|doi=10.1007/s00208-002-0362-0|arxiv=math/0107187|s2cid=16916132 }}
• {{cite book |first1=Ralph Louis |last1=Cohen |authorlink=Ralph Louis Cohen |first2=John D. S. |last2=Jones |first3=Jun |last3=Yan |chapter=The loop homology algebra of spheres and projective spaces |title=Categorical decomposition techniques in algebraic topology: International Conference in Algebraic Topology, Isle of Skye, Scotland, June 2001 |editor1-first=Gregory |editor1-last=Arone |editor2-first=John |editor2-last=Hubbuck |editor3-first=Ran |editor3-last=Levi |editor4-first=Michael |editor4-last=Weiss |editor4-link=Michael Weiss (mathematician) |publisher=Birkhäuser |pages=77–92 |year=2004}}
• {{Cite journal|last=Meier|first= Lennart| title=Spectral Sequences in String Topology|journal= Algebraic & Geometric Topology|volume= 11 | year=2011 | issue= 5|pages= 2829–2860|doi=10.2140/agt.2011.11.2829|mr=2846913|arxiv=1001.4906|s2cid= 58893087}}
• {{Cite journal|first=Hirotaka|last=Tamanoi|title=Loop coproducts in string topology and triviality of higher genus TQFT operations|journal= Journal of Pure and Applied Algebra|volume= 214|issue=5|pages=605–615|year=2010|mr=2577666 |doi=10.1016/j.jpaa.2009.07.011|arxiv=0706.1276|s2cid=2147096}}

Category:Geometric topology

Category:Algebraic topology

Category:String theory