Difference between revisions of "Connes-Moscovici index theorem"
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+ | ''Gamma index theorem, $\Gamma$ index theorem'' | ||
− | + | A theorem [[#References|[a3]]] which computes the pairing of a cyclic cocycle $\varphi$ of the [[Group algebra|group algebra]] $\mathbf{C} [ \Gamma ]$ with the algebraic [[K-theory|$K$-theory]] index of an invariant (pseudo-) differential operator on a covering $\tilde { M } \rightarrow M$ with [[Galois group|Galois group]] (or group of deck transformations) $\Gamma$ (cf. also [[Cohomology|Cohomology]]). | |
− | + | The ingredients of this theorem are stated in more detail below. Let $M$ be a smooth compact [[Manifold|manifold]]. | |
− | + | First, any $\Gamma$-invariant, elliptic partial differential operator (cf. [[Elliptic partial differential equation|Elliptic partial differential equation]]) $D$ on $\tilde { M }$ has an algebraic $K$-theory index $\operatorname {ind} ( D )$. The definition of $\operatorname {ind} ( D )$ is obtained using the boundary mapping on $K _ { 1 }$ applied to $\sigma ( D )$, the principal symbol of $D$ (cf. also [[Symbol of an operator|Symbol of an operator]]). This gives | |
− | + | \begin{equation*} \operatorname {ind}( D ) \in K _ { 0 } ^ { \text{alg} } ( \mathcal{C} _ { 1 } \bigotimes \mathbf{C} [ \Gamma ] ), \end{equation*} | |
− | + | where $C _ { 1 }$ is the algebra of trace-class operators on $L ^ { 2 } ( M )$ (cf. also [[Trace|Trace]]). More generally, one can assume that $D$ is an invariant [[Pseudo-differential operator|pseudo-differential operator]] on $\tilde { M }$ (with nice support). | |
− | + | Secondly, it is known [[#References|[a2]]] that any group-cohomology $q$-cocycle $\varphi : \Gamma ^ { q + 1 } \rightarrow \mathbf{C}$ of $\Gamma$ can be represented by an anti-symmetric function, and hence it defines a cyclic cocycle on the group algebra $\mathbf{C} [ \Gamma ]$ of the group $\Gamma$. Moreover, the class of this cocycle in the periodic cyclic cohomology group $\operatorname{HP} ^ { q } ( \mathbf{C} [ \Gamma ] )$, also denoted by $\varphi$, depends only on the class of $\varphi$ in $H ^ { q } ( B \Gamma , \mathbf{C} ) \simeq H ^ { q } ( \Gamma , \mathbf{C} )$. Here, as customary, $B \Gamma$ denotes the [[Classifying space|classifying space]] of $\Gamma$, whose simplicial cohomology is known to be isomorphic to $H ^ { q } ( \Gamma , \mathbf{C} )$, the group cohomology of $\Gamma$. | |
− | + | Finally, any element $\varphi \in \operatorname{HP} ^ { 0 } ( A )$ gives rise to a group morphism $\varphi_{ * } : K _ { 0 } ^ { \text{alg} } ( A ) \rightarrow \mathbf{C}$, see [[#References|[a2]]]. In particular, any group cocycle $\varphi \in H ^ { 2 m } ( \Gamma , {\bf C} )$ gives rise to a mapping | |
− | + | \begin{equation*} \varphi_{ *} : K _ { 0 } ^ { \text{alg} } ( \mathcal{C} _ { 1 } \bigotimes \mathbf{C} [ \Gamma ] ) \rightarrow \mathbf{C}, \end{equation*} | |
− | + | using also the trace on $\mathcal{C} _ { 1 }$. | |
− | is a pairing of a compactly supported cohomology class with the fundamental class of | + | The Connes–Moscovici index theorem now states [[#References|[a3]]]): Let $f : M \rightarrow B \Gamma$ be the mapping classifying the covering $\tilde { M }$, let $\mathcal{T} ( M )$ be the Todd class of $M$, and let $\operatorname {Ch} ( D ) \in H _ { c } ^ { * } ( T M )$ be the [[Chern character|Chern character]] of the element in $K ( T M )$ defined by $\sigma ( D )$, as in the Atiyah–Singer index theorem (see [[#References|[a1]]] and [[Index formulas|Index formulas]]). Then |
+ | |||
+ | \begin{equation*} \phi_{ *} ( \operatorname { ind } ( D ) ) = c _ { q } \left( \operatorname { Ch } ( D ) \mathcal{T} ( M ) f ^ { * } ( \phi ) \right) [ T M ] \end{equation*} | ||
+ | |||
+ | is a pairing of a compactly supported cohomology class with the fundamental class of $T M$. Here, $c _ { q } = ( - 1 ) ^ { q } q ! / ( 2 q ) !$. | ||
The Connes–Moscovici index theorem is sometimes called the higher index theorem for coverings and is the prototype of a higher index theorem. | The Connes–Moscovici index theorem is sometimes called the higher index theorem for coverings and is the prototype of a higher index theorem. | ||
====References==== | ====References==== | ||
− | <table>< | + | <table><tr><td valign="top">[a1]</td> <td valign="top"> M.F. Atiyah, I.M. Singer, "The index of elliptic operators I" ''Ann. of Math.'' , '''93''' (1971) pp. 484–530</td></tr><tr><td valign="top">[a2]</td> <td valign="top"> A. Connes, "Non-commutative differential geometry" ''Publ. Math. IHES'' , '''62''' (1985) pp. 41–144</td></tr><tr><td valign="top">[a3]</td> <td valign="top"> A. Connes, H. Moscovici, "Cyclic cohomology, the Novikov conjecture and hyperbolic groups" ''Topology'' , '''29''' (1990) pp. 345–388</td></tr><tr><td valign="top">[a4]</td> <td valign="top"> G. Lusztig, "Novikov's higher signature and families of elliptic operators" ''J. Diff. Geom.'' , '''7''' (1972) pp. 229–256</td></tr></table> |
Latest revision as of 17:02, 1 July 2020
Gamma index theorem, $\Gamma$ index theorem
A theorem [a3] which computes the pairing of a cyclic cocycle $\varphi$ of the group algebra $\mathbf{C} [ \Gamma ]$ with the algebraic $K$-theory index of an invariant (pseudo-) differential operator on a covering $\tilde { M } \rightarrow M$ with Galois group (or group of deck transformations) $\Gamma$ (cf. also Cohomology).
The ingredients of this theorem are stated in more detail below. Let $M$ be a smooth compact manifold.
First, any $\Gamma$-invariant, elliptic partial differential operator (cf. Elliptic partial differential equation) $D$ on $\tilde { M }$ has an algebraic $K$-theory index $\operatorname {ind} ( D )$. The definition of $\operatorname {ind} ( D )$ is obtained using the boundary mapping on $K _ { 1 }$ applied to $\sigma ( D )$, the principal symbol of $D$ (cf. also Symbol of an operator). This gives
\begin{equation*} \operatorname {ind}( D ) \in K _ { 0 } ^ { \text{alg} } ( \mathcal{C} _ { 1 } \bigotimes \mathbf{C} [ \Gamma ] ), \end{equation*}
where $C _ { 1 }$ is the algebra of trace-class operators on $L ^ { 2 } ( M )$ (cf. also Trace). More generally, one can assume that $D$ is an invariant pseudo-differential operator on $\tilde { M }$ (with nice support).
Secondly, it is known [a2] that any group-cohomology $q$-cocycle $\varphi : \Gamma ^ { q + 1 } \rightarrow \mathbf{C}$ of $\Gamma$ can be represented by an anti-symmetric function, and hence it defines a cyclic cocycle on the group algebra $\mathbf{C} [ \Gamma ]$ of the group $\Gamma$. Moreover, the class of this cocycle in the periodic cyclic cohomology group $\operatorname{HP} ^ { q } ( \mathbf{C} [ \Gamma ] )$, also denoted by $\varphi$, depends only on the class of $\varphi$ in $H ^ { q } ( B \Gamma , \mathbf{C} ) \simeq H ^ { q } ( \Gamma , \mathbf{C} )$. Here, as customary, $B \Gamma$ denotes the classifying space of $\Gamma$, whose simplicial cohomology is known to be isomorphic to $H ^ { q } ( \Gamma , \mathbf{C} )$, the group cohomology of $\Gamma$.
Finally, any element $\varphi \in \operatorname{HP} ^ { 0 } ( A )$ gives rise to a group morphism $\varphi_{ * } : K _ { 0 } ^ { \text{alg} } ( A ) \rightarrow \mathbf{C}$, see [a2]. In particular, any group cocycle $\varphi \in H ^ { 2 m } ( \Gamma , {\bf C} )$ gives rise to a mapping
\begin{equation*} \varphi_{ *} : K _ { 0 } ^ { \text{alg} } ( \mathcal{C} _ { 1 } \bigotimes \mathbf{C} [ \Gamma ] ) \rightarrow \mathbf{C}, \end{equation*}
using also the trace on $\mathcal{C} _ { 1 }$.
The Connes–Moscovici index theorem now states [a3]): Let $f : M \rightarrow B \Gamma$ be the mapping classifying the covering $\tilde { M }$, let $\mathcal{T} ( M )$ be the Todd class of $M$, and let $\operatorname {Ch} ( D ) \in H _ { c } ^ { * } ( T M )$ be the Chern character of the element in $K ( T M )$ defined by $\sigma ( D )$, as in the Atiyah–Singer index theorem (see [a1] and Index formulas). Then
\begin{equation*} \phi_{ *} ( \operatorname { ind } ( D ) ) = c _ { q } \left( \operatorname { Ch } ( D ) \mathcal{T} ( M ) f ^ { * } ( \phi ) \right) [ T M ] \end{equation*}
is a pairing of a compactly supported cohomology class with the fundamental class of $T M$. Here, $c _ { q } = ( - 1 ) ^ { q } q ! / ( 2 q ) !$.
The Connes–Moscovici index theorem is sometimes called the higher index theorem for coverings and is the prototype of a higher index theorem.
References
[a1] | M.F. Atiyah, I.M. Singer, "The index of elliptic operators I" Ann. of Math. , 93 (1971) pp. 484–530 |
[a2] | A. Connes, "Non-commutative differential geometry" Publ. Math. IHES , 62 (1985) pp. 41–144 |
[a3] | A. Connes, H. Moscovici, "Cyclic cohomology, the Novikov conjecture and hyperbolic groups" Topology , 29 (1990) pp. 345–388 |
[a4] | G. Lusztig, "Novikov's higher signature and families of elliptic operators" J. Diff. Geom. , 7 (1972) pp. 229–256 |
Connes-Moscovici index theorem. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Connes-Moscovici_index_theorem&oldid=13937