825 \label{zzz3}

   825 \label{zzz3}

   826 \end{figure}

   826 \end{figure}

   827 

   827 

   828 First, we can compose two module morphisms to get another module morphism.

   828 First, we can compose two module morphisms to get another module morphism.

   829 

   829 

   831 {Let $M = M_1 \cup_Y M_2$, where $M$, $M_1$ and $M_2$ are marked $k$-balls ($0\le k\le n$)

   831 {Let $M = M_1 \cup_Y M_2$, where $M$, $M_1$ and $M_2$ are marked $k$-balls ($0\le k\le n$)

   832 and $Y = M_1\cap M_2$ is a marked $k{-}1$-ball.

   832 and $Y = M_1\cap M_2$ is a marked $k{-}1$-ball.

   833 Let $E = \bd Y$, which is a marked $k{-}2$-hemisphere.

   833 Let $E = \bd Y$, which is a marked $k{-}2$-hemisphere.

   834 Note that each of $M$, $M_1$ and $M_2$ has its boundary split into two marked $k{-}1$-balls by $E$.

   834 Note that each of $M$, $M_1$ and $M_2$ has its boundary split into two marked $k{-}1$-balls by $E$.

   835 We have restriction (domain or range) maps $\cM(M_i)_E \to \cM(Y)$.

   835 We have restriction (domain or range) maps $\cM(M_i)_E \to \cM(Y)$.

   847 

   847 

   848 Second, we can compose an $n$-category morphism with a module morphism to get another

   848 Second, we can compose an $n$-category morphism with a module morphism to get another

   849 module morphism.

   849 module morphism.

   850 We'll call this the action map to distinguish it from the other kind of composition.

   850 We'll call this the action map to distinguish it from the other kind of composition.

   851 

   851 

   853 {Let $M = X \cup_Y M'$, where $M$ and $M'$ are marked $k$-balls ($0\le k\le n$),

   853 {Let $M = X \cup_Y M'$, where $M$ and $M'$ are marked $k$-balls ($0\le k\le n$),

   854 $X$ is a plain $k$-ball,

   854 $X$ is a plain $k$-ball,

   855 and $Y = X\cap M'$ is a $k{-}1$-ball.

   855 and $Y = X\cap M'$ is a $k{-}1$-ball.

   856 Let $E = \bd Y$, which is a $k{-}2$-sphere.

   856 Let $E = \bd Y$, which is a $k{-}2$-sphere.

   857 We have restriction maps $\cM(M')_E \to \cC(Y)$ and $\cC(X)_E\to \cC(Y)$.

   857 We have restriction maps $\cM(M')_E \to \cC(Y)$ and $\cC(X)_E\to \cC(Y)$.

   863 which is natural with respect to the actions of homeomorphisms, and also compatible with restrictions

   863 which is natural with respect to the actions of homeomorphisms, and also compatible with restrictions

   864 to the intersection of the boundaries of $X$ and $M'$.

   864 to the intersection of the boundaries of $X$ and $M'$.

   865 If $k < n$ we require that $\gl_Y$ is injective.

   865 If $k < n$ we require that $\gl_Y$ is injective.

   866 (For $k=n$, see below.)}

   866 (For $k=n$, see below.)}

   867 

   867 

   869 {The composition and action maps above are strictly associative.}

   869 {The composition and action maps above are strictly associative.}

   870 

   870 

   871 Note that the above associativity axiom applies to mixtures of module composition,

   871 Note that the above associativity axiom applies to mixtures of module composition,

   872 action maps and $n$-category composition.

   872 action maps and $n$-category composition.

   873 See Figure \ref{zzz1b}.

   873 See Figure \ref{zzz1b}.

   901 and these various multifold composition maps satisfy an

   901 and these various multifold composition maps satisfy an

   902 operad-type strict associativity condition.}

   902 operad-type strict associativity condition.}

   903 

   903 

   904 (The above operad-like structure is analogous to the swiss cheese operad

   904 (The above operad-like structure is analogous to the swiss cheese operad

   905 \cite{MR1718089}.)

   905 \cite{MR1718089}.)

   909 {Let $M$ be a marked $k$-ball and $D$ be a plain $m$-ball, with $k+m \le n$.

   909 {Let $M$ be a marked $k$-ball and $D$ be a plain $m$-ball, with $k+m \le n$.

   910 Then we have a map $\cM(M)\to \cM(M\times D)$, usually denoted $a\mapsto a\times D$ for $a\in \cM(M)$.

   910 Then we have a map $\cM(M)\to \cM(M\times D)$, usually denoted $a\mapsto a\times D$ for $a\in \cM(M)$.

   911 If $f:M\to M'$ and $\tilde{f}:M\times D \to M'\times D'$ are maps such that the diagram

   911 If $f:M\to M'$ and $\tilde{f}:M\times D \to M'\times D'$ are maps such that the diagram

   912 \[ \xymatrix{

   912 \[ \xymatrix{

   913 	M\times D \ar[r]^{\tilde{f}} \ar[d]_{\pi} & M'\times D' \ar[d]^{\pi} \\

   913 	M\times D \ar[r]^{\tilde{f}} \ar[d]_{\pi} & M'\times D' \ar[d]^{\pi} \\

   915 } \]

   915 } \]

   916 commutes, then we have $\tilde{f}(a\times D) = f(a)\times D'$.}

   916 commutes, then we have $\tilde{f}(a\times D) = f(a)\times D'$.}

   917 

   917 

   918 \nn{Need to add compatibility with various things, as in the n-cat version of this axiom above.}

   918 \nn{Need to add compatibility with various things, as in the n-cat version of this axiom above.}

   919 

   919 

   921 

   921 

   922 There are two alternatives for the next axiom, according whether we are defining

   922 There are two alternatives for the next axiom, according whether we are defining

   923 modules for plain $n$-categories or $A_\infty$ $n$-categories.

   923 modules for plain $n$-categories or $A_\infty$ $n$-categories.

   924 In the plain case we require

   924 In the plain case we require

   925 

   925 

   927 {Let $M$ be a marked $n$-ball and $f: M\to M$ be a homeomorphism which restricts

   927 {Let $M$ be a marked $n$-ball and $f: M\to M$ be a homeomorphism which restricts

   928 to the identity on $\bd M$ and is extended isotopic (rel boundary) to the identity.

   928 to the identity on $\bd M$ and is extended isotopic (rel boundary) to the identity.

   929 Then $f$ acts trivially on $\cM(M)$.}

   929 Then $f$ acts trivially on $\cM(M)$.}

   930 

   930 

   931 \nn{need to rephrase this, since extended isotopies don't correspond to homeomorphisms.}

   931 \nn{need to rephrase this, since extended isotopies don't correspond to homeomorphisms.}

   934 In other words, if $M = (B, N)$ then we require only that isotopies are fixed 

   934 In other words, if $M = (B, N)$ then we require only that isotopies are fixed 

   935 on $\bd B \setmin N$.

   935 on $\bd B \setmin N$.

   936 

   936 

   937 For $A_\infty$ modules we require

   937 For $A_\infty$ modules we require

   938 

   938 

   940 {For each marked $n$-ball $M$ and each $c\in \cM(\bd M)$ we have a map of chain complexes

   940 {For each marked $n$-ball $M$ and each $c\in \cM(\bd M)$ we have a map of chain complexes

   941 \[

   941 \[

   942 	C_*(\Homeo_\bd(M))\ot \cM(M; c) \to \cM(M; c) .

   942 	C_*(\Homeo_\bd(M))\ot \cM(M; c) \to \cM(M; c) .

   943 \]

   943 \]

   944 Here $C_*$ means singular chains and $\Homeo_\bd(M)$ is the space of homeomorphisms of $M$

   944 Here $C_*$ means singular chains and $\Homeo_\bd(M)$ is the space of homeomorphisms of $M$

   954 Note that the above axioms imply that an $n$-category module has the structure

   954 Note that the above axioms imply that an $n$-category module has the structure

   955 of an $n{-}1$-category.

   955 of an $n{-}1$-category.

   956 More specifically, let $J$ be a marked 1-ball, and define $\cE(X)\deq \cM(X\times J)$,

   956 More specifically, let $J$ be a marked 1-ball, and define $\cE(X)\deq \cM(X\times J)$,

   957 where $X$ is a $k$-ball or $k{-}1$-sphere and in the product $X\times J$ we pinch 

   957 where $X$ is a $k$-ball or $k{-}1$-sphere and in the product $X\times J$ we pinch 

   958 above the non-marked boundary component of $J$.

   958 above the non-marked boundary component of $J$.

   960 Then $\cE$ has the structure of an $n{-}1$-category.

   962 Then $\cE$ has the structure of an $n{-}1$-category.

   961 

   963 

   962 All marked $k$-balls are homeomorphic, unless $k = 1$ and our manifolds

   964 All marked $k$-balls are homeomorphic, unless $k = 1$ and our manifolds

   963 are oriented or Spin (but not unoriented or $\text{Pin}_\pm$).

   965 are oriented or Spin (but not unoriented or $\text{Pin}_\pm$).

   964 In this case ($k=1$ and oriented or Spin), there are two types

   966 In this case ($k=1$ and oriented or Spin), there are two types