## Is there an algebraic description of Yang-Mills measure?

Consider $X=\operatorname{Hom}(\pi,SL(2,\mathbb C))/\!/SL(2,\mathbb C)$ and $Y=\operatorname{Hom}(\pi,SU(2))/\!/SU(2)$, where $\pi$ is a surface group. Note that if we use the right coordinates, then $Y$ is exactly the real valued points of $X$ (for the purposes of this question, though, this is irrelevant).

For those reading the comments below, I used to use $X_{\mathbb R}$ instead of $Y$.

Since $\pi$ is a surface group, the cup product (intersection pairing) gives rise to a symplectic form $\omega$ on $Y$ (which can also be naturally viewed as a holomorphic symplectic form on $X$). Now for $f\in\Gamma(X,\mathcal O_X)$, we have a natural linear map:

$$f\mapsto \int_{Y}f\cdot\wedge^{\operatorname{top}}\omega$$

(I believe it is more or less correct to call this the Yang-Mills measure, e.g. see this paper by Bullock, Frohman, and Kania-Bartoszynska)

Question: Is there a completely algebraic description of this integral? i.e. one that just works with input $\pi$ and the algebraic group $SL(2)$, and avoids the notion of real and complex points?

Note: there is certainly a simple algebraic description of $\omega$, so perhaps we just need to algebraically define the homology class of $Y$ in $X$ . . .

A paper of Witten's is perhaps related (and great to read even if it isn't).

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The way I've defined $X_{\mathbb R}$, I don't see how it can fail to be compact. Surely it forms a closed subset of $(SU(2)\times\cdots\times SU(2))//SU(2)$ (one copy of $SU(2)$ for each element of some finite set of generators of $\pi$). – unknown (google) Jul 3 2011 at 1:19
Also, in W. Goldman, "Topological components of spaces of representations" Invent. Math. 93, 557-607 (1988), Theorem A(ii) asserts that $X_{\mathbb R}$ is connected. – unknown (google) Jul 3 2011 at 1:30
Sorry, I thought you were talking about $SL_2\mathbb{R}$. What coordinates are you using so that the $SU(2)$ characters are the only real points? – Charlie Frohman Jul 3 2011 at 1:50
Consider the matrix $\left(\begin{smallmatrix}x+iy&z+iw\cr-z+iw&x-iy\end{smallmatrix}\right)$ subject to the condition $x^2+y^2+z^2+w^2=1$. If $x,y,z,w$ are real, then this is exactly an element of $SU(2)$. Letting them be complex, we clearly have an algebraic group of dimension $3$. I believe it is $SL(2,\mathbb C)$, though I'm short a reference at the moment . . . – unknown (google) Jul 3 2011 at 2:16
I think the characters of the $Sl_2\mathbb{R}$ representations will be real points of your character variety. The reason is they are conjugate to their complex conjugates. – Charlie Frohman Jul 3 2011 at 2:33

I am a little reticent to do this. This is just an outline that is based heavily on the BFK paper you cited in the question, and what seems to be your observation. Maybe I am just repeating back to you what you are thinking.

To start with $SL_2$ is the restricted dual of $U(sl_2)$ that is the linear functionals that factor through a finite dimensional representation. You can also think of $SL_2$ as the coordinate ring of $SL_2\mathbb{C}$. There is a linear functional $\mu:SL_2\rightarrow \mathbb{C}$ given by restricting the function to $SU(2)$ and integrating against Haar measure. Even though its analytic its really algebraic, as Weyl orthogonality gives a complete set of rules for evaluating it. $SL_2$ is a Hopf algebra, which you will need for the next construction.

Taking the tensor product of $\mu$ with itself $k$-times you get $\mu^{\otimes k}:SL_2^{\otimes k}\rightarrow \mathbb{C}$. There is an action of $U(sl_2)$ on $SL_2^{\otimes k}$ that is the analogy of the diagonal action by conjugacy of $SL_2\mathbb{C}$ on the coordinate ring of the cartesian product of $SL_2\mathbb{C}$ with itself $k$-times, $C[SL_2\mathbb{C}^k]=SL_2^{\otimes k}$, so that the ring of invariants can be identified with the characters of $SL_2\mathbb{C}$ representations of the free group on $k$ letters.

From the Bullock paper in Commentari, or if you wish the Przytycki-Sikora paper about the same time, you can identify this ring with Kauffman bracket skein algebra with $A=-1$ of a cylinder over any orientable surface $F$ whose fundamental group is the free group on $k$ letters. That means we can use the algebra of Jones-Wenzl idempotents to construct things.

Let $F$ be a closed oriented surface of genus $g$ and let $F'$ be the result of removing an open disk from $F$. Let $\sum_c (-1)^c(c+1)s_c(\partial F')$ be series coming from coloring $\partial F'$ with the $c$th Jones Wenzl idempotent. We can define a linear functional on the characters ring of $F'$ by letting $$YM(\alpha)=\lim_{N\rightarrow \infty} \mu^{\otimes 2g}(\sum_{c=0}^N\alpha(-1)^c(c+1)s_c(\partial F'))$$ The linear functional cannot see handleslides across the boundary of $F'$. That was how we defined the Yang-Mills measure in the paper.

Lets see if we can see it more algebraically.

Complete $SL_2^{\otimes 2g}$ so that

$$\zeta=\sum_{c=0}^{\infty}(-1)^c(c+1)s_c(\partial F')$$

is in the completion and annihilates handleslides.

Here is how to complete. The Yang-Mills measure defines a symmetric pairing

$$<\alpha,\beta>=YM(\alpha\beta)$$ We say a sequence $\alpha_n$ is Cauchy if for every character $\beta$, the sequence of complex numbers $<\alpha_n,\beta>$ is Cauchy. We complete by including the characters of the free group into the equivalence classes of Cauchy sequences. The completion is no longer an algebra, but it is a module over the the characters of the free group.

Notice for any character $\alpha$, the sequence of partial sums of $\alpha \zeta$ is Cauchy, and hence defines an element of the completion. The span of all $\alpha\zeta$, the cyclic module generated by $\zeta$ is isomorphic to the $SL_2\mathbb{C}$ characters of the fundamental group of $F$. Furthermore the restriction of the extension of the $\mu^{\otimes 2g}$ to that cyclic module is the Yang-Mills measure.

Finally, instead of using characters, you can use the Kauffman bracket skein algebras of cylinders over surfaces as long as $A$ doesn't lie on the unit circle, or it it does, it needs to be a $2p$th root of unity for some counting number $p$.

There are other ways of getting there. I always thought that the Yang-Mills measure had something to do with type $II_1$ factors, at least in the quantized case, but I could never get there. No doubt you need $A$ to be real, and then you need to do some some sort of transform as initially skeins act like unbounded operators.

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 More interesting to me, was what I thought you were asking to start with. There is another trace on the $SL_2\mathbb{C}$ characters of a surface group coming from the integral against the Weil-Peterson metric on the moduli space of curves. What does it look like? How does it compare to the Yang-Mills measure? – Charlie Frohman Jul 4 2011 at 12:01