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Ribbon categories are braided monoidal categories with a twist or balance, $\theta_B:B\to B$, which is a natural transformation from the identity functor to itself. In the string diagram calculus for ribbon categories, the ribbon is represented as a 360˚ twist in a ribbon (op. cit.). (See for example Street's Quantum Groups or Kassel's Quantum Groups for details.)

My questions are:

  • Is there work describing what happens if we consider a 180˚ twist?

  • If not, what goes wrong if we take this half twist one of the operations of interest on ribbons?

  • How are ribbons with a 180˚ twist axiomatised? What if loops are possible and we have twisted tangles? (I believe that Traced Monoidal Categories by Verity, Street and Joyal doesn't cover this case.)

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    $\begingroup$ For the case of quantum groups, see arxiv.org/abs/0810.0084 $\endgroup$
    – S. Carnahan
    Commented Jun 14, 2010 at 17:42
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    $\begingroup$ @Scott: I should (re)read Noah and Peter's paper. Do you know if anyone's worked out a "Tannaka Krein theorem" form half-twist ribbon categories? $\endgroup$ Commented Jun 14, 2010 at 22:39
  • $\begingroup$ @Theo: I have no idea. You should ask an expert (and/or peruse Google Scholar). $\endgroup$
    – S. Carnahan
    Commented Jun 15, 2010 at 1:03
  • $\begingroup$ If you take a strip of paper, put a half twist in it and glue the ends together you get a möbius band. Do the same thing with a full twist and you get an annulus. It probably means that there will be a forking in resolutions that will keep you from having truly local skein relations for invariants derived from such a theory. $\endgroup$ Commented Jun 15, 2010 at 2:29
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    $\begingroup$ As far as I know Peter and my paper is the only paper that really deals with any questions about half-ribbon categories. In particular, we only define half-ribbon Hopf algebras, not half-ribbon categories, so it's very unlikely that there's any Tannaka-Krein theorem in the literature. $\endgroup$ Commented Jun 15, 2010 at 3:41

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The completeness result, which I conjectured in "Autonomous categories in which A is isomorphic to A*" (as cited by Dave above), has been proven last month. I talked about this at QPL 2010 in May, but it is not yet written. It is actually relatively easy to prove, although it took me over a month to realize that this is so. Essentially it is a reduction to the known result for ribbon categories. The absence of Moebius strips is one of the things that makes this possible.

What must be shown is: given two terms (in the half-twist language) that have the same diagram, then the terms can be proved equal by the axioms.

In a nutshell: first, it suffices to show this for terms that use the half-twist map only at object generators (half twists on A tensor B, on I, and on A* can be immediately reduced using the axioms). Now given two terms t and s that have the same diagram, there are two possibilities:

(1) each ribbon in the diagram has an even number of half-twists on it. In this case, they can all be moved next to each other and replaced by full twists, using the axioms. Then one can simply use coherence for ribbon categories to show that s and t are provably equal.

(2) some ribbon in the diagram has an odd number of half-twists on it. Since there are no Moebius strips, this can only happen if the ribbon has two ends, each of which is either connected to a box or to a source/sink of the diagram. W.l.o.g. assume one side of the ribbon is connected to an output of the box f in the diagram. Using the above trick, we can use the axioms to replace all but one of the half-twists by full twists, and to move the remaining half-twist adjacent to the box f. The key point is that this happens in both terms s and t. In both s and t, now replace this particular occurrence of the half-twist by a new variable H:A->A*. Note that this is no longer a half-twist graphically, but simply a new box. Call the modified terms s' and t'. Since both s' and t' have the H in the same place, s' and t' still have isomorphic diagrams. But they have one less ribbon with an odd number of twists, so the result follows by induction.

This proof is annoyingly simple, but it's correct.

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  • $\begingroup$ If I understand correctly, the absence of Möbius strips follows from the fact that the objects corresponding to (using terminology above) the light and dark sides of the ribbon are different, so the light and dark strips cannot be plugged together. Do you have a reference for this result? $\endgroup$ Commented Jun 24, 2010 at 13:38
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    $\begingroup$ Much of this argument is written up in Section 4 of my paper with Noah (cited above). See especially Prop 4.15 which argues that there is a unique functor incorporating the half twist. This argument actually requires almost no assumptions on the half twist (only that it is invertible), but does not imply all the properties one would want (for instance, it does not imply all caps/cups are what you expect). These extra properties are checked later with additional assumptions on t. We work with the quantum group case, but I think the argument is unchanged for more general ribbon categories. $\endgroup$ Commented Jun 24, 2010 at 15:35
  • $\begingroup$ @dave: I don't have a reference; it seems to be just a consequence of soundness. By induction, the diagram corresponding to every term has the property that no "light" and "dark" sides are plugged together. @Peter: great, then I'll have another paper to cite! I agree that it is essentially a similar proof. The setting is slightly different, e.g. you don't identify the two duals of an object (the dual from the rigid structure and the light/dark dual). This actually simplifies the proof a bit. But yes, it's a very similar idea. $\endgroup$ Commented Jun 24, 2010 at 18:45
  • $\begingroup$ @Peter I'm actually very interested to see the case where the dark side functor is duality worked out in detail. Among the things that confuse me about that case is that, the way Noah and I set things up, the dark side functor and the duality functor don't actually commute, so cannot be equal. See our Comment 4.12. They do commmute up to isomorphism, and one can set things up so that they commute exactly. But then other things get worse. In particular, our proposition 4.18 becomes messy (i.e. the half-twist on a tensor product is hard to describe). Do you see such issues in your work? $\endgroup$ Commented Jun 25, 2010 at 15:19
  • $\begingroup$ @supercooldave, I'm quite certain that you're right in that observation. It seems that what you need for a Möbius strip is an additional, monoidal natural isomorphism between $A$ and $A^*$. I'm currently writing up my thesis in which I'll attempt to explain that. $\endgroup$ Commented Apr 7, 2016 at 9:14
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As Scott points out, Peter Tingley and I wrote a paper about this question. For the sake of concreteness (and because it included our main example) we only deal with the case of Hopf algebras whose representation theory has a ribbon half-twist, but the whole theory carries over to general monoidal categories. I'll sketch this generalization below, but you should probably read my paper with Peter first which is more accessible. The main result we use are formulas for the braiding given (independently) by Kirillov-Reshetikhin and Levendorskii-Soibleman which can be interpreted as given a formula for the half-twist. Certainly Reshetikhin (and presumably some of the other authors) were aware that these formulas could be interpreted in terms of half-twists, but it didn't explicitly appear until Peter and my paper.

One important warning that applies to everything though, in this theory the front and the back of the ribbon correspond to a priori different objects, so you still can't talk about Mobius bands.

Recall that a monoidal functor (these are often called "weak monoidal functors" in the quantum groups literature to distinguish them from strict monoidal functors, while they're called "strong monoidal functors" in the category theory literature to distinguish them from "lax monoidal functors) is a pair a functor F: C->D together with a binatural isomorphism $F(X\otimes Y) \rightarrow F(X) \otimes F(Y)$ which plays well with the associator.

Let's define a commutor to be a monoidal functor from C to C' (which will denote C with the opposite tensor product) whose underlying functor is the identity. The natural transformation is thus a map $X \otimes Y \rightarrow Y \otimes X$. The consistency condition says that there's a well-defined map $X \otimes Y \otimes Z \rightarrow Z \otimes Y \otimes X$. This definition of a commutor is the common generalization of braidings (which additionally satisfy the Yang-Baxter equation) and cactus commutors (which additionally square to 1). It's a natural condition that is satisfied by all known interesting "commutivity constraints."

There is a common way to produce commutors which comes up in a paper of Kamnitzer and Henriques (which is a very beautiful paper) which is closely related to half-twists.

First let's define a "dark side functor" to be any monoidal functor from C to C'. The name comes from the fact that this functor is what lets us talk about the "dark side" of the ribbon. If F is a dark side functor, then a half-twist for F is a natural transformation between F and the identity functor from C to C'.

Certainly you can use a half-twist for a dark side functor to produce a commutor, just compose the natural transformation with the dark side functor to get a commutor! If you work through what this tautological explanation means, you'll see that you get the commutor by first applying the half-twist to each object seperately, and then the inverse of the half-twist to the tensor product (or maybe visa-versa).

A ribbon half-twist is just a half-twist for a dark side functor whose resulting commutor is a braiding.

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  • $\begingroup$ @Noah. Thanks. I'll get to work on the two papers you recommend. $\endgroup$ Commented Jun 15, 2010 at 14:23
  • $\begingroup$ Noah, you went to the trouble of clarifying the terminology for "monoidal functor", but then you didn't specify that the transformation $F(X\otimes Y)\to F(X) \otimes F(Y)$ should be invertible! That's exactly what distinguishes strong monoidal from (co)lax monoidal in the category theory literature, at least. $\endgroup$ Commented Jul 10, 2011 at 7:14
  • $\begingroup$ Good point. Fixed. $\endgroup$ Commented Jul 10, 2011 at 15:15
  • $\begingroup$ Isn't your "dark side functor" actually a $\mathbb{Z}_2$ action, and representations of half-ribbon hopf algebras equivariant objects for that action? $\endgroup$ Commented May 5, 2016 at 17:24
  • $\begingroup$ @Turion: I don't think so... For one thing the functor is tensor reversing. For another thing the full twist isn't the identity. – Noah Snyder 40 mins ago delete $\endgroup$ Commented May 14, 2016 at 14:35
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I stumbled across Autonomous categories in which $A \cong A^∗$ by Peter Selinger. It states that the graphical representation of the self-duality $h_A:A\to A^*$ is represented by a half-twist of a ribbon. A coherence result is conjectured, but not proven (of course).

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    $\begingroup$ Thanks, I was not aware of this work. In Noah's language, perhaps the most obvious guess for a "dark side functor" would be duality. A half twist should then be a natural transformation from the identity functor $C \rightarrow C'$ and the duality functor, and it seems Selinger is exactly writing down the conditions to make this work. $\endgroup$ Commented Jun 23, 2010 at 19:30
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    $\begingroup$ I actually once started working out this story in the case of representations of quantum groups. There $V$ need not necessarily isomorphic to $V^*$, but one can define natural inner products on each irreducible $V_\lambda$. Equivalently, one has a chosen system of isomorphism of vector spaces $V_\lambda \rightarrow V_\lambda^*$ (at least up to scaling). These behave quite well with respect to the representation structure, but are not morphisms). I wanted to use this as the half-twist...but never worked out the details. I've very glad to see that other people are thinking these things through! $\endgroup$ Commented Jun 23, 2010 at 19:38
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I'm surprised nobody has mentioned Jeff Eggers "On involutive monoidal categories", which generalises Peter Selingers work, I guess. It's an excellent article, and it connects to other special cases.

The idea is as follows: A strict involutive monoidal category is a monoidal category $\mathcal{C}$ with a covariant (!) involution functor $\overline{(\;)} : \mathcal{C} \to \mathcal{C}$. It has to satisfy $\overline{\overline{X}} = X$ and $\overline{X \otimes Y} = \overline{Y} \otimes \overline{X}$. (Actually one may consider the non-strict version, but there is a coherence theorem.) These categories have just the right structure to define what an internal $*$-algebra is. Basically, an involution (such as the $*$-structure) of an object $X$ is a morphism $X \to \overline{X}$. For example, antilinear maps arise in that way. But note that $\overline{X}$ is usually not the dual of $X$, nor does it need to be isomorphic to $X$ or its dual. But Selinger's example is a special case of this framework, it seems, as are Dagger pivotal categories.

Now comes the (half-)twist. It is a natural transformation $\zeta: \overline{(\;)} \implies 1_\mathcal{C}$, satisfying some simple conditions. The punchline: Like Noah Snyder's and Peter Tingley's work would make you believe, such a half-twist will give rise to a ribbon category. The twist is given by $\zeta\overline{\zeta}$, the braiding is $(\zeta \otimes \zeta)\zeta^{-1}$. Egger also explains the graphical calculus, it all makes sense.

Involutive monoidal categories are, up to notation, the same as Majid's and Begg's Bar categories.

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