What is the proof of the compatibility of a braiding with the unitors?

Question

I am specifically referencing the property that, given a braided monoidal category with a braiding $c$ and left and right unitors $\lambda, \rho$, $$ \lambda_A \circ c_{A,I}=\rho_{A}, $$ for any object $A$. This equation is stated in almost every reference (first done so by Joyal and Street) defining a braided category, yet an explicit or reproducible proof is, to my knowledge, not given anywhere. The closest thing to a proof I can find is a series of hints on Mathematics SE asked in 2014, however this answer (by Turion) has several inconsistencies/typos, making it hard to understand. Is there some reference where this proof is actually 'spelled out'? How can one prove this relation given the braided monoidal category axioms?

Answer 1

Using the notation of Joyal and Street §2, here’s a proof of $\newcommand{\r}{\rho}\newcommand{\l}{\lambda}\newcommand{\x}{\otimes}\newcommand{\comp}{\!\!\cdot\!}\r_A = \l_A \comp c_{A,I}$. Since $\l$ and $c$ are invertible, it suffices to prove $\r_A \comp (\l_A \comp c_{A,I} \x I) = \l_A \comp c_{A,I} \comp(\l_A \comp c_{A,I} \x I)$. Notation: I will write composition as $\comp$, and it binds tighter than $\x$; and will write all associators just as $\alpha$, to reduce clutter. I’ll black-box details of steps that are purely about symm. mon. cats., not involving the braiding — these are most easily seen using coherence for SMC’s.

$$\begin{align} \r_A \comp (\l_A \comp c_{A,I} \x I) &= (\l_A \comp c_{A,I}) \comp \r_{A \x I} & \text{naturality of $\r$} \\ &= \l_A \comp c_{A,I} \comp (A \x \r_I) \comp \alpha & \text{SMC facts}\\ &= \l_A \comp (\r_I \x A) \comp c_{A,I \x I} \comp \alpha & \text{naturality of $c$}\\ &= \l_A \comp (\r_I \x A) \comp \alpha \comp (I \x c_{A,I}) \comp \alpha \comp (c_{A,I} \x I) & \text{axiom (B1)} \\ &= \l_A \comp (I \x \l_A) \comp (I \x c_{A,I}) \comp \alpha \comp (c_{A,I} \x I) & \text{SMC facts}\\ &= \l_A \comp (I \x \l_A \comp c_{A,I}) \comp \alpha \comp (c_{A,I} \x I) & \text{functoriality of $\x$}\\ &= (\l_A \comp c_{A,I}) \comp \l_{A \x I} \comp \alpha \comp (c_{A,I} \x I) & \text{naturality of $\l$}\\ &= (\lambda_A \comp c_{A,I}) \comp (\lambda_A \x I) \comp (c_{A,I} \x I) & \text{SMC facts}\\ &= (\lambda_A \comp c_{A,I}) \comp (\lambda_A \comp c_{A,I} \x I) & \text{functoriality of $\x$} \end{align} $$

I found this proof using string diagrams, writing down (B1) for $A,I,I$ (as Joyal and Street suggest), and then contemplating how to connect that to the desired equation.

Answer 2

A completely spelled out diagrammatic proof is given in Proposition 1.3.21 of Volume II of Bimonoidal Categories, $E_n$-Monoidal Categories, and Algebraic K-Theory by Niles Johnson and Donald Yau.

Answer 3

Here is a proof in string diagrams inspired by the proof in Johnson and Yau linked to in Emily's answer.

Read this diagram bottom to top; solid line represents A and dashed lines represent I. Coherence for the underlying monoidal category is assumed. The steps are labeled by 'inv' for invertibility of the braiding, 'nat' for naturality of the braiding, and a hexagon symbol for a hexagon identity.

Update - there is an error in the first diagram, the dashed line should start in a bold dot to represent the unitor - sorry.