Strong monad

A (left) strong monad is a monad (T, η, μ) over a monoidal category (C, ⊗, I) together with a natural transformation t_A,B : A ⊗ TB → T(A ⊗ B), called (tensorial) left strength, such that the diagrams

 ,  ,

 , and  

commute for every object A, B and C.

For every strong monad T on a symmetric monoidal category, a right strength natural transformation can be defined by

$${\displaystyle t'_{A,B}=T(\gamma _{B,A})\circ t_{B,A}\circ \gamma _{TA,B}:TA\otimes B\to T(A\otimes B).}$$ 

A strong monad T is said to be commutative when the diagram

commutes for all objects ${\displaystyle A}$  and ${\displaystyle B}$ .

The Kleisli category of a commutative monad is symmetric monoidal in a canonical way, see corollary 7 in Guitart^[2] and corollary 4.3 in Power & Robison.^[3] When a monad is strong but not necessarily commutative, its Kleisli category is a premonoidal category.

One interesting fact about commutative strong monads is that they are "the same as" symmetric monoidal monads.^[4] More explicitly,

• a commutative strong monad ${\displaystyle (T,\eta ,\mu ,t)}$  defines a symmetric monoidal monad ${\displaystyle (T,\eta ,\mu ,m)}$  by$${\displaystyle m_{A,B}=\mu _{A\otimes B}\circ Tt'_{A,B}\circ t_{TA,B}:TA\otimes TB\to T(A\otimes B)}$$ 
• and conversely a symmetric monoidal monad ${\displaystyle (T,\eta ,\mu ,m)}$  defines a commutative strong monad ${\displaystyle (T,\eta ,\mu ,t)}$  by$${\displaystyle t_{A,B}=m_{A,B}\circ (\eta _{A}\otimes 1_{TB}):A\otimes TB\to T(A\otimes B)}$$ 

and the conversion between one and the other presentation is bijective.

• Strong monad at the nLab