Is there a set of matrices that satisfy all of the following constraints?
1) $A^2=0, B^2=0, C^2=0...$ where $A,B,C,D..$ are different matrices.
2) All of them commute.
Edit: 3) $AB \neq 0, AC \neq 0, BC \neq 0, ...$.
Is there a set of matrices that satisfy all of the following constraints?
1) $A^2=0, B^2=0, C^2=0...$ where $A,B,C,D..$ are different matrices.
2) All of them commute.
Edit: 3) $AB \neq 0, AC \neq 0, BC \neq 0, ...$.
Let $E=\left(\begin{array}{cc} 0 & 1\\ 0 & 0 \end{array}\right), \ \ \ \ I=\left(\begin{array}{cc} 1 & 0\\ 0 & 1 \end{array}\right).$
Then set
$ A = E\otimes I\otimes I\otimes I,\\ B = I\otimes E\otimes I\otimes I,\\ C = I\otimes I\otimes E\otimes I,\\ D = I\otimes I\otimes I\otimes E. $
Where $\otimes$ is the Kronecker product. These were constructed following the procedure outline by @HenningMakholm here:
More generally if only you have an $A$ and $B$ with $A^2=B^2$, $AB=BA=0$, you can combine $n$ copies of this structure using Kronecker products. That automatically makes matrices from different pairs commute, and ensures that cross-level products are nonzero as long as the generators are.