Regarding Dirac equation heuristic formulation

Question

So in the Wikipedia Page of Dirac equation we are presented with this equation
$$nabla^2 - frac{1}{c^2}frac{partial^2}{partial t^2} = left(A partial_x + B partial_y + C partial_z + frac{i}{c}D partial_tright)left(A partial_x + B partial_y + C partial_z + frac{i}{c}D partial_tright).$$
My question is: Is the multiplication of two first-order equal to second-order as presented above?

ohneVal · Accepted Answer

When in doubt always use a test function to find out what differential operators might do, as an example (assuming $A,B,C$ and $D$ do not depend on position and do not commute):
$$begin{align}
left(Apartial_x + Bright)left(Cpartial_x + Dright)f(x) &= left(Apartial_x + Bright)left(Cpartial_x f(x) +D f(x)right) 
&= Apartial_x left(Cpartial_x f(x) +D f(x)right) + B left(Cpartial_x f(x) +D f(x)right)
&= A Cpartial_x partial_x f(x) + A Dpartial_x f(x) + B Cpartial_x f(x) + BDf(x)
&= A Cpartial^2_x f(x) + A Dpartial_x f(x) + B Cpartial_x f(x) + BDf(x)
end{align}$$
as you can see operating with a differential operator of order 1 on another differential operator of order 1 produces a differential operator of order 2. Perhaps the notation is what is misleading to you:
$$partial_x^2 = left(frac{partial}{partial x}right)^2 = frac{partial}{partial x}frac{partial}{partial x}$$
is a second order derivative, while
$$left(frac{partial f}{partial x}right)^2 = (partial_x f) (partial_x f)$$
is a square of a first derivative.

Regarding Dirac equation heuristic formulation

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