Increase in angular momentum through classical radiation?

My question can be asked in either Einstein GR or Maxwell electromagnetism. Suppose we have a system which is localized in space (enclosed in a sphere of finite radius). For example two point masses(charges) orbiting each other. The system starts to radiate due to the acceleration of masses(charges).

What I know:
For the energy, there are positivity theorems showing that the total energy of the system $cal{E}$ decreases in time, i.e. $d{cal E}/dtleq 0$. In electromagnetism, this can be proven easily
begin{align}
dfrac{dE_{rad}}{dt}=oint n_i T_{0i}=oint ncdot (Etimes B)
end{align}
Far from the source, we the wave becomes planar at each direction and we have $B=frac{1}{c} ntimes E$. Using this in prevous equation implies
begin{align}
dfrac{dE_{rad}}{dt}=oint (|vec{E}|^2-(ncdot vec{E})^2)geq0
end{align}
Since $E_{rad}+cal{E}$ is conserved, the latter should be decreasing. For Einstein GR, the same can be proved using the Bondi formalism and looking at the balance equation for energy.

My question: I intuitively expect that the magnitude of the angular momentum $|vec{J}|^2$of the system is also a decreasing function of time, i.e. $frac{d}{dt}|vec{J}|^2leq 0$. Is this true? If yes, what is the proof? If no, what is an example of such phenomenon? Intuitively, this is strange, because a system can spin up through radiation without any need for external torque.