If $l \ne m$, then
$$
\int_{0}^{b}\!x{{\rm J}_{a}\left(lx\right)}{{\rm J}_{a}\left(mx\right)
}\,{\rm d}x={\frac {b \big( {{\rm J}_{a+1}\left(lb\right)}\;{{\rm J}_{a
}\left(mb\right)}\;l-{{\rm J}_{a+1}\left(mb\right)}\;{{\rm J}_{a}\left(lb
\right)}\;m \big) }{{l}^{2}-{m}^{2}}}
$$


Assume $l,m$ are zeros of $J_a$ and $b=1$.  Then we get the value $0$.