As it is known that if 1 ≤ p < 2d/d+1, d ≥2, the Fourier transform of L^p($\mathbb{R^d}$) radial function is a continuous function away from origin. How do we prove that this range for p cannot be extended?
For $p>\frac{2d}{d+1}$, the function $f(x)=\x\^{d/2}J_{d/2}(\x\)$ is in $L^p(\mathbf R^d)$ by standard Bessel asymptotics, and its Fourier transform is the (obviously discontinuous) characteristic function of the unit ball.


$\begingroup$ @OwenKING Then this $f$ is barely not in $L^p$ ($\int_{\x\\leqslant r}f^p\simeq\log r$), so it's no longer a counterexample. $\endgroup$ Apr 14 '17 at 1:21