On the dimension-free control of higher order truncated Riesz transforms by higher order Riesz transforms

Abstract

Fix a positive integer k. Let Rk be a higher order Riesz transform of order k on Rd and let Rkt, t>0, be the corresponding truncated Riesz transform. We study the relation between \|Rk f\|Lp(Rd) and \|Rkt f\|Lp(Rd) for p=1, p=∞, and p=2. We do this by analyzing the factorization operator Mkt defined by the relation Rkt=Mkt Rk. The operator Mkt is a convolution operator associated with an L1 radial kernel bk,dt(x)=t-dbk,d(x/t), where bk,d(x):=bk,d1(x). We prove that bk,d 0 only for k=1,2. We also show that for fixed k 3, \[ d ∞\|bk,d\|L1(Rd)=∞. \] This contrasts with the cases k=1,2, where it is known that \|bk,d\|L1(Rd)=1. Finally, we show that for any positive integer k, the Fourier transform of bk,d is bounded in absolute value by 1. This implies the contractive estimate \[ \|Rkt f\|L2(Rd) \|Rk f\|L2(Rd) \] and an analogous estimate for general singular integrals with smooth kernels for radial input functions f.