English

Uniform subellipticity

Analysis of PDEs 2014-01-03 v1

Abstract

We establish two global subellipticity properties of positive symmetric second-order partial differential operators on L2(\Rid)L_2(\Ri^d). First, if m\Nim \in \Ni then we consider operators H0H_0 with coefficients in Wm+1,(\Rid)W^{m+1,\infty}(\Ri^d) and domain D(H0)=W,2(\Rid)D(H_0)=W^{\infty,2}(\Ri^d) satisfying the subellipticity property c(ϕ,(I+H0)ϕ)Δγ/2ϕ22 c (\phi, (I+H_0)\phi)\geq \|\Delta^{\gamma/2} \phi\|_2^2 for some c>0c>0 and γ<0,1]\gamma\in<0,1], uniformly for all ϕW,2(\Rid)\phi\in W^{\infty,2}(\Ri^d), where Δ\Delta denotes the usual Laplacian. Then we prove that D(Hα)D(Δαγ)D(H^\alpha) \subseteq D(\Delta^{\alpha \gamma}) for all α[0,21(m+1+γ1)>\alpha \in [0,2^{-1} (m + 1 + \gamma^{-1})>. Hence there is a c>0c>0 such that the norm estimate c(I+H)αϕ2Δαγϕ2 c \|(I+H)^\alpha \phi\|_2\geq \|\Delta^{\alpha \gamma} \phi\|_2 is valid for all ϕD(Hα)\phi\in D(H^\alpha) where HH denotes the self-adjoint closure of H0H_0. In particular, if the coefficients of H0H_0 are in Cb(\Rid)C_b^\infty(\Ri^d) then the conclusion is valid for all α0\alpha\geq0. Secondly, we prove that if H0=i=1NXiXi, H_0=\sum^N_{i=1}X_i^* X_i, where the XiX_i are vector fields on \Rid\Ri^d with coefficients in Cb(\Rid)C_b^\infty(\Ri^d) satisfying a uniform version of H\"ormander's criterion for hypoellipticity, then H0H_0 satisfies the subellipticity condition for γ=r1\gamma=r^{-1} where rr is the rank of the set of vector fields. Consequently D(Hn)D(Δn/r)D(H^n) \subseteq D(\Delta^{n/r}) for all n\Nin \in \Ni, where HH is the closure of H0H_0.

Keywords

Cite

@article{arxiv.math/0612680,
  title  = {Uniform subellipticity},
  author = {A. F. M. ter Elst and Derek W. Robinson},
  journal= {arXiv preprint arXiv:math/0612680},
  year   = {2014}
}

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24 pages