• h{ \g\' — d'(g\ e) where e denotes the identity of G and the local dimension D', that is, the integer for which the left Haar measure \B'(g; r)\ of the ball B'(g; r) = [h e G : d'{g\ h) < r) satisfies bounds c~xrD' < \B'(e; r)\ < crD' for some c > 0 and all small r. If the algebraic basis a , , . . . , ad> is completed to a vector space basis ax,... , ad of g then
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A. F. M. ter Elst and Derek W. Robinson
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the associated distance and modulus are denoted by d{-\ •) and | • |, respectively, and the corresponding balls by B(g; r). Note that D' = d if a\,... , ad is a vector space basis. In general we omit the prime in the notation for quantities with respect to a vector space basis au ... ,ad. For v e (0, 1) define the (subelliptic) Holder space Cv '(G) of continuous functions over G for which sup (\g\Tv\\U
IIHIIc. 0 with \k\' + \l\' < Ktx'2 + 2\gh l\'
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REMARK 1.2. Since the operators have complex coefficients there is 9C > 0 such that e' 0 H is also subelliptic for cp e {—9C,9C)- The estimates of Theorem 1.1 are then valid for e'^H instead of H. Moreover, for all 9 G (0, 9C) the constants in the kernel estimates are uniform for
0 there exist a, b > 0 and co > 0 such that
and \(A"B/iKl)(k-ig;
r'h) - (AaBeK,)(g; h)\ 1-1
uniformly for all a e Jn+\(d), fi e Jn_i(d), t > 0, g, h e G andk,l e G such that \k\ + \l\ [0, oo] by
'=
SU
P
(\g\Tv\\Ai/2(I-L(g))cp\U.
Then introduce the corresponding Banach spaces L^ = [cp e L Uoc : IMIro < °°} and Cl' = W € C(G) : |||^|||c.- < oo}. One has the following continuity properties of multiplication operators. LEMMA 2.1. Letv e (0,1). I. If. 2.3. Letv e (0,1). # > € (0, v) and p e (1, oo) tfzen ^
PROPOSITION
I.
0 such that
uniformly for all (p e L'py and i/r e C ' f l L^. II.
For all n e N, y e (0, v) a n d p £ ( l , oo} fftere gxwrt a c > 0 5«cn
Uf\\'p.,n+y < C ( SUp IHA^IIIc.. + \a€y,,(d')
uniformly for all
r(v~r)/2\\ 0, depending only on G and the basis at,... , a^. that
f
-
(Ak 0, uniformly for all 0 < r < c~lR and R < Ro. One can now extend the estimates to the range 0 < r < R < 1 by the argument at the end of the proof of [E1R6, Proposition 3.4].
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2.2.2. Subelliptic operators on stratified groups with constant coefficients Let G be a (connected, simply connected) stratified Lie group and a\, ... , ad> a basis for g, in the stratification (gn)n(=ji r) of g. LEMMA 2.5. Let H = — ^ . =1 CJJAJAJ be a pure second-order subelliptic operator with constant coefficients. Then for all v e (0, 1} there exists a cDC > 0 such that for all R e (0, l],g eG and tp e H2l(B'(g; R)) satisfying H
| JB'( B'(g;R)
2
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for all 0 < r < R, where v = 2"'(1 + v). Moreover, cDG and c'DC depend on the coefficients of H only through /xc, IICIloo and |||C|||c"by fixing the PROOF. For g e G define the operator H(g) = - X!?7=i Aicij(g)Aj coefficients. By Lemmas 2.4 and 2.5 it follows that there exist cDC > 0 and c'DG > 0 such that for all R e (0, 1], and r] e H^A{B'{g\ R)) satisfying H{g)t) = 0 weakly on B'{g; R) one has
k=\ k=\ JB'ig.r)
< cDC(r/R)D+2i
\Akr, - {Akr,)g,R\2 + c'DCR2 f
J2 f k=i
JB'(g;R)
\Vn\2
JB'(g;R)
forallO < r < R. The cDC and c'DC depend only on fxc and \\C\\co and are in particular independent of g. Let R € (0, 1], g e G,
0 such that PROPOSITION
uniformly for all e > 0. The value of a is independent of 0, depending only on y + 8, such that where we have set /x = (y + 8 — D')/2. Moreover,
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and
Ilk,''"" \\cu\U for suitable a' and co, by Lemma 2.1 and (6). Together with the bounds (14) one deduces that
lllc;(')lllc,'lis>|£ < arv^r^e-^'uvh
