Bull. Malays. Math. Sci. Soc. DOI 10.1007/s40840-017-0538-0

A Note on Carleson Measures for Besov–Sobolev Spaces in the Unit Ball Cheng Yuan1 · Cezhong Tong2

Received: 10 November 2016 / Revised: 2 August 2017 © Malaysian Mathematical Sciences Society and Penerbit Universiti Sains Malaysia 2017

Abstract We show that a class of logarithmic Carleson measures is the Carleson measure for the Besov–Sobolev space in the unit ball of Cn . Keywords Carleson measures · Besov–Sobolev spaces Mathematics Subject Classification 32A37 · 30H25

1 Introduction Let Bn be the unit ball of Cn with boundary Sn and H (Bn ) the space of holomorphic functions on Bn . In particular, B1 is the unit disk D. Let dv denote the normalized Lebesgue measure of Bn , i.e., v(Bn ) = 1, and dσ denote the normalized rotation invariant Lebesgue measure of Sn satisfying σ (Sn ) = 1.

Communicated by Saminathan Ponnusamy. Cheng Yuan is supported by the National Natural Science Foundation of China (Grant No. 11501415); Cezhong Tong is supported by the National Natural Science Foundation of China (Grant No. 11301132) and Natural Science Foundation of Hebei Province (Grant No. A2013202265).

B

Cheng Yuan [email protected] Cezhong Tong [email protected]

1

Institute of Mathematics, School of Science, Tianjin University of Technology and Education, Tianjin 300222, China

2

Department of Mathematics, School of Science, Hebei University of Technology, Tianjin 300401, China

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C. Yuan, C. Tong

If ζ ∈ Sn and r > 0, let B(ζ, r ) = {z ∈ Bn : |1 − z, ζ | < r }. For 0 ≤ t, s < ∞ with t +s > 0, we say that a nonnegative Borel measure μ on Bn is a (t, s)-logarithmic Carleson measure if    2 t μ(B(ζ, r )) : ζ ∈ S , r > 0 < ∞. μLCMt,s = sup log n r r ns We write LCMt,s for the class of all (t, s)-logarithmic Carleson measures. When t = 0, the (t, s)-logarithmic Carleson measure becomes the s-Carleson measure, and we will denote by CMs = LCM0,s . See [9] for more details. Logarithmic Carleson measures were first introduced in [7] and were used to characterize the Riemann– Stieltjes operator on the Q p space, see [4,6]. For f ∈ H (Bn ) with homogeneous expansion f (z) =

∞ 

f k (z),

k=0

the radial derivative of f is defined as R f (z) =

∞ 

k f k (z).

k=1

It is easy to see that R f ∈ H (Bn ) with



1

f (z) − f (0) = 0

R f (t z) dt. t

(1)

More generally, for any two real parameters α and λ with the property that neither n+α nor n+α+λ is a negative integer, we define a class of fractional radial derivatives on H (Bn ) as R α,λ f (z) =

∞  (n + 1 + α)(n + 1 + k + α + λ) k=0

(n + 1 + α + λ)(n + 1 + k + α)

f k (z).

For integer m > 0, and for 0 ≤ σ < ∞, 1 < p < ∞, m + σ > n/ p , where neither n + α nor n + α + m is a negative integer, the Besov–Sobolev space B σp (Bn ) is defined to consist of those f ∈ H (Bn ) on the ball such that  p |R α,m f (z)| p (1 − |z|2 )mp+ pσ −n−1 dv(z) < ∞. (2)  f  B σ (Bn ) = p

Bn

A positive Borel measure μ on Bn is called a Carleson measure for B σp (Bn ) if there is a constant C > 0 such that  p | f (z)| p dμ(z) ≤ C f  B σ (Bn ) Bn

for all f ∈ B σp (Bn ).

123

p

A Note on Carleson Measures for Besov–Sobolev Spaces in…

The following theorem is quoted from [5], which characterizes the relation between the Carleson measure for B σp (Bn ) and the s-Carleson measure. Theorem 1 (Theorem 2.1 in [5]) Suppose integer m > 0, 0 ≤ σ < ∞, 1 < p < ∞, m + σ > n/ p , neither n + α nor n + α + m is a negative integer. Let μ be a positive Borel measure in Bn . (1) If σ > 0, then μ is a Carleson measure for B σp (Bn ) implies μ is a pσ/n-Carleson measure, and on the other hand, for any ε > 0, suppose μ is a ( pσ + ε)/nCarleson measure, we can get μ is a Carleson measure for B σp (Bn ). (2) If σ = 0, then μ is a Carleson measure for B 0p (Bn ) implies 

2 log r

sup



 p−1

μ(B(ζ, r )) : ζ ∈ Sn , r > 0 < ∞,

and on the other hand, for any ε > 0, suppose  sup

2 log r



 p+ε−1

μ(B(ζ, r )) : ζ ∈ Sn , r > 0 < ∞,

we can get μ is a Carleson measure for B 0p (Bn ). In the above characterization, there is an ε difference between the sufficient and necessary conditions. Motivated by this result, we show that the above ε conditions can be substituted by the logarithmic conditions, which seems a little bit sharper than the ε conditions. Our results are stated as follows: Theorem 2 Suppose integer m > 0, 0 ≤ σ < ∞, 1 < p < ∞, t > p − 1, m + σ > n/ p , neither n + α nor n + α + m is a negative integer. Let μ be a positive Borel measure in Bn . (1) If σ > 0, suppose μ is a (t, pσ n )-logarithmic Carleson measure, then μ is a Carleson measure for B σp (Bn ). (2) If σ = 0, suppose  sup

4 log log r

t   2 p−1 log μ(B(ζ, r )) : ζ ∈ Sn , r > 0 < ∞, r

then μ is a Carleson measure for B 0p (Bn ). The key point in [5] is that the duality theorem is adapted. In this manuscript we use a different strategy, which can also be used to prove Peng and Ouyang’s theorem in [5]. Some techniques in this paper are inspired in [3]. Notation Throughout this paper, we only write U  V (or V  U ) for U ≤ cV for a positive constant c, and moreover U ≈ V for both U  V and V  U . For 1 < p < ∞, we also write p = p/( p − 1) be the conjugate index of p.

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2 Preliminaries For each real parameter λ we define an operator R λ on H (Bn ) as λ

R f (z) =

∞ 

λ

k f k (z),

f (z) =

k=1

∞ 

f k (z).

(3)

k=0

The operator R λ is clearly invertible on H (Bn )/C, with its inverse given by Rλ f (z) = R

−λ

f (z) =

∞ 

k

−λ

f k (z),

f (z) =

k=1

∞ 

f k (z).

(4)

k=0

An application of Stirling’s formula yields that (n + 1 + α)(n + 1 + k + α + λ) ≈ kλ. (n + 1 + α + λ)(n + 1 + k + α) Thus, the semi-norm in definition of B σp (Bn ) is equivalent to 

p

 f  B σ (Bn ),∗ = p

Bn

|R m f (z)| p (1 − |z|2 )mp+ pσ −n−1 dv(z) < ∞.

(5)

We will need the following lemma modified by Lemma 3.2 in [2]. Lemma 3 Let t, s, γ ∈ (0, ∞) and μ be a nonnegative Borel measure on Bn . Then (1) μ ∈ LCMt,s if and only if μLCMt,s ,γ

 = sup log w∈Bn

2 1 − |w|2

t  Bn

(1 − |w|2 )γ dμ(z) < ∞; |1 − z, w|γ +ns

(6)

(2) sup

     4 t 2 s log log log μ(B(ζ, r )) : ζ ∈ Sn , r > 0 < ∞ r r

(7)

if and only if

t 4  log log 1−|w| 2 (1 − |w|2 )γ dμ(z) < ∞. sup

−s |1 − z, w|γ 2 Bn w∈Bn log 1−|w| 2

123

(8)

A Note on Carleson Measures for Besov–Sobolev Spaces in…

Proof (1) is Lemma 3.2 in [2]. For (2), first suppose Eq. (8) holds, given B(ζ, r ) = {z ∈ Bn : |1 − z, ζ | < r }. Letting w = (1 − r )ζ , we have 

t  s  (1 − |w|2 )γ dμ(z) 4 2 log log log 1 − |w|2 1 − |w|2 |1 − z, w|γ Bn t  s  2 (1 − |w|2 )γ 4 log ≥ log log μ(B(ζ, r )) inf z∈B(ζ,r ) |1 − z, w|γ r r t  s  2 4 log  log log μ(B(ζ, r )). r r

This means that      2 s 4 t log log log μ(B(ζ, r )) : ζ ∈ Sn , r > 0 r r

t 4  log log 1−|w| 2 (1 − |w|2 )γ dμ(z)  sup

. −s |1 − z, w|γ 2 Bn w∈Bn log 1−|w| 2

sup

On the other hand, if sup

     2 s 4 t log μ(B(ζ, r )) : ζ ∈ Sn , r > 0 < ∞. log log r r

When |w| < 3/4, it is easy to check that  log log

4 1 − |w|2

t  log

2 1 − |w|2

s  Bn

(1 − |w|2 )γ dμ(z) < ∞. |1 − z, w|γ

When 3/4 ≤ |w| < 1, let ξ = w/|w| and Jw be the integer part of | log2 (1−|w|2 )|−1. For k = 0, 1, . . . , Jw , consider the sets E 0 = ∅, E k = {z ∈ Bn : |1 − z, ξ | < 2k (1 − |w|2 )}, k ≥ 1. Moreover, let E Jw +1 be the unit ball. It follows that  log log

4 1 − |w|2

t  log

2 1 − |w|2

s  Bn

(1 − |w|2 )γ dμ(z) |1 − z, w|γ

t

4 J w +1 log log 1−|w| 2 (1 − |w|2 )γ 

μ(E k \ E k−1 ) −s 2γ (k−1) (1 − |w|2 )γ 2 log 1−|w| k=1 2

t 4 J w +1 log log 1−|w| 2 μ(E k ) 

−s 2γ (k−1) 2 log 1−|w| k=1 2

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C. Yuan, C. Tong

t

−s 4 2  −t J w +1 log log log 1−|w| 2 k 2 4 2 (1−|w| ) 

. log log −s 2k (1 − |w|2 ) 2γ (k−1) 2 log 1−|w| k=1 2 Similar to the proof of Lemma 3.2 in [2], it can be checked that  log

2 (1 − |w|2 )

 log

2 k 2 (1 − |w|2 )

−1

 k + 1,

and  log log

4 (1 − |w|2 )

 log log

4 2k (1 − |w|2 )

−1

 1 + log(k + 1).

Then we can easily get that

t

−s 4 2  −t J w +1 log log log 1−|w| 2 k 2 4 2 (1−|w| ) log log

−s 2k (1 − |w|2 ) 2γ (k−1) 2 log 1−|w| k=1 2



∞  (k + 1)s (1 + log(k + 1))t

2γ (k−1)

k=1

< ∞. 

This completes the proof.

It is easy to check that if Eqs. (6) and (8) hold for some γ > 0, they hold for all γ > 0 in the above lemma. We also need the following standard result from [9]. Lemma 4 Suppose s > −1, b > 0 and c < 0. Then (1)

 Bn

(2)

(1 − |w|2 )s dv(w)  1; |1 − z, w|n+1+s+c

(9)

dσ (ζ ) 1 ≈ |1 − z, ζ |n+b (1 − |z|2 )b

(10)

 Sn

for all z ∈ Bn . Straightforward computation can verify the following lemma. Lemma 5 Suppose t > 1 and s > −1. Then (1)

 Bn

123

 log

2 1 − |w|2

−t

(1 − |w|2 )s dv(w)  1; |1 − z, w|n+1+s

(11)

A Note on Carleson Measures for Besov–Sobolev Spaces in…

(2)  Bn

 log log

4 1 − |w|2

−t  log

2 1 − |w|2

−1

(1 − |w|2 )s dv(w)  1 |1 − z, w|n+1+s (12)

for all z ∈ Bn . Proof Inequality (11) can be seen as a special case of Lemma 3.4 in [1]. Indeed, let ζ = z and s = t0 + t1 in Lemma 3.4 of [1], (11) follows. Here we focus on the verification of (12). (11) can also be checked in the same way. It follows from the polar coordinate integral that −t  −1 4 2 (1 − |w|2 )s log dv(w) 1 − |w|2 1 − |w|2 |1 − z, w|n+1+s Bn −t  −1  1   4 2 (1 − r 2 )s log log log = 2n r 2n−1 dr dσ (ζ ) 2 2 1−r 1−r |1 − z, r ζ |n+1+s Sn 0  −t  −1  1  4 2 dσ (ζ ) 2 )s dr log = 2n r 2n−1 log log (1 − r 2 2 n+1+s 1−r 1−r Sn |1 − r z, ζ | 0  −t  −1  1 4 2 (1 − r 2 )s log ≈ 2n r 2n−1 log log dr 2 2 1−r 1−r (1 − r 2 |z|2 )1+s 0  −t  −1  1 4 2 (1 − r 2 )s log r 2n−1 log log dr ≤ 2n 2 2 1−r 1−r (1 − r 2 )1+s 0  −t  −1  1 4 2 1 log r 2n−1 log log dr = 2n 2 2 1−r 1−r 1 − r2 0 −t  −1   1 4 2 1 du. log u n−1 log log =n 1 − u 1 − u 1 − u 0



 log log

Obviously, the above “≈” line follows from (10) since 1 + s > 0. Notice that n ≥ 1. So last integral is less than or equal to 1

 I =

log log 0

Let x = 

4 1−u , ∞

I =

then u = 1 −

(log log x)

−t



4

∞

I ≤2 4

−t  log

and du =

4 x2

x 2

≥

1 2

−1

1 du. 1−u



∞

4

x −1 1 dx. (log log x)−t log 2 x

log x when x ≥ 4. Recall that t > 1, we have

dx =2 x log x(log log x)t

This completes the proof.

2 1−u

dx. Thus,

x −1 x 4 · log dx = 2 4 x2

It is easy to check that log 

4 x

4 1−u



∞ log 4

dy < ∞. y(log y)t 

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C. Yuan, C. Tong

3 Proof of Theorem 2 Proof For f ∈ B σp (Bn ), R m f ∈ H (Bn ), we can use the reproducing formula to get that  R m f (w)dvβ (w) , R m f (z) = n+1+β Bn (1 − z, w) where dvβ (z) =

(n + 1 + β) (1 − |z|2 )β dv(z), n!(β + 1)

and β > −1. Without loss of generality, we can suppose β > m + σ − n+1 p . m Since R f (0) = 0, we have    1 m m R f (w) − 1 dvβ (w) R f (z) = (1 − z, w)n+1+β Bn for all z ∈ Bn . According to (1),  1  1 dt1 dtm f (z) − f (0) = ··· R m f (t1 · · · tm z) ··· t tm 1 0 0 = R m f (w)L m (z, w)dvβ (w), Bn

where the kernel  L m (z, w) =

1

1

 ···

0

0

 1 dt1 dtm − 1 ··· . n+1+β (1 − t1 · · · tm z, w) t1 tm

Similar to [9, page 74, Exercise 2.24], we have |L m (z, w)| 

1 . |1 − z, w|n+1+β−m

Indeed, if we let h w (z) =

1 − 1, (1 − z, w)n+1+β

then h w (0) = 0. We can deduce from (1) and (4) that 

1



1

dt1 dtm ··· t1 tm 0 0  1  1 dt1 dtm = ··· R R −1 h w (t1 · · · tm z) ··· t1 tm 0 0 −m = R h w (z) = Rm h w (z).

L m (z, w) =

123

···

h w (t1 · · · tm z)

A Note on Carleson Measures for Besov–Sobolev Spaces in…

Recall that 1 −1 (1 − z, w)n+1+β ∞  (n + 1 + β + k) z, wk ; = k!(n + 1 + β)

h w (z) =

k=1

thus,

Rm h w (z) =

∞  (n + 1 + β + k) z, wk . k!(n + 1 + β)k m k=1

It can be checked from Stirling’s formula that (n + 1 + β + k) (n + 1 + β + k − m) . ≈ m (n + 1 + β)k (n + 1 + β − m) This gives that |L m (z, w)| = |Rm h w (z)| 

1 . |1 − z, w|n+1+β−m

It is not loss of generality to suppose f (0) = 0, and then we have the estimate  | f (z)| p 

Bn

p |R m f (w)|(1 − |w|2 )β dv(w) . |1 − z, w|n+1+β−m

(1) When σ > 0, notice that t/( p − 1) > 1, and it follows from the Hölder’s inequality and Lemma 5 that  t 2 |R m f (w)| p (1 − |w|2 ) pβ | f (z)|  log dv(w) n+1+ pβ− pm 1 − |w|2 Bn |1 − z, w|  

p−1  t 1− p 2 dv(w) log × 1 − |w|2 |1 − z, w|n+1 Bn  t  2 |R m f (w)| p (1 − |w|2 ) pβ log  dv(w). n+1+ pβ− pm 1 − |w|2 Bn |1 − z, w| 

p

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C. Yuan, C. Tong

Recall that β > m + σ − n+1 p , which implies n + 1 − pm − pσ + pβ > 0, and then we can use Fubini’s theorem and Lemma 3 to get that  | f (z)| p dμ(z) Bn





 |R f (w)| log

t  2 (1 − |w|2 ) pβ dμ(z) dv(w) n+1+ pβ− pm 1 − |w|2 Bn |1 − z, w| 2 t  |R m f (w)| p (log 1−|w| 2) (1 − |w|2 )n+1− pm− pσ + pβ dμ(z) dv(w) (1 − |w|2 )n+1− pm− pσ Bn |1 − z, w|n+1+ pβ− pm m

Bn

 

Bn

 

Bn

p

|R m f (w)| p (1 − |w|2 ) pm+ pσ −n−1 dv(w) p

=  f  B σ (Bn ),∗ , p

as desired. (2) When σ = 0, similarly to the σ > 0 case, we have 

| f (z)| p 

4 t |R m f (w)| p (1 − |w|2 ) pβ (log log 1−|w|2 ) dv(w) 2 n+1+ pβ− pm 1− p (log 1−|w| Bn |1 − z, w| 2) ⎛ ⎞ p−1  (log log 4 ) 1−t p 2 dv(w) 1−|w| ⎠ ×⎝ |1 − z, w|n+1 (log 2 2 ) Bn 1−|w|

  Thus,

Bn

4 t |R m f (w)| p (1 − |w|2 ) pβ (log log 1−|w|2 ) dv(w). |1 − z, w|n+1+ pβ− pm (log 2 2 )1− p 1−|w|

 Bn

| f (z)| p dμ(z) 

 

Bn

|R m f (w)| p

4 t  (log log 1−|w| 2)

(log

2 )1− p 1−|w|2

Bn

(1 − |w|2 ) pβ dμ(z) dv(w) |1 − z, w|n+1+ pβ− pm

|R m f (w)| p 2 n+1− pm Bn (1 − |w| ) 4 t  (log log 1−|w| 2) (1 − |w|2 )n+1− pm+ pβ dμ(z) × dv(w) 2 (log 1−|w|2 )1− p Bn |1 − z, w|n+1+ pβ− pm   |R m f (w)| p (1 − |w|2 ) pm−n−1 dv(w) 

Bn

p

=  f  B 0 (B p

n ),∗

.

This completes the proof.

123



A Note on Carleson Measures for Besov–Sobolev Spaces in…

Remark 6 In [5], Peng and Ouyang proved the sufficient part of Theorem 1 by the duality theorem. Indeed, it can also be proved by the method of this paper. (1) When σ > 0, if ε > 0 and μ is a  sup

w∈Bn

Bn

σ p+ε n -Carleson

measure, then

(1 − |w|2 )γ dμ(z) < ∞ |1 − z, w|γ +σ p+ε

for γ > 0. See Theorem 50 of [8] or Lemma 2.1 in [5]. We can use Lemma 4 and Hölder’s inequality to estimate that  | f (z)| 

Bn

Bn

|R m f (w)| p (1 − |w|2 ) pβ dv(w). |1 − z, w|n+1+ pβ− pm+ε

 



|R m f (w)| p (1 − |w|2 ) pβ dv(w) |1 − z, w|n+1+ pβ− pm+ε

p

Bn

p−1

dv(w) |1 − z, w|

ε n+1− p−1

Then  Bn

| f (z)| p dμ(z)





Bn

 

Bn

 

Bn



(1 − |w|2 ) pβ dμ(z) dv(w) n+1+ pβ− pm+ε Bn |1 − z, w|  |R m f (w)| p (1 − |w|2 )n+1− pm− pσ + pβ dμ(z) dv(w) 2 n+1− pm− pσ (1 − |w| ) |1 − z, w|n+1+ pβ− pm+ε Bn

|R m f (w)| p

|R m f (w)| p (1 − |w|2 ) pm+ pσ −n−1 dv(w) p

=  f  B σ (Bn ),∗ . p

(2) When σ = 0, if ε > 0 and μ is a nonnegative Borel measure with 

2 log r

sup



 p+ε−1

μ(B(ζ, r )) : ζ ∈ Sn , r > 0 < ∞,

then  sup

w∈Bn

log

2 1 − |w|2

 p−1+ε  Bn

(1 − |w|2 )γ dμ(z) < ∞ |1 − z, w|γ

(13)

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C. Yuan, C. Tong

for γ > 0. See Lemma 2.2 in [5]. Then  | f (z)|  p

Bn

|R m f (w)| p (1 − |w|2 ) pβ |1 − z, w|n+1+ pβ− pm

⎛  ×⎝  

Bn

Bn

 log

2 1 − |w|2

 log

2 1 − |w|2

 p−1+ε dv(w)

⎞ p−1 dv(w) ⎠ |1 − z, w|n+1   p−1+ε 2 log dv(w). 1 − |w|2

− p−1+ε p−1

|R m f (w)| p (1 − |w|2 ) pβ |1 − z, w|n+1+ pβ− pm

It follows from (13) that  | f (z)| p dμ(z) Bn





Bn

 

 |R m f (w)| p log |R m

2 ) p−1+ε 1−|w|2 (1 − |w|2 )n+1− pm

Bn

|R f (w)| (1 − |w| ) m

Bn

p

p

=  f  B 0 (B p

 p−1+ε 

f (w)| p (log

 

2 1 − |w|2

n ),∗

2 pm−n−1

 Bn

Bn

(1 − |w|2 ) pβ dμ(z) dv(w) |1 − z, w|n+1+ pβ− pm

(1 − |w|2 )n+1− pm+ pβ dμ(z) dv(w) |1 − z, w|n+1+ pβ− pm

dv(w)

.

Acknowledgements The authors would like to thank the editor and the referee(s) for their helpful comments and valuable suggestions for improving this manuscript.

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