Commutators of Singular Integral Operators Related to Magnetic Schrdinger Operators

Wanqing Ma and Yu Liu

School of Mathematics and Physics,University of Science and Technology Beijing,Beijing 100083,China

1 Introduction

Letbbe a locally integrable function on RnandTbe a linear operator.For a suitable functionf,the commutator is defined by[b,T]f=bT(f)?T(bf).It is well known that Coifman,Rochberg and Weiss[3]proved that[b,T]is a bounded operator onLpfor 1

Furthermore,Lu,Wu and Yang studied the boundedness properties of the commutator[b,T]on the classical Hardy spaces whenb∈Lipα(Rn)in[12].

In recent years,more scholars pay attention to the boundedness of the commutators[b,T]whenTare the singular integral operators associated with the Schrdinger operator(cf.[1,6–11]).When the potentialVsatisfies the weaker condition,the operatorTmay not be a Calder′on-Zygmund operator.In this paper we focus on the boundedness of the commutators[b,T]whenTare the singular integral operators associated with the magnetic Schrdinger operator based on the research in[5]and[16].

Consider a real vector potential~a=(a1,···,an)and an electric potentialV.In this paper,we assume that

LetLk=?/?xk?iak.We adopt the same notation as in[5]and define thesesquilinear form Qby

with domain

It is known thatQis closed and symmetric.So the magnetic Schrdinger operatorAis a self-adjoint operator associated withQ.

The domain ofAis given by

andAis formally given by the following expression

orA=?(??)·(??)+V,whereis the adjoint operator ofLk.Fork=1,···,n,the operatorsLkA?1/2andV1/2A?1/2are called the Riesz transforms associated withA.Moreover,it was proved in[14]that for eachk=1,···,n,the Riesz transformLkA?1/2andV1/2A?1/2are bounded onLp(Rn)for all 10 such that

Furthermore,in[5]Duong and Yan proved that the commutators[b,V1/2A?1/2]and[b,LkA?1/2]are bounded onLpfor 10 such that

See also Shen’s result in[15]forLp-boundedness of singular integral operators related to the magnetic Schrdinger operator,which is different from the operatorsLkA?1/2andV1/2A?1/2.Recently,D.Y.Yang in[16]has proven that fork∈{1,···,n},the commutators[b,LkA?1/2]are bounded fromLp(Rn)toLq(Rn)with 1/p?1/q=α/n,whereb∈Lipα(Rn).Inspired by[5]and[16],the purpose of this paper is to study the boundedness of commutator[b,V1/2A?1/2]with a functionbin the Lipschitz space Lipα(Rn),α∈(0,1).

We are now in a position to give our main result,which will be proven in the next section.

Theorem 1.1.Let α∈(0,1),p,q∈(1,2]with1/p?1/q=α/n.Assume that b∈Lipα(Rn).Then the commutator[b,V1/2A?1/2]is bounded from Lp(Rn)to Lq(Rn).

2 Proof of Theorem 1.1

In this section,we adopt the method in[16]to prove Theorem 1.1.Firstly,we begin with the sharp maximal functionestablished in[13].For anyf∈Lp(Rn),p∈[1,∞),the sharp maximal functionassociated with the semi group{e?tA}is given by

whererBis the radius of the ballBandtB:=

Lemma 2.1.Let p∈(1,∞).There exists a positive constant Cpsuch that for all f∈Lp(Rn),

Proofof Theorem 1.1.Now,we prove the boundedness of the commutator[b,V1/2A?1/2]in Theorem 1.1.Let(V1/2A?1/2)?=A?1/2V1/2denote the adjoint operator ofV1/2A?1/2.By duality,for givenp,q∈(1,2]with 1/p?1/q=α/n,it suffices to prove[b,A?1/2V1/2]is bounded fromLq′(Rn)toLp′(Rn).To obtain the conclusion,it suffices to prove that there exists a constantCsuch that for all

where forr∈[2,n/α)and any suitable functionf,

In fact,assume that(2.1)holds.Forb∈Lipα(Rn)and eachN∈N,definebN:=min{N,|b|}sgn(b).Then we conclude thatbN∈L∞(Rn)and kbNkLipα(Rn)≤CkbkLipα(Rn),whereCis a constant.Moreover,it has been proved in Theorem1.1 of[14]thatV1/2A?1/2is bounded onLp(Rn)for all 1

Recall thatM2,αis bounded fromLs(Rn)toLt(Rn)withs∈(2,n/α)and 1/s?1/t=α/n,see Chanillo[2].By this fact together with 1/q′?1/p′=α/n,Lemma 2.1 and(2.1),we have that for all

A standard argument together with the Fatou lemma then implies that for all

and

which imply Theorem 1.1.

Now,we prove(2.1)is valid.For anyf∈Lq′(Rn),andx∈Rn,choose a ballB:=B(xB,rB)={y∈Rn:|xB?y|

and

for any functionfand ballB,where

Therefore,

Firstly,we get

For I,by the Hlder inequality and(2.3),we have

For II,using the Hlder inequality again and theL2(Rn)-boundedness ofT,if follows that

To estimate III,it follows from[5]that the kernelpt(y,z)ofe?tAsatisfies that for allt>0 and almost ally,z∈Rn,

Letg:=(b?bB)Tf.By(2.4),the formula equation ofe?|x|≤C|x|?Nand the conclusion of I,for anyy∈B,

whereN>n/2.So for III,it is easy for us to get

For IV,for all locally integrable functionsfandx∈Rn,letM(f)(x)be the Hardy-Little wood maximal function as follow:

By(2.4),the conclusion of II,the Hlder in equality and theL2(Rn)-boundedness ofTandM,we conclude that

In order to estimate the term V,we need the following Proposition 2.1 and Lemma 2.2.

Proposition 2.1(cf.Proposition 3.1 in[5]).Fixs>0.LetA=?(??)·(??)+Vbe the magnetic Schrdinger operator.Then for anym∈N,there exist positive constantsCandcsuch that

for alls>0 andy∈Rn.

Lemma 2.2.For a real vector potential~a=(a1,···,an)and an electric potential V,we as-sume that ak∈Then the composite operator(I?e?tA)A?1/2V1/2,t>0,which is the adjoint operator of V1/2A?1/2(I?e?tA),has an associated kernel(y,z)which satisfies

Proofof Lemma 2.2.Firstly,we need to compute the(y,z)of(I?e?tA)A?1/2V1/2.Observe that

then we have

Therefore,

By Minkowski’s inequality,we have

Together with Proposition 2.1,this gives

We first estimate the term I1.Note thatχs>t≡ 0 fors0,shows

Consider the term II1.Oberve that,fors>t,thenχs>t=1.A direct calculation shows that

Substituting the above into the term II1,we obtain

Because thatt

Therefore,

Finally,we estimate the term II1,2.Sinces>2t,we have thatHence,

Combining the estimates of I1,II1,1,II1,2we obtain(2.5).Hence,the proof of(2.5)is complete.Now,we will start the proof of Theorem 1.1.

Proofof Theorem 1.1.Let us consider the term V.We have that

So the kernelof the operatorsatisfies the following estimate

whereCis a constant independent oftandy.

Finally,from the fact that|y?z|≥rBfor anyy∈B,z/∈2B,the conclusion of(2.3),Lemma 2.2 and the Hlder inequality,the term V is dominated as follows,

Combining the estimates from I to V,we see that(2.1)holds,which completes the proof of Theorem 1.1. ?

Acknowledgements

This work is supported by the National Natural Science Foundation of China(No.11671031 and No.11471018),the Fundamental Research Funds for the Central Universities(No.FRF-BR-17-004B),Program for New Century Excellent Talents in University,Beijing Municipal Science and Technology Project(No.Z17111000220000).

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