The sharp higher order Hardy Rellich type inequalities on the homogeneous groups

The sharp higher order Hardy Rellich type inequalities on the homogeneous groups arxiv:708.093v [math.fa] 30 Aug 07 Van Hoang Nguyen August 3, 07 Abstract We prove several interesting equalities for the integrals of higher order derivatives on the homogeneous groups. As consequences, we obtain the sharp Hardy Rellich type inequalities for higher order derivatives including both the subcritical and critical inequalities on the homogeneous groups. We also prove several uncertainty principles on thehomogeneous groups. Ourresultsseem to benew even in thecase of Euclidean space R n and give a simple proof of several classical Hardy Rellich type inequalities in R n. Introduction The motivation of this paper is to prove several inequalities of Hardy Rellich type in the setting of the homogeneous groupsthe most general class of all nilpotent Lie groups in the framework of equalities. Our obtained inequalities generalize several well-known Hardy Rellich type inequalities in the Euclidean space R n. The Hardy Rellich type inequalities in R n involve the integrals of a function and its derivatives. They appear frequently in various branches of mathematics and provide a useful tool, e.g., in the theory and practice of differential equations, in the theory of approximation etc. Let us start by recalling the classical Hardy inequalities in R n, n 3 n Rn f f R. n Institut de Mathématiques de Toulouse, Université Paul Sabatier, 8 Route de Narbonne, 306 Toulouse cédex 09, France. Email: van-hoang.nguyen@math.univ-toulouse.fr, vanhoang060@yahoo.com 00 Mathematics Subject Classification: 6D0, 43A85, E30, 43A80. Key words and phrases: weighted L Hardy Rellich type inequalities, weighted L p Hardy Rellich type inequalities, critical Hardy Rellich type inequalities, uncertainty principles, homogeneous groups

foranyfunctionf C0 R n. Theconstantn /4in.issharp. Asimilarinequality with the same best constant holds if R n is replaced by any domain Ω containing the origin. This inequality plays an important role in many areas such as the spectral theory, the theory of partial differential equations associated to the Laplacian, see e.g., [4, 5, ] for reviews of this subject. For interest readers, we refer to [6,5] for the improvements of. when R n is replaced by the bounded domains Ω containing the origin. The L p version of. takes the form p n p Rn f p f p R p p,. n for any function f C0 R n with n and < p < n. Again, the constant n p p /p p is sharp in.. In the case p = n the inequality. fails for any constant. However, in boundede domains, the following inequality holds B n n f n n B f n n +ln n, f C 0 B.3 for any n, where B denotes the unit centered ball in R n see, e.g., [4]. The constant n n /n n in.3 is sharp. It was also shown in [4] that.3 is equivalent to the critical case of the Sobolev Lorentz inequality. However,.3 is not invariant under the scalings as. and.. In [7], Ioku and Ishiwata established a scaling version of.3 as follows n n f n n B n ln n x B f n, f C0 B..4 The constant n n /n n in.4 is sharp. The inequality.4 in bounded domains is also discussed in [7]. It is surprise that the critical Hardy inequality.4 is equivalent to the subcritical Hardy inequality. in larger dimension spaces see [5]. A global scaling invariant version of.3 was proved in [8] by Ioku, Ishiwata and Ozawa as follows n n Rn f f R n n n n ln R n x R f, f C0 Rn \{0}.5 n for any R > 0 with f R x = frx/. Indeed,.5 was proved in [8] with a sharp remainder. Again, the constant n n /n n in.5 is sharp. Note that.5 implies.4 by taking R = for any function supported in B. The Rellich inequality states that for any function f H R n, n 5 nn 4 Rn f f R 4 4..6 n The constant n n 4 /6 is sharp in.6. A similar inequality also holds true in H 0 Ω for any smooth domain Ω of R n containing the origin. This inequality was first proved by

Rellich[4]forfunctionsf H0Ωandthenwasextendedforfunctionsf H Ω H0Ω by Dold et al. in [3]. Davies and Hinz [] generalized.6 and shows that for any p,n/, it holds p np n p Rn f p f p R p n p, f C 0 Rn \{0}..7 The constant np n p p /p p is the best constant in.7. A weighted version with the sharp constant of.7 is also given in []. In [3,,53], the improvements of.6 in smooth bounded domains Ω R n containing the origin was proved by adding the nonnegative remainder terms. The Hardy and Rellich inequalities also was extended to the higher order derivatives with weights in []. Let 0 < k < n/ be an integer and a function f H k R n. Then if k = m If k = m+, then R n m f m i= n+4in 4 4i 4 f R 4m..8 n m n n++4in 6 4i Rn m f f R 4 4m+..9 n Again, the inequalities.8 and.9 are sharp with the best constants. The improved versions of.8 and.9 in bounded smooth domains of R n was proved by Tertikas and Zographopoulos [53]. We next state the L p version with weights of.8 and.9 which was established in []. If k = m < n, m, p,n/m and α p /p,n mp/p then Rn m f p m n p i+αpn+p p i+α Rn f p αp pp αp+mp.0 for any function f C 0 Rn \{0}, where p = p/p with p >. It was also prove that if k = m+ < n, m, p,n/m+ and α /p,n m+p/p, then Rn m f p p m n p α n p i++αpn+p p i++α αp p pp Rn f p αp+m+p. for any function f C 0 R n \ {0}. Note that the constants in.0 and. are sharp. Davies and Hinz proved the inequality.0 by iterating the sharp weighted Rellich inequality i.e., a weighted version of.7. The inequality. follows from the sharp weighted Hardy inequality i.e., a weighted version of.. We refer the reader 3

to [] for more detail on the proof of.0 and.. In [38], Mitidieri proposed the simple approaches to prove these Hardy Rellich type inequalities including.,.,.6,.7,.8,.9,.0 and.. The first approach is based on the divergence theorem by choosing a special vector field. The second approach is based on the Rellich- Pohozaev type identities [37]. In the critical case p = n/k, the critical Rellich type inequalities on bounded domains was proved by Adimurthi and Santra [3]. Let us recall their results here. Let Ω be a bounded domain of R n containing the origin. If n = p then we can find a R > 0 such that Ω f p n p n p Ω f p ln n R p, f C0 Ω\{0}.. It is noted that the constant n p /n p is the best constant in.. In the case n = 4, it was proved that there exists R 0 > 0 such that for any R R 0, it holds f f Ω Ω ln 4 R, f C 0 Ω\{0}..3 The inequality.3 is sharp see also []. Adimurthi and Santra [3] also proved the critical Rellich type inequalities in H k R n with n = k. Let B denote the unit ball centered at the origin in R n. We can find a R > 0 such that m f n m f 4i+8m 4i 6 B 6 m B ln n R.4 if n = 4m, m and m f n m 4m 4i 4m+4i+ 6 m B B f ln n R.5 if n = 4m+, m for any radial function f H0 k B. Again, the inequalities.4 and.5 are sharp. Moreover, the stronger versions of.,.4 and.5 with nonnegative remainder terms was proved in [3]. Besides these Hardy Rellich type inequalities, there is a similar Rellich inequality that connects first to second order derivatives. That is, for any n 5 and for any function f C0 Rn \{0} we have Rn f n 4 Rn f..6 The constant N /4 is the best constant in.6. This inequality was proved in [] by Adimurthi, rossi and Santra for radial functions. And its improvement was obtained by 4

Tertilas and Zographopoulos in [53] together with its weighted version. We also mention here that the L p version of.6 was proved by Adimurthi and Santra in [3] for only radial functions again. These Hardy Rellich type inequalities arise very naturally in the study of singular differential operators. They have been intensively analysed in many different settings. The sharp Hardy and Rellich inequalities was extended to the Riemannian manifolds in [,9,5,3,3,54]. They were proved in the setting of the fractional Laplacians in [6,9, 0, 6, 39, 55] and references therein. The Hardy inequality was proved in the Heisenberg group for p = by arofalo and Lanconelli [] see also D Ambrosio [8] and for any p by Niu, Zhang and Wang [40]. Further extensions were made by Danielli, arofalo and Phuc [0] on groups of Heisenberg type, by oldstein and Kombe [3] on polarisable groups, by JinandShen [30] andlian[33] oncarnot groupstogether with certainweighted versions. An unified approach to the weighted Hardy inequalities on Carnot groups was recently introduced in [4]. The higher order Hardy inequalities on the stratified Lie groups was obtained by Ciatti, Cowling and Ricci [7] for arbitrary homogeneous quasinorm but without the sharp constant. For the horizontal Hardy, Rellich, Caffarelli Kohn Nirenberg inequalities on stratified groups, we refer the reader to the paper of Ruzhansky and Suragan [44]. Recently, there is an enourmous work on studying the sharp Hardy and sharp Rellich inequalities on the homogeneous groups see, e.g., [4, 43, 45 50]. Note that the abelian groups R n,+, the Heisenberg group, homogeneous Carnot groups, straified Lie groups and graded Lie groups are all special cases of the homogeneous groups. Before introducing the recent inequalities obtained on the homogeneous groups, let us remark that the Hardy inequalities. and. can be sharpned to the inequality p n p Rn f p p p x f p, < p < n..7 R n The remainder terms for.7 have been analysed by Ioku, Ishiwata and Ozawa [9], see also Machihara, Ozawa and Wadade [35]. An extension of.7 have been extended to the homogeneous groups by Ruzhansky and Suragan [45]. Let be a homogeneous groups of homogeneous dimension Q, and let be any homogeneous quasi-norm on we refer the reader to Section for further details related to the homogeneous group. Let us define the radial operator R = R with respect to by R := R = d d..8 Clearly, when is abelian group R n,+ and is Euclidean norm onr n then R is exactly the radian derivative r := x. In [45], the following generalized Lp Hardy inequality was proved p Q p f p p p Rf p, < p < Q,.9 foranycomplex-valuedfunctionf C0 \{0}, wheredenotesthehaarmeasureon. TheconstantQ p p /p p in.9issharpforanyquasi-norm. Moreover, Ruzhanskyand 5

Suragan also obtained the remainder terms in.9 and proved an uncertainty principle on from.9. The inequality in the critical case p = Q of.9 was discussed in [43] p p f f R p Rf sup p p R>0 ln Q R p Q p,.0 for any < p <, where f R = frx/. The inequality.0 generalizes the inequality.5 to the homogeneous groups for any homogeneous quasi-norm. In [45], Ruzhansky and Suragan also proved a Rellich inequality on. Denote Then the following inequality holds Q Q 4 6 R = R + Q R.. f 4 R f,. for any complex-valued function f C 0 \ {0}. The constant Q Q 4 /6 is the best constant in. for any homogeneous quasi-norm. The appearance of R in. is nature since there is no analogue of homogeneous Laplacian or sub-laplacian on the general homogeneous groups to formulate a version similar to.6. In fact, there may be no homogeneous hypoelliptic left-invariant differential operators at all: the existence of such an operator would imply that the group must be graded as was shown by Miller [36] with further corrections by ter Elst and Robinson [5] see also [7, Proposition 4..3] for a simple proof. Obviously, in the abelian case with the Euclidean norm, R is nothing the radial Laplacian r = r + n r. Hence,. implies the following inequality in R n n n 4 Rn f 6 4 r f, n 5..3 R n The inequality.3 together with a recent result of Machihara, Ozawa and Wadade [35] implies.6. The higher order versions of.9 in the case p = was also obtained in [45]. By iterating the weighted versions of.9 with p =, Ruzhansky and Suragan proved the following sharp weighted Hardy Rellich type inequalities k Q j=0 α+j f k+α R k f.4 α for any Q 3, k and α R. The inequalities. and.4 are new even in the abelian case. As mentioned above, the main aim of this paper is devoted to prove several inequalities of Hardy Rellich type on the homogeneous groups. Our main results extended the 6

inequality. in several ways. They give the generalizations of the Hardy Rellich type inequalities on R n mentioned above to the homogeneous groups with any homogeneous quasi-norm. First, we generalize it to any p, Q/ together with its weighted versions which is the content of Theorem 3. and Theorem 4. below. These obtained inequalities can be seen as the generalizations of the inequalities.6,.7 and their weighted versions to the homogeneous groups with any homogeneous quasi-norm. Second, we extend it to the derivatives of higher order, i.e., we prove the Hardy Rellich type inequality for R k and RR k for k. This is the content of Theorem 3. and Theorem 4.4. These obtained inequalities also extend the inequalities.8,.9,.0 and. to the homogeneous groups with any homogeneous quasi-norm. Thirst, we will prove the inequality. in the critical case, i.e., p = Q/ and extend this critical inequality to the derivatives of higher order in Theorem 5. and Theorem 5.4 below respectively. Again, these are the extensions of the critical Rellich type inequalities.,.3,.4 and.5 to the homogeneous groups. Finally, we will generalize the inequality.6 together with its weighted versions and its L p versions to the homogeneous groups. These are the Rellich type inequalities obtained in Theorem 3.3 below for p = and Theorem 4.7 for any < p < Q/. By iterating these obtained inequalities, we will prove an extension of.6 to any order of derivatives in Theorem 3.4 and Theorem 4.8. In application, we obtain, in Section 6 below, several uncertainty principles on the homogeneous groups by using our obtained Hardy Rellich type inequalities. It is worth to emphasize here that all the inequalities obtained in this paper are sharp and are derived from the corresponding equalities by dropping the nonnegative remainder terms. They are new even in the Euclidean space R n, and give some new inequalities of Hardy Rellich type both in the subcritical and critical cases in the setting of Euclidean space R n see Section 7 below. The rest of this paper is organized as follows. In Section we review briefly some basic properties of the homogeneous groups, fix the notation and recall the weighted L Hardy inequalities on the homogeneous groups established by Ruzhansky and Suragan. In Section 3 we prove some weighted L Hardy Rellich inequalities on the homogeneous groups. These inequalities include the weighted L Rellich inequality a weighted version.. We then use the weighted L Hardy and weighted L Rellich inequality to establish the weighted L Hardy Rellich type inequalities for higher order derivatives on the homogeneous groups. We also prove the Rellich type inequality that connects first to seconde order of derivatives and use it to derive the similar inequalities for any order of derivatives in this section. The L p versions of the Hardy Rellich type iequalities obtained in Section 3 i.e., the weighted L p Hardy Rellich type inequalities will be established in Section 4. The critical Hardy Rellich type inequalities on the homogeneous groups are proved in Section 5. In Section 6, we obtain several new inequalities in the Euclidean space R n by applying our results to this setting. 7

Preliminaries In this section, we review briefly some basics of the analysis on homogeneous groups, some properties of the operator R from.8 and the weighted L Hardy inequality on the homogeneous groups due to Ruzhansky and Suragan [45]. For the general background details on homogeneous groups, we refer the reader to the book of Folland and Stein [8] and the book of Fisher and Ruzhansky [7]. We recall that a family of dilations of a Lie algebra g is a family of linear mappings given by D λ = expalnλ = k! Alnλk, where A is a diagonalisable linear operator on g with positive egienvalues, and each D λ is a morphism of the Lie algebra g, that is, a linear mapping from g to itself which respects the Lie bracket: [D λ X,D λ Y] = D λ [X,Y], X,Y g, λ > 0. A homogeneous groups is a simply connected Lie group whose Lie algebra is equipped with dilations. Homogeneous groups are necessarily nilpotent and hence the exponential mapping exp : g is a global diffeomorphism. It induces a dilation structure on which is still denoted by D λ x or simply by λx with x, i.e., k=0 D λ x = λx := exp D λ exp x. The homogeneous dimension of is TrA and is denoted by Q. Let denote the Haar measure on and let S denote the corresponding volume of a measurable subset S. Then we have λs = λ Q S, fλx = λ Q fx. Fix a basis X,...,X k of g such that AX k = ν k X k for each k, so that A has the form A = diagν,...,ν n in this basis. Then each X k is homogeneous of degree ν k and Q = ν +ν + +ν n. The decomposition of exp x in the Lie algebra g defines the vector by the formula ex = e x,...,e n x exp x = ex = e i xx i, where = X,...,X n. In the other word, we have x = exp j= i= e j xx j. 8

By the homogeneity, we have rx = exp r ν j e j xx j, j= that is, erx = r ν e x,...,r νn e n x. Consequently, we can calculate d dr frx = d dr f exp r ν j e j xx j j= = ν j r νj e j xx j frx. j= This implies the equality d frx = Rfrx. dr In other words, the operator R plays the role of the radial derivative on. Note that R is positively homogeneous of order. A homogeneous quasi-norm on a homogeneous group is a continuous nonnegative function x [0, satisfying the following conditions: x = for any x, λx = λ for any λ > 0 and x, = 0 if and only if x = 0. Let be a quasi-norm on and let S denote the quasi-unit sphere with respect to, i.e., S = {x : = }. It is well-known that there is a unique positive Borel measure σ on S such that for any function f L we have fx = fryr Q dσydr.. 0 S We refer the reader the book of Folland and Stein [8] for the proof see also [7, Section 3..7]. In our analysis below, the following result whose proof can be found in [45, Lemma.] plays an important role. 9

Lemma.. Define the Euler s operator E on by E = R. If f : \ {0} R is continuously differentiable, then Ef = νf if and onlu if fλx = λ ν fx, λ > 0,x 0, i.e., f is positively homogeneous of order ν. We conclude this section by recalling a weighted L Hardy inequality on the homogeneous group due to Ruzhansky and Suragan see [45, Theorem 4. and Corollary 4.]. Theorem.. Let be a homogeneous group of homogeneous dimension Q 3 and let be any homogeneous quasi-norm on. Then for any complex-valued function f C0 \{0} we have Rf Q α f = α α++ Rf + Q α f α α+. for any α R. As a corollary, we have the following weighted L Hardy inequality on, Q α f α+ Rf..3 α The constant in.3 is sharp and it is attained if and only if f = 0. 3 Weighted L Hardy Rellich type inequalities Throughout this section, we use the notation c α = Q+αQ 4 α 4 for any α R, here Q is the homogeneous dimension of a homogeneous group. We start this section by proving an interesting equality which implies the weighted L Rellich inequality. on. This can be seen as a weighted version of Theorem 5. in [45]. Recall that R f = R f + Q Rf. We then have following results. Theorem 3.. Let be a homogeneous group of homogeneous dimension Q 5 and let be any homogeneous quasi-norm on. Then for any complex-valued function f C0 \{0} we have R f α = c α f α+4+ +c α 0 R f +c f α α α+ Rf Q 4 α + f +α +α, 3.

for any α R. The constant c α before 4 α f in the right hand side of 3. is sharp. As a consequence, we obtain the following weighted Rellich inequality for any complex-valued function f C 0 \{0} Q+αQ 4 α 4 f α+4 R f, 3. α for any α Q/,Q 4/. The constant in 3. is sharp and it is attained if and only if f = 0. If α = 0, Theorem 3. recovers Theorem 5. and Corollary 5. in [45]. The proof of Theorem 3. follows the lines in the proof of Theorem 5. in [45] see also the proof of Theorem. in [35] for the Euclidean space R n. Proof. Using the polar coordinate., we have f 4+α = r Q 5 α fry dσydr 0 S = r Q 4 α fry dσydr Q 4 α 0 S = Q 4 α R r Q 4 α fryrfrydσydr 0 S = Q 4 αq 3 α R r Q 3 α fryrfrydσydr 0 S = Q 4 αq 3 α R r Q 3 α Rfry +fryr fry dσydr 0 S = Q 4 αq 3 α R Rf + fr f, 3.3 +α +α here Rz denotes the real part of a complex number z C. From Theorem., we have Rf Q 4 α f +α = 4 4+α+ Rf Q 4 α + f +α +α Using integration by parts, we have fr R f +α = R = R f R f frf +α Q R f R f Q Q 4 α +α+ 3+α 3.4 f 4+α. 3.5

Plugging 3.4 and 3.5 into 3.3 implies f 4+α = R c α = c α + c α f R f +α c α R f +c f α α R f α c a Rf Q 4 α + f +α +α + f 4+α Rf Q 4 α + f +α +α α+ which implies our desired result 3.. It remains to verify the sharpness of c α in 3.. To do this, we will use the approximations of the function r Q 4 α/ as follows. Let φ C0 R such that φ = on, and φ = 0 on R\,. For any ǫ > 0, define f ǫ r = φr/ǫr Q 4 α φǫr. Differentiating f ǫ we get and Rf ǫ r = ǫ φ ǫ rr Q 4 α φǫr Q 4 α φǫ rr Q α φǫr +ǫ φr/ǫr Q 4 α φ ǫr, R f ǫ r = ǫ φ ǫ rr Q 4 α φǫr+ǫ φǫ rr Q 4 α φ ǫr + Q 4 α φ ǫ rr Q α φǫr ǫq 4 α φǫ rr Q α φ ǫr ǫ + Q 4 αq α φǫ rr Q α φǫr, 4 here we use the supports of φ r/ǫ and φ ǫr are disjoint for ǫ > 0 small enough. Thus, we obtain R f ǫ r = ǫ φ ǫ rr Q 4 α φǫr+ǫ φǫ rr Q 4 α φ ǫr This implies We can easily check that 3+α φ ǫ rr Q α φǫr+ǫ3+α φǫ rr Q α φ ǫr ǫ c α φǫ rr Q α φǫr. R f ǫ α = c α lnǫσs+o. f ǫ 4+α = lnǫσs+o,

and R f ǫ + Q α +αrf ǫ +c α +αrf ǫ + Q 4 α +α f ǫ α+ f ǫ = O, = O. These computations show that the constant c α is sharp in 3.. The inequality 3. is trivial since c α > 0 for α Q/,Q 4/. We next verify the sharpness of constant. For ǫ > 0, consider the function f ǫ as above. We then have lim ǫ 0 R f α ǫ + Q f ǫ 4+α Rf ǫ = c α, which implies the sharpness of c α. Suppose that there exists equality in 3. for some function f. From Theorem 3., we must have Rf + Q 4 α f = 0 Ef = Q 4 α f. Lemm. implies that f is positively homogeneous of order Q 4 α/, i.e., there exists function h : S C such that fx = Q 4 α/ hx/. Since fx/ +α is in L, we then have h = 0 on S or equivalently f = 0 on. We continue by extending Theorem. and Theorem 3. to derivatives of higher order. This will be done in the following theorem. Theorem 3.. Let be a homogeneous group of homogeneous dimension Q, and let be a quasi-norm on and k be a positive integer and α R. For any complex-valued function f C 0 \{0} we have k c i+α j= f 4k+α R k = f α k j c i+α c α α +α RRk k j j= Rk f +c R k f α R k j 4j+α Rk j f +c j+α f+ Q 4 α c i+α c j+α +α+4j f R k f RRk j f+ Q 4 α 4j R k j f, 3.6 3

if Q 4k +, and k Q α c i++α RR k = f α α Q α 4 Q α 4 +α k j j= Q α c +α Q α k j j= f 4k++α Q α RRk f+ R k f Rk f +c R k f +α R k j c i+α +α+4j Rk j f +c j++α 4+α RRk f+ Q 6 α R k f c i++α c j++α 4+α+4j RRk j f+ Q 6 α 4j f R k j f 3.7 if Q 4k +3. As consequence, we following weighted Hardy Rellich type inequalities for any complexvalued function f C 0 \{0} k c i+α f 4k+α R k f 3.8 α if Q 4k + and α Q/,Q 4k/, and k Q α f c i++α 4k++α RR k f 3.9 α if Q 4k +3, k and α Q+/,Q 4k /. Moreover, these inequalities are sharp and the equality holds if and only if f = 0. Proof. We first prove 3.6. If k =, it is exactly 3. from Theorem 3.. If k >, it follows by induction argument using consecutively Theorem 3.. We next prove 3.7. Using Theorem., we get RR k f α = Q α 4 R k f +α+ Q α α RRk f+ R k. f 3.0 4

Thus, 3.7 follows from 3.6 and 3.0. The inequalities 3.8 and 3.9 are trivial since c i+α > 0,c i++α > 0 for any i = 0,...,k corresponding to each case. To check the sharpness of constant, we use the arguments as in the proof of Theorem 3. by approximating the function r Q 4k α/. The straightforward and tedious computations show that f ǫ 4k+α = lnǫσs+o, and R k k f = c α i+α lnǫσs+o. This proves the sharpness of 3.8. For 3.9, we use the approximations of the function r Q 4k α/ and make the same computations. If equality holds in 3.8 for a function f. From 3.6, we see that Rf + Q α 4k f = 0 Ef = Q α 4k f. By Lemma., f is positive homogeneous of order Q α 4k/ which forces f = 0 since f/ α+k L. The same argument also works for the equality in 3.9. The rest of this section is to establish the generalizations of.6 to the homogeneous groups and its higher order versions. We first extend.6 to a weighted version on the homogeneous groups as follows. Theorem 3.3. Let be a homogeneous group of homogeneous dimension Q 5. Let be any homogeneous quasi-norm on. Then for any complex-valued function f C 0 \{0}, we have R f Q+α = α 4 Rf +α+ α R f + Q α Rf, 3. for any α R. As consequence, we get the following Rellich type inequality Q+α Rf 4 +α R f 3. α for any complex-valued function f C 0 \ {0} and α R. The inequality 3. is sharp and equality hold if and only if f = 0. Proof. Expanding the square of R f, we get R f = α RRf α RRfRf +Q R +Q Rf α+ +α. 5

Using integration by parts, we have RRfRf R α+ By Theorem., we have RRf = Q α α 4 = Q α Rf +α. Rf +α+ α R f + Q α Rf athering these equalities together, we obtain 3.. The inequality 3. is an immediate consequence of 3.. The sharpness of 3. is verified by using approximations of the function r Q 4 α/. If equality in 3. holds for some function f, then we must have R f + Q α Rf = 0 ERf = Q α Rf which implies that Rf is positively homogeneous of degree Q α/ by Lemma.. This will implies Rf = 0 since Rf/ +α is in L. Hence, so is f. Combining Theorem 3. and Theorem 3.3, we obtain some new weighted Rellich type inequalities. Theorem 3.4. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let k,l be nonnegative integers such that Q 4k + and k l+. Then for any complex-valued function f C0 \{0} and α R, we have R k f α = 4 Q α + k l k l c i+α Q 4i+α RR l f 4k l +α 4 R R l f + Q+ 4k l α RR l f 4k l +α R k R f +c k f k l α j + + c α i+α j= RR k f+ Q 4 α R k f +c α + k l j j= +α c i+α c j+α RR k j R k j R f +c k j f j+α 4j+α f+ Q 4 α 4j R k j f. +α+4j, 3.3 6

and RR k f α k l Q 4+α+i = 4 + Q α 4 + Q α 4 + Q α 4 k l k l j= +c +α Q α 4 + Q α 4 + c i++α RR l f 4k l+α R k R f +c k f +α k l j= RR k f + Q α j +α c i++α j R k f R R l f + Q+ 4k l α RR k f+ Q 6 α R k 4k l ++α RR l f R k j R f +c k j f j++α 4+α c i++α c j++α RR k j 4j++α f f+ Q 6 α 4j R k j f 4+α+4j α. 3.4 As a consequence, the following weighted Rellich type inequalities holds for any complexvalued function f C 0 \{0} k l 4 Q α Q 4i+α 4 RR l f 4k l +α R k f, 3.5 α for any α Q/,Q 4k l / if k l+ and α R if k = l +, and k l Q 4+α+i 4 RR l f 4k l+α RR k f, 3.6 α for any α Q+/,Q 4k l+/ if k l+ and α R if k = l+. Moreover, these inequalities 3.5 and 3.6 are sharp and equality holds if and only if f = 0. 7

Proof. We first prove 3.3. Denote g = R l+ f and apply 3.6 for R k l g and then apply Theorem 3.3 for R R l f, we get the desired equality 3.3. Here we use the equality Q+4k l +α k l c i+α = 4 Q α k l Q 4i+α. 4 To prove 3.4, we first apply. to RR k f and then use 3.3 for R k f with weights +α and the equality Q α Q+4k l ++α 4 4 k l c i++α = k l Q 4+α+i. 4 The inequalities 3.5 and 3.6 are implied from 3.3 and 3.4 respectively by dropping the nonnegative remainder terms. The sharpness of 3.5 and 3.6 is verified by using the approximations of the function r Q 4k α/ and the function r Q 4k α/ respectively. Suppose that equality holds in 3.5 for a function f. It follows from 3.3 that RR k f+ Q 4 α R k f = 0 ER k f = Q 4 α R k f. By Lemma., R k f is positively homogeneous of order Q 4 α/. Since R k f/ +α L, we then must have R k f = 0 which forces f = 0. Similar arguments work for 3.6. 4 Weighted L p Hardy Rellich type inequalities In this section, we establish the L p weighted Hardy Rellich type inequalities with p >, i.e., L p version of the inequalities obtained in Section 3. Throughout this section, we will use the following notation for p > and α R c p,α = Q p pαq+p α, p = p pp p, and d p,α = Q p+α. 4. p Let ξ,η C, denote R p ξ,η = p η p + p p ξ p R ξ p ξη. By the convexity of z z p, we see that R p ξ,η 0 and R p ξ,η = 0 if and only if ξ = η. If ξ,η R, we then have R p ξ,η = p 0 tξ + tη p tdt ξ η. 8

We start by establish a weighted version of.9, i.e., a weighted L p Hardy inequality on which will be frequently used in this section. Theorem 4.. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let < p < Q, and for any complex-valued function f C0 \{0}, we have Rf p = d p,α p f p f pα p+α+p pαr p d p,α,rf. 4. for any α R. As consequence, we obtain the L p weighted Hardy inequality d p,α p f p p+α Rf p, 4.3 pα for any α R such that Q p+α 0 and any complex-valued function f C 0 \{0}. The constant d p,α p is sharp and equality holds in 4.3 if and only if f = 0. The case α = 0, Theorem 4. recovers Theorem 3. in [45]. The case p = Theorem 4. recovers Theorem. of Ruzhansky and Suragan. Proof. Using the polar coordinate., we have f p p+α = r Q p+α fry p dσydr 0 S = r Q p+α fry p dσydr Q p+α 0 S p = Q p+α R r Q p+α fry p fryrfrydσydr 0 S p = Q p+α R fry p fry Rf p +α α = p f p p p Rf p p p+α+ p Q p+α pα f p Rf R p +α,. 4.4 Q p+α α The equality 4. is now derived from 4.4. The inequality 4.3 is an immediate consequence of 4.. The sharpness of 4.3 is verified by testing the approximations of the function r Q p+α/p. From 4. we see that equality holds in 4.3 if and only if R p Q p+α f p,rf = 0 9

or equivalently Rf = Q p+α p f Ef = Q p+α f. p By Lemma., f is positively homogeneous of order Q p+α/p which forces f = 0 since f / +α is in L p. We next prove a weighted L p Rellich inequality on which generalizes the inequality. to the weighted version and for any p,q/ and generalizes the inequality.7 to the setting of homogeneous groups. Theorem 4.. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let < p < Q/, and for any complex-valued function f C0 \{0}, we have R f p = c p,α p f p f pα p+α+p pαr p c p,α, R f +p c p,α p f c p,α p p Q p+α p+α R f + f p f p 4 IfRf +, 4.5 p+α for any α R, here Iz denotes the imagine part of a complex number z C. As a consequence, we obtain a weighted L p Rellich inequality in for any α p Q/p,Q p/p and any complex-valued function f C0 \{0} as follows c p p,α f p p+α R f p. 4.6 pα Moreover, the constant c p p,α is sharp and equality holds in 4.6 if and only if f = 0. 0

Proof. Using the polar coordinate., we have Q p+αq p+α+ f p p p+α = Q p+αq p+α+ r Q p+α fry p dσydr p 0 S = Q p+α+ r Q p+α fry p dσydr p 0 S = Q p+α+r r Q p+α fry p fryrfrydσydr 0 S = R r Q p+α+ fry p fryrfrydσydr 0 S = R r Q p+α+ p fry p 4 RfryRfry + fry p Rfry 0 S + fry p fryr fry dσydr = R p f p 4 RfRf + f p Rf + f p fr f p+α = R = R f p f R f p +α α Q R + 4p p +p f p frf p+α f p 4 RfRf + p+α f p f R f Q Q p+α p +α α+ p R f p p+α + f p 4 IfRf p+α f p p+α f p 4 IfRf p+α, 4.7 here we use integration by parts for the last equality. Applying Theorem. for f p, we have R f p Q p+α f p p+α = 4 p+α + Q p+α p+α R f p + f p.

Plugging this equality into 4.7, we obtain f p p+α = f p f R f R f p 4 IfRf c p,α p +α α c p,α p+α 4p Q p+α c p,α p p+α R f p + f p = p f p R f p f p p+α+ R R f p c p,α p pα p +α, c p,α α 4p Q p+α p c p,α p+α R f p + f p f p 4 IfRf. 4.8 c p,α p+α The equality 4.5 is now derived from 4.8 and the fact R f p = p f p R f. The inequality 4.6 is a direct consequence of 4.5 since c p,α > 0 under the condition of α. The sharpness of 4.6 is verified by using approximations of the function r Q p+α/p. Suppose that there is equality in 4.6 for some function f. From 4.5, we must have R f + Q p+α p f = 0 E f = Q p+α f. p Using Lemma. implies that f is positively homogeneous of degree Q p+α/p which forces f = 0 since f / +α is in L p. We next use Theorem 4. and Theorem 4. to establish the higher order versions of the weighted L p Hardy and weighted L p Rellich inequalities. It gives an L p analogue of the weighted L Hardy Rellich type inequalities obtained in Theorem 3.. It also gives the generalization of the inequalities.0 and. to the homogeneous groups. In order to do this, we first establish the following interesting equalities. Proposition 4.3. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let k be a positive integer, < p < Q/k and let α

be any real number. For any complex-valued function f C 0 \{0}, we have R l f p pα l p = c p,i+α l j p +p c p,i+α j= f p pk+α+p +p c p,α p c p,α [p pj+αr p + pαr p R l f p p+α R c l f p,α, Rl f R l j f c p,j+α, R l j f R Rl f + Q p+α p ] f R l f p 4 IR l f RR l p+α l j p [ +p c p,i+α c p,j+α p c p,j+α j= R l j f p +p pj++α R Rl j f + f R l R l j f p 4 IR l j f RR l j pj++α f Q pj ++α R l j p f ]. 4.9 3

if k = l,l, and RR l f p pα l p = d p,α p c p,i++α +p d p,α p p+αr p j f p l +p d p,α p p c p,i++α j= pk+α+p c p,+α R l f +p d p,α p c p,+α p c p,+α [p pαr p, Rl f pj++αr p + R l f p p3+α R l d f p,α,rrl f f c p,j++α R l j R Rl R l f p 4 IR l f RR l p3+α l j +p d p,α p p c p,i++α c p,j++α p c p,j++α j= [ R l j f p 4 IR l j f RR l j f R l j f p +p pj+3+α pj+3+α R Rl j, R l j f f + Q p3+α p ] f Q pj +3+α f + R l j f p f R l ]. 4.0 if k = l +,l with remark that the terms concerning the sum from to l do not appear if l =. Proof. The equality 4.9 is proved by using consecutively 4.5. The equality 4.0 is consequence of 4.9 and 4.. By dropping the nonnegative remainder terms in 4.9 and 4.0, we obtain the following higher order weighted L p Hardy-Rellich type inequalities. Theorem 4.4. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on and let α be any real number. For any complex-valued function f C0 \{0}, we have k p f p c p,i+α pk+α R k f p, 4. pα if < p < Q/k and α Qp /p,q pk/p, and k p d p f p p,α c p,i++α pk++α 4 RR k f p pα 4.

if < p < Q/k + and α Q+p /p,q pk +/p. The inequalities 4. and 4. are sharp and equality holds if and only if f = 0. Proof. The inequalities 4. and 4. are evidently consequences of 4.9 and 4.9 respectively since c p,i+α 0 and c p,i++α 0 for 0 i k in this case. The sharpness of the 4. and 4. is verified by approximating the function r Q pk+α/p and the function r Q pk++α/p respectively where. Moreover, if equality holds for a function f, then by Proposition 4.3, we must have that f is positive homogeneous of degree Q pk+α/p corresponding to 4. and Q pk++α/p corresponding to 4. which force f = 0 by the condition of L p integrability. Theorem 4.4 implies the following uncertainly principles. Corollary 4.5. Let k be a positive integer and p >. Let be a homogeneous group of homogeneous dimension Q > kp, and let be any homogeneous quasi-norm on. Then for any complex-valued function f C0 \{0}, we have l c p,i+α f R l f p p f p p l+α p 4.3 pα if k = l, l and for any α Qp /p,q pl/p, and d p,α l c p,i++α f RR l f p p f p p l++α p 4.4 c p,l++α pα if k = l+, l 0 and for any α Q+p /p,q pl+/p if l and for any α R if l = 0. Proof. We first prove 4.3. By Hölder inequality, we have f = f f p p l+α f l+α pl+α f p p l+α p. Now, applying the inequality 4. to the previous inequality, we get 4.3 with remark that c i+α > 0 for 0 i l for α Qp /p,q pl/p. The inequality 4.4 is proved by the similar way. Corollary 4.5 contains an uncertainly principle on the homogeneous group established by Ruzhansky and Suragan [45, Corollary 3.4] which corresponds to the case k = and α = 0. For the other cases, the inequalities in Corollary 4.5 seem to be new. We next establish a L p version of Theorem 3.3 for p,q/. To do this, we will need the following equality. 5

Proposition 4.6. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let be any homogeneous quasi-norm on and < p < Q. Then for any complex-valued function f C0 \{0}, we have Q p Rf + f pα = Q+p α p p p r f p p+α+p for any α R with p = p/p. Q+p α pαr p p f Q,Rf + f 4.5 Proof. Using the polar coordinate., we have f p p+α = r Q p+α fry p dσydr 0 S = r Q p+α fry p dσydr Q p+α 0 S p = Q p+α R r Q p+α fry p fryrfrydσydy 0 S p = Q p+α R f p f Rf p+α p f = R p Q f Rf + f f p Q Q p+α p +α α This equality implies f p p+α = p Q+p α R f p f Rf + p +α α = p f p p p p p+α+ p Q+p α p f p R p +α, Q+p α which yields our desired result 4.5. Q f Rf + Q f α p+α Q pα Rf + f Using Lemma 4.6, we get the following L p analogue of Theorem 3.3. Theorem 4.7. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let be any homogeneous quasi-norm on and < p < Q/. Then for any complex-valued function f C0 \{0}, we have R f p = Q+p α p Rf p Q+p αrf pα p p p+α+p pαr p p,r f 4.6 6.

for any α R. As consequence, we obtain the following weighted L p Rellich type inequality Q+p α p Rf p p p p+α R f p, 4.7 pα for any α R and for any complex-valued function f C0 \ {0}. Moreover, the inequality 4.7 is sharp and equality holds if and only if f = 0. Proof. The equality 4.6 is exactly 4.5 with f being replaced by Rf. The inequality 4.7 is immediately implies from 4.6 by dropping the nonnegative remainder term on the right hand side of 4.6. The sharpness of 4.7 is proved by using approximations of the function r Q p+α/p. If equality occurs in 4.7 by a function f, then by 4.6, we must have R f = Q+p α Rf, p which is equivalent to R f + Q p+α p Rf = 0 ERf = Q p+α Rf. p Hence Rf is positively homogeneous of degree Q p+α/p, by Lemma., which forces Rf = 0 since Rf/ +α is in L p. Thus, we get f = 0. Combining Theorem 4.7 andtheorem 4.3, we obtainthe following weighted L p Rellich type inequality which is a L p analogue of Theorem 3.4. Theorem 4.8. Let be a homogeneous group of homogeneous dimension Q. Let be any homogeneous quasi-norm on. Let k,l be nonnegative integers such that k l + and let p >. Then for any α R and for any complex-valued function f C 0 \{0}, 7

we have R k f p pα p p k l = Q pα p k l p +p c p,i+α R R p c k p,α +p pα +p k l j= j p c p,i+α Q pi+αq+p i+α pp R p Q+p k l +α p f,r k f +p c p,α p c p,α [p + pk l +α R p c p,j+α R k j R k f p p+α p RR l f,r l+ f f pj+α R Rk,R k j f RR l f p pk l +α f + Q p+α p ] f R k f p 4 IR k f RR k p+α k l j p [ +p c p,i+α c p,j+α p c p,j+α j= R k j f p +p pj++α R Rk j f + f R k R k j f p 4 IR k j f RR k j pj++α f Q pj ++α R k j p f ], 4.8 8

and RR k f p pα k l Q pi++αq+p i++α p = pp k l +p d p,α p +p d p,α p k l +p d p,α p j= c p,i++α p R R p c k f p,+α,r k f p+α j p c p,i++α R p Q+p k l +α p pk l +α R p c p,j++α R k j RR l f p pk l+α RR l f,r l+ f f pj++α,r k j f [ +p d p,α p c p,+α p R k f p 4 IR k f RR k f c p,+α p3+α R k f p +p p3+α R Rk f + Q p3+α p k l j +p d p,α p p c p,i++α c p,j++α p c p,j++α j= [ R k j f p 4 IR k j f RR k j f +p p pαr p pj+++α R k j f p pj+++α R Rk j Q p pα p R k f,rrk f f R k ] Q pj ++α f + R k j f p. 4.9 As a consequence, the following weighted L p Rellich type inequalities holds for any function f C0 \{0} p p k l Q pi+αq+p i+α p RR l f p Q pα p pp pk l +α R k f p, pα 4.0 for any α Qp /p,q pk l / if k l and for any α R if k = l+, ] 9

and k l Q pi++αq+p i++α pp p RR l f p pk l +α RR k f p, pα 4. for any α Q+p /p,q pk l +/p if k l and for any α R if k = l +. Moreover, these inequalities 4.0 and 4. are sharp and equality holds if and only if f = 0. 5 The critical Rellich type inequalities This section is devoted to study the critical Rellich inequalities. Let us start by recalling a family of logarithmic Hardy inequalities in [43]. Proposition 5.. Let be a homogeneous group of homogeneous dimension Q and a homogeneous quasi-norm denoted by. Let f C0 \ {0} be any complex-valued function and denote f R x = frx/ with x and R > 0. Then we have Rf p Q p = p p p +p f f R p ln Q R p p f f R,Rf p ln R 5. Q pr p for any < p < and any R > 0. As a consequence, we obtain the following critical Hardy inequality on, p p f f R p Rf sup p p R>0 ln Q R p Q p, < p <, 5. any complex-valued function f C 0 \ {0}. Moreover, the constant p /pp is sharp. Our main aim of this section is to extend the critical Hardy inequality 5. to the higher order derivatives, i.e., to establish the critical Rellich type inequalities on. To do this, we first prove a critical Rellich inequality for R as follows. Theorem 5.. Let be a homogeneous group of homogeneous dimension Q 3 and a homogeneous quasi-norm denoted by. Let f C0 \ {0} be any complex-valued function and denote f R x = frx/ with x and R > 0. Then we have R f p p Q Q p = f f R p p ln Q R p +p Q pr p Q Rf,R f +pq p Q pr p p f f R,Rf, 5.3 p ln R 30

for any < p < and any R > 0. As a consequence, we obtain the following critical Rellich inequality on, p Q f f R p R sup f p p R>0 ln Q R p Q p, < p <, 5.4 any complex-valued function f C 0 \ {0}. Moreover, the constant Q /p p is sharp. Proof. It follows from Theorem 4.7 for α = Q p/p that R f p Rf p Q p = Q p Q p+p Q pr p Q Rf,R f Plugging 5. into the previous equality, we obtain 5.3. The inequality 5.4 is an immediate consequence of 5.3. It remains to check the sharpness of 5.4. For ǫ,δ > 0 small enough and R >, define the function f δ x = ln R p δ φ, where φ is the function as in the proof of Theorem 3.. By the direct computations, we have and R f δ r = + Rf δ r = p δ ln R p δ φr+ ln R p δ φ r r r r p δ r ln R p δ φ r p p r r δ +δ ln R p δ φr r p r δ ln R p δ φr+ ln R p δ φ r r r Thus, we obtain R f δ r = p δ r ln R p δ φ r Q p r r δ ln R p δ φr r p p r δ +δ ln R p δ φr+ ln R p δ R φr. r r 3

Evidently, f δ R = 0 and f δ f δ R p ln Q R p = σs Hence It is easy to check that and Q p Consequently, we get Q p Q p Q p lim δ 0 ln R lim δ 0 This proves the sharpness of 5.4. 0 r lnr lnr δp φr p dr σs 0 r lnr lnr δp dr = δp lnr pδ S. f δ f δ R p ln Q R p =. ln R ln R ln R p δ φ p R f δ p Q p f δ f δ R p Q ln p = R p δ φ p = O, p δ p φ = O, p δ p R φ = O, = σs 0 r lnr lnr pδ φrdr f δ f δ R = p ln Q R p. p Q. We next combine Theorem 5. together with Theorem 4. and Theorem 4.3 to establish the critical Hardy Rellich type inequalities of higher orders. Denote Then the following equalities holds true. p a j,q = jq j. 3

Proposition 5.3. Let be a homogeneous group of homogeneous dimension Q and a homogeneous quasi-norm denoted by. Let f C0 \ {0} be any complex-valued function and denote f R x = frx/ with x and R > 0. Then we have for any R > 0, R k f p Q kp p k p Q = a i,q +p p k i= p a i,q i= k p +pq p a i,q +p k k +p j= +pa p k,q i= Q kpr p i=k j l k +p j= +p f f R p ln Q R p Q pr p Q Rf Q pr p a k,q R k f a i,q p [ p i=k j,r k f Q k jpr p R k f p,r f p f f R,Rf p ln R Q k p R Rk + a k i,q p a p k j,q R k j f p Q k j p f a k j,q R k j f + R k f p 4 IR k f RR k [ Q k p R Rk j,r k j f k R k f ] f Q k j p R k j f p 4 IR k j f RR k j f Q pj ++α f + R k j f p ] 5.5 33

if k < Q/, and RR k f p Q k+p = k p Q p p k p a i,q i= k p +pk p a i,q i= k p +pk p Q p a i,q +pk p k +pk p i= Q kpr p j= k i=k j f f R p ln Q R p Q pr p Q Rf Q pr p a k,q R k f a i,q p [ +pk p a p k,q p k +pk p j= +p k i=k j +p if k < Q /. +,R k f Q k jpr p R k f p Q k p,r f p f f R,Rf p ln R R Rk R k j f a k j,q,r k j f k f + ] f R k f p 4 IR k f RR k a k i,q p a p k j,q R k j f p Q k j p R Rk j Q k+pr p Q k p [ f + k Rk f,rrk f f R k Q k j p R k j f p 4 IR k j f RR k j f ] Q pj ++α R k j f p, 5.6 Proof. We first prove 5.5. Denote g = R f. Applying 4.9 to the function g and l = k, and then using 5.3, we obtain 5.5. We next prove 5.6. Using Theorem 4. with α = Q k +p/p we get RR k f p Q k+p = kp R k f p Q kp+p Q k+pr p Combining the previous equality together with 5.5 implies 5.6. k Rk f,rrk f. By dropping the nonnegative remainder terms, Proposition 5.3 yields the following critical Hardy Rellich type inequalities on which are extensions of the critical Hardy inequality 5. and the critical Rellich inequality 5.4 to higher order of derivatives. 34

Theorem 5.4. Let be a homogeneous group of homogeneous dimension Q and a homogeneous quasi-norm denoted by. Let f C0 \{0} be any complex-valued function and denote f R x = frx/ with x and R > 0. Then we have k k p k! Q i sup p R>0 for any k < Q/ and for any p >, and k k p k! Q i sup p R>0 f f R p ln Q R p f f R p ln Q R p R k f p Q kp, 5.7 RR k f p Q k+p, 5.8 for any k Q / and for any p >. Moreover, the inequalities 5.7 and 5.8 are sharp. Proof. Obviously that a i,q 0 for i k, hence the inequalities 5.7 and 5.8 are immediate consequence of 5.5 and 5.6 respectively with the remark that and p k p Q a i,q = p i= p k p Q k p a p i,q = i= k k k! p k k k! p Q i p, Q i p. To verify the sharpness of 5.7 and 5.8, we consider the test functions f δ x = ln R p δ φ, as used in the proof of Theorem 5. and make the same computations. We skip the slightly tedious details. Theorem 5.4 implies the following uncertainly type principles Corollary 5.5. Let be a homogeneous group of homogeneous dimension Q and let be any homogeneous quasi-norm on. Let k be a positive integer less than Q. Then for any f C0 \{0}, any R > 0 and p,q > such that /p+/q = /, we have l l! p l Q i f f f R Q p ln R 35 f L q R l f p p Q lp 5.9

if k = l, l and l l l! Q i p f f f R Q p ln R f Lq RR l f p p Q l+p 5.0 if k = l+, l 0. Also, we have for any complex-valued function f C 0 \{0} l l! p l Q i if k = l, l, and l l! p l Q i if k = l+, l 0. f f R Q ln R f f R Q ln R R l f p p Q lp RR l f p p Q l+p f f R p p Q ln R p 5. f f R p p Q ln R p 5. Proof. These inequalities are consequence of Theorem 5.4 and Hölder inequality. Again, Corollary 5.5 contains a uncertainly type principle on the homogeneous group recently proved by Ruzhansky and Suragan [43, Corollary 3.] corresponding to the case k =. Corollary 5.5 provides an extension of their result to the higher order derivative. 6 The inequalities in the Euclidean space We restrict ourselves in this section to the Euclidean space, i.e., the abelian case = R n,+ and Q = n. Let denote the usual Euclidean norm on R n. In this case, R is exactly the derivative in the radial direction, i.e., r, and R = r + n r =: r r 36

to be the radial Laplacian. In the sequel, we collect some inequalities obtained from previous sections when restricting to the Euclidean space R n. Firstly, Theorem 3. gives k f c i+α R 4k+α n Rn k r = f k α R n α k r f rf +c α k j c i+α k j j= R n 4j+α k j r f r f +c j+α c α n r n α 4 r k f R n k j j= c i+α c j+α R n n r n α 4 4j k j r f, 6. and k n α f c i++α R 4k++α n Rn r k r = f n α r n α k rf R n n α 4 R n +α k r f +c r k f +α n α k j c i+α k j 4 j= R n +α+4j k j r f r f +c j++α n α c +α n r n α 6 k r f R n n α k j c i++α c j++α n r n α 6 4j k j r f j= R n 6. for any function f C 0 Rn \ {0}. The equality 6. with k = α = 0 was proved by Machihara, Ozawa and Wadade in [34]. The equality 6. with k = and α = 0 was proved by these same authors in [35]. We believe that the other cases of 6. and 6. to be new. Evidently, 6. and 6. imply the following weighted L -Hardy Rellich type inequalities k n+4i+αn 4i α 4 f Rn 4 R 4k+α k r f 6.3 n α 37

for n 4k +, α n/,n 4k/, and k n α n+4i++αn 4i 6 α f 4 R 4k++α n Rn r k r f α 6.4 for n 4k+3, α n+/,n 4k /. It is easy to see that r f f. This together with 6.4 gives a simple proof of the classical L -Hardy inequality.. For j n, we denote by L j a spherical derivative, i.e., It was proved in [35] that L j = j x j r = j f L R n = rf L R n + L j f + j= L R n rl j f + n L j f j= k= L R n x j x k k. + nn 4 L jf j= L R n, 6.5 for n 5 which implies r f L R n f L R n with equality holds if and only if f is radial function. Again, this estimate together with 6.3 gives a simple proof of the classical L Rellich inequality.6. The next result gives an expression of f L R n in the spirit of 6.5. Theorem 6.. Let n 7. Then the following equality holds for all function f H 3 R n : f = r r f + R n R n R r Ljf + L j f n j= j= R n n 4n 4 Rn L j f + +n 3n 7 4 4 j= + n 4 n n r L j f j= R n + n r n r L j f. 6.6 R n j= As a consequence, we obtain f r r f, 6.7 R n R n with equality holds if and only if f is radial function. 38

Combining 6.7 with 6.4 for k =, we obtain a simple proof of the Rellich type inequality for n 7 n 6 n n+ Rn f 64 6 f R n which is a special case of.9 with m =. It would be interesting to find an analogues of Theorem 6. for the higher order derivatives. Such a result combining with 6.3 or 6.4 would give a simple proof of the Hardy Rellich type inequalities.8 and.9. Let us go to the proof of Theorem 6.. Proof of Theorem 6.. It is enough to prove 6.6 for function f C0 R n \ {0} by the density argument. Notice that = r + L j, which can be verified by some simple computations. Expanding the scalar product, we have f = r f + L j f R n R n j= R n = R r r f + r L j + f L j f n j= j= R n = r r f + R n R r L j f n j= +Re r r f r L j + f L j f. 6.8 R n R n Our next goal is to compute j= j= Re r r f r L j. f R n j= Denote h j = L j f,j =,,...,n and g = r f. Using integration by parts, we have R n r g r j= We can readily check that r L j = L j r L j /, and j= L j f = g r L j. f 6.9 R n j= r L j = L j r L j r n 3 L j, 39

Since n j= x jl j = 0, then x j r L j = j= x j r L j = 0. j= Using integration by parts and the fact L j a u = a L j u, we get g r L j f = R n j= j= = R n g j= L j r h j L j r h j n 3 R L j g Notice that L j r = r L j + r L j /+n L j /, hence L jh j r h j rh j n 3 h j. L j g = L j r f = r L j + rl j + n L jf = r h j + rh j + n h j. This expression of L j g implies Re g r L j f R n = = = Re j= j= j= R n R n j= R n r h j + rh j + n h j r h j rh j n 3 h j r h j 4 rh j n n 3 4 h j 4n Re j= r h j h j R n 3 r h j 4 rh j n n 3 4 h j n 3 r h j h j Re. R n 3 j= + + j= j= r h j h j Re R n Rn r Re h jh j 40

Using integration by parts, we obtain Re g r L j f = R n j= = = j= j= j= R n R n R n r h j 6 rh j n n 3 h 4 j r h j h j 4n 3 Re j= R n 3 r h j 6 rh j n n 3 h 4 j +n 3n 4 j= Rn h j 4 r h j 6 rh j + n 3n 7 4 h j. Applying Theorem 3.3 to = R n,+ with theeuclidean norm andthe integral of r h j, we obtain Re g r L j f = n 4 Rn r h j Rn h j n 3n 7 R 4 n 4 j= j= j= n r n r h j. 6.0 R n j= Using 6. for k = 0, α =, we have Rn r h j = n 4 4 Rn h j + n 4 r n h j. 6. R n Plugging 6., 6.0 and 6.9 into 6.8 implies our desired equality 6.6. The inequality 6.7 is an immediate consequence of 6.6 since n 7. Moreover, if f is radial then equality holds since L j f = 0 for all j =,,...,n. Conversely, suppose that equality holds in 6.7. Since n 4n 4 +n 3n 7 > 0, 4 4 for any n 7, then we must have L j f = 0 for all j =,,...,n. In particular, we get x k j fx = x kx j rfx = x j k fx, for any j,k =,,...,n. This fact implies that f is radial function. 4

Next, Theorem 4.4 gives the following weighted L p Hardy Rellich type inequalities on R n. k p n+p i+αn pi++α pp R n f p pk+α if < p < n/k and α np /p,n pk/p, and n p+α p p p k p n+p i++αn pi+3+α pp R n Rn k rf p, 6. pα f p pk++α Rn r k r f p pα 6.3 if < p < n/k + and α n+p /p,n pk +/p. Similarly, Theorem 4.7 gives the following weighted L p -Rellich type inequality n+p α p p p Rn r f p Rn p+α r f p, 6.4 pα for any α R. The inequalities 6., 6.3 and 6.4 seem to be new in the Euclidean space R n. Finally, Theorem 5. and Theorem 5.4 give some new critical Hardy Rellich type inequalities in R n as follows k k k! p n i p sup R>0 Rn f f R p Rn k ln n R p for any k < n/ and any p >, and k k p k! n i Rn f f R sup p p R>0 ln n R p Rn r k rf p rf p n kp, 6.5 n k+p, 6.6 for any 0 k < n / and any p >. The inequality 6.6 was first proved by Ioku, Ishiwata and Ozawa [8] in the case k = 0 andp = nandthen was extended by Ruzhansky andsuragan[43] forany p,. Especially, consider the case p = then 6.5 and 6.6 become k k! sup R>0 Rn f f R ln n R k rf, 6.7 R n if n = 4k and k k! sup R>0 Rn f f R ln n R r k rf, 6.8 R n 4