3.1 Paley inequality for commutative hypergroups

In this subsection, we prove the Paley inequality for commutative hypergroups. The Paley inequality has been proved for many different settings, for example, compact homogeneous spaces [Reference Akylzhanov, Nursultanov and Ruzhansky2, Reference Akylzhanov, Nursultanov and Ruzhansky3], compact quantum groups [Reference Akylzhanov, Majid and Ruzhansky1, Reference Youn43], compact hypergroups [Reference Kumar and Ruzhansky32], generalised Fourier transforms [Reference Kumar and Ruzhansky33] and locally compact groups [Reference Akylzhanov and Ruzhansky4].

The Paley inequality is an important inequality in itself but also plays a vital role in obtaining the Hausdorff–Young–Paley inequality for commutative hypergroups. We follow the strategy of the proof of the Paley inequality in [Reference Akylzhanov and Ruzhansky4] in the noncommutative setting.

Theorem 3.1. Let H be a commutative hypergroup equipped with a Haar measure $\lambda $ and let $\widehat {H}$ be the dual of H equipped with measure $\pi .$ Suppose that $\psi $ is a positive function on $\widehat {H}$ satisfying the condition

$$ \begin{align*} M_\psi := \sup_{t>0} t \int_{\underset{\psi(\chi)\geq t}{\chi \in \widehat{H}}} \,d\pi(\chi) <\infty. \end{align*} $$

Then for $f \in L^p(H, d\lambda ),\ 1<p\leq 2,$

(3-1) $$ \begin{align} \bigg( \int_{\widehat{H}} |\widehat{f}(\chi)|^p\, \psi(\chi)^{2-p} \,d\pi(\chi) \bigg)^{{1}/{p}} \lesssim M_{\psi}^{({2-p})/{p}}\, \|f\|_{\,L^p(H, d\lambda)}. \end{align} $$

Proof. Let us consider a measure $\nu $ on $\widehat {H}$ given by

(3-2) $$ \begin{align} \nu(\chi)= \psi(\chi)^2 \,d\pi(\chi). \end{align} $$

We define the corresponding $L^p(\widehat {H}, \nu )$ -space, $1 \leq p<\infty ,$ as the space of all complex-valued functions f defined by $\widehat {H}$ such that

$$ \begin{align*} \|f\|_{\,L^p(\widehat{H}, \nu)}:= \bigg( \int_{\widehat{H}} |f(\chi)|^p \, \psi(\chi)^2 \,d\pi(\chi) \bigg)^{{1}/{p}}<\infty.\end{align*} $$

We define a sublinear operator T for $f \in L^p(H, d\lambda )$ by

$$ \begin{align*} Tf(\chi):= \frac{|\widehat{f}(\chi)|}{\psi(\chi)} \in L^p(\widehat{H}, \nu).\end{align*} $$

We show that T is well-defined and bounded from $L^p(H, d\lambda )$ to $L^p(\widehat {H}, \nu )$ for any ${1 < p \leq 2}$ . In other words, we claim the following estimate:

(3-3) $$ \begin{align} \|Tf\|_{\,L^p(\widehat{H}, \nu)}= \bigg( \int_{\widehat{H}} \frac{|\widehat{f}(\chi)|^p}{\psi(\chi)^p}\,\psi(\chi)^2 \,d\pi(\chi) \bigg)^{{1}/{p}} \lesssim M_{\psi}^{({2-p})/{p}} \|f\|_{\,L^p(H, d \lambda)}, \end{align} $$

which gives us the required inequality (3-1) with $M_\psi := \sup _{t>0} \int _{\underset {\psi (\chi ) \geq t}{\chi \in \widehat {H}}} d\pi (\lambda ).$ We show that T is weak-type $(2,2)$ and weak-type $(1,1).$ More precisely, with the distribution function,

$$ \begin{align*}\nu(y; Tf)= \int_{\underset{\frac{|\widehat{f}(\chi)|} {\psi(\chi)} \geq y}{\chi \in \widehat{H}}} \psi(\chi)^2 \,d\pi(\chi), \end{align*} $$

where $\nu $ is given by (3-2), we show that

(3-4) $$ \begin{align} \nu(y; Tf) \leq \bigg( \frac{M_2 \|f\|_{\,L^2(H, d\lambda)}}{y} \bigg)^2 \quad\text{with norm } M_2=1, \end{align} $$

(3-5) $$ \begin{align} \nu(y; Tf) \leq \frac{M_1 \|f\|_{\,L^1(H, d\lambda)}}{y}\quad\text{with norm } M_1=M_\psi. \end{align} $$

Then the estimate (3-3) follows from the Marcinkiewicz interpolation theorem. Now, we show (3-4). Using the Plancherel identity,

$$ \begin{align*} y^2 \nu(y; Tf) &\leq \sup_{y>0}y^2 \nu(y; Tf)=: \|Tf\|^2_{L^{2, \infty}(\widehat{H}, \nu)} \leq \|Tf\|^2_{L^2(\widehat{H}, \nu)} \\&= \int_{\widehat{H}} \bigg( \frac{|\widehat{f}(\chi)|}{\psi(\chi)} \bigg)^2 \psi(\chi)^2 \,d\pi(\chi) \\&= \int_{\widehat{H}} |\widehat{f}(\chi)|^2 \,d\pi(\chi) = \|f\|_2^2. \end{align*} $$

Thus, T is type $(2,2)$ with norm $M_2 \leq 1.$ Further, we show that T is of weak type $(1,1)$ with norm $M_1=M_\psi $ ; more precisely, we show that

(3-6) $$ \begin{align} \nu \bigg\{ \chi \in \widehat{H}: \frac{|\widehat{f}(\chi)|}{\psi(\chi)}>y \bigg\} \lesssim M_\psi \frac{\|f\|_{\,L^1(H, \,d\lambda)}}{y}. \end{align} $$

The left-hand side is an integral $ \int \psi (\chi ) \,d\pi (\chi )$ taken over all those $\chi \in \widehat {H}$ for which ${|\widehat {f}(\chi )|}/{\psi (\chi )}>y.$ Since $|\widehat {f}(\chi )| \leq \|f\|_1$ for all $\chi \in \widehat {H}$ ,

$$ \begin{align*}\bigg\{ \chi \in \widehat{H}: \frac{|\widehat{f}(\chi)|}{\psi(\chi)}>y \bigg\} \subset \bigg\{ \chi \in \widehat{H}: \frac{\|f\|_1}{\psi(\chi)}>y \bigg\}\end{align*} $$

for any $y>0$ and, therefore,

$$ \begin{align*}\nu \bigg\{ \chi \in \widehat{H}: \frac{|\widehat{f}(\chi)|}{\psi(\chi)}>y \bigg\} \leq \nu \bigg\{ \chi \in \widehat{H}: \frac{\|f\|_1}{\psi(\chi)}>y \bigg\}.\end{align*} $$

Now by setting $w:={\|f\|_1}/{y},$

$$ \begin{align*} \nu \bigg\{ \chi \in \widehat{H}: \frac{\|f\|_1}{\psi(\chi)}>y \bigg\} \leq \int_{\overset{\chi \in \widehat{H}}{\psi(\chi) \leq w} } \psi(\chi)^2\, \,d\pi(\chi). \end{align*} $$

Now we claim that

(3-7) $$ \begin{align} \int_{\overset{\chi \in \widehat{H}}{\psi(\chi) \leq w}} \psi(\chi)^2 d\pi(\chi) \lesssim M_\psi w. \end{align} $$

Indeed, first we notice that

$$ \begin{align*} \int_{\overset{\chi \in \widehat{H}}{\psi(\chi) \leq w} } \psi(\chi)^2 \,d\pi(\chi) = \int_{\overset{\chi \in \widehat{H}}{\psi(\chi) \leq w} } d\pi(\chi) \int_0^{\psi(\chi)^2} d\tau. \end{align*} $$

By interchanging the order of integration,

$$ \begin{align*} \int_{\overset{\chi \in \widehat{H}}{\psi(\chi) \leq w} } d\pi(\chi) \int_0^{\psi(\chi)^2} d\tau = \int_{0}^{w^2} d\tau \int_{\underset{\tau^{{1}/{2}} \leq \psi(\chi) \leq w}{\chi \in \widehat{H}}} d\pi(\chi). \end{align*} $$

Further, by making substitution $\tau = t^2,$

$$ \begin{align*} \int_{0}^{w^2} d\tau \int_{\underset{\tau^{{1}/{2}} \leq \psi(\chi) \leq w}{\chi \in \widehat{H}}} d\pi(\chi) &= 2 \int_0^w t\, dt \int_{\underset{t \leq \psi(\chi) \leq w}{\chi \in \widehat{H}}} d\pi(\chi) \\&\leq 2 \int_0^w t\, dt \int_{\underset{t \leq \psi(\chi) }{\chi \in \widehat{H}}} d\pi(\chi). \end{align*} $$

Since

$$ \begin{align*} t \int_{\underset{t \leq \psi(\chi) }{\chi \in \widehat{H}}} d\pi(\chi) \leq \sup_{t>0} t \int_{\underset{t \leq \psi(\chi) }{\chi \in \widehat{H}}} d\pi(\chi) = M_\psi \end{align*} $$

is finite by the assumption that $M_\psi <\infty ,$

$$ \begin{align*} 2 \int_0^w t\, dt \int_{\underset{t \leq \psi(\chi) }{\chi \in \widehat{H}}} d\pi(\chi) \lesssim M_\psi w. \end{align*} $$

This establishes our claim (3-7) and eventually proves (3-6). So, we have proved (3-4) and (3-5). Then by using the Marcinkiewicz interpolation theorem with $p_1=1$ and $p_2=2$ , and ${1}/{p}= 1-\theta +{\theta }/{2}$ , we now obtain

$$ \begin{align*}\bigg( \int_{\widehat{H}} \bigg(\frac{|\widehat{f}(\chi)|}{\psi(\chi)} \bigg)^p \psi(\chi)^2 \,d\pi(\chi) \bigg)^{{1}/{p}}= \|Tf\|_{\,L^p(\widehat{H},\, \nu)} \lesssim M_\psi^{({2-p})/{p}} \|f\|_{\,L^p(H, d\lambda)}.\end{align*} $$

This completes the proof of the theorem.

3.2 Hausdorff–Young–Paley inequality for commutative hypergroups

In this subsection, we prove the Hausdorff–Young–Paley inequality for commutative hypergroups. The Hausdorff–Young–Paley inequality is an important inequality in itself but it serves as an essential tool to prove the $L^p$ – $L^q$ Fourier multiplier for commutative hypergroups. The following theorem [Reference Bergh and Lofstrom9] is useful to obtain our result.

Theorem 3.2. Let $d\mu _0(x)= \omega _0(x) d\mu '(x),\ d\mu _1(x)= \omega _1(x) d\mu '(x)$ and write $L^p(\omega )= L^p(\omega d\mu ')$ for the weight $\omega .$ Suppose that $0<p_0, p_1< \infty .$ Then,

$$ \begin{align*}(L^{p_0}(\omega_0), L^{p_1}(\omega_1))_{\theta, p}=L^p(\omega),\end{align*} $$

where $0<\theta <1, \, {1}/{p}= ({1-\theta })/{p_0}+{\theta }/{p_1}$ and $\omega = \omega _0^{{p(1-\theta )}/{p_0}} \omega _1^{{p\theta }/{p_1}}.$

The following corollary is immediate.

Using the above corollary, we now present the Hausdorff–Young–Paley inequality.

Theorem 3.4 (Hausdorff–Young–Paley inequality).

Let H be a commutative hypergroup equipped with a Haar measure $\lambda $ and let $\widehat {H}$ be the dual of H equipped with measure $\pi .$ Let $1<p\leq 2$ and let $1<p \leq b \leq p' < \infty ,$ where $p'= {p}/({p-1}).$ If $\psi (\chi )$ is a positive function on $\widehat {H}$ such that

$$ \begin{align*} M_\psi := \sup_{t>0} t \int_{\underset{\psi(\chi)\geq t}{\chi \in \widehat{H}}} \,d\pi(\chi) \end{align*} $$

is finite, then for every $f \in L^p(H, d\lambda )$ ,

$$ \begin{align*} \bigg( \int_{\widehat{H}} ( |\widehat{f}(\chi)| \psi(\chi)^{{1}/{b}-{1}/{p'}} )^b \,d\pi(\chi) \bigg)^{{1}/{b}} \lesssim M_\psi^{{1}/{b}-{1}/{p'}} \|f\|_{\,L^p(H, d\lambda)}. \end{align*} $$

This naturally reduces to the Hausdorff–Young inequality when $b=p'$ and to the Paley inequality (3-1) when $b=p$ .

Proof. From Theorem 3.1, the operator defined by

$$ \begin{align*}Af(\chi)= \widehat{f}(\chi),\,\,\,\,\chi \in \widehat{H}\end{align*} $$

is bounded from $L^p(H, d\lambda )$ to $L^{p}(\widehat {H},\omega _0 d\mu '),$ where $d\mu '(\chi )=\,d\pi (\chi )$ and $\omega _{0}(\chi )= \psi (\chi )^{2-p}$ . From Theorem 2.2, we deduce that $A:L^p(H, d\lambda ) \rightarrow L^{p'}(\widehat {H}, \omega _1 d\mu ')$ with $d\mu '(\chi )=\,d\pi (\chi )$ , and $\omega _1(\chi )= 1$ admits a bounded extension. By using the real interpolation (Corollary 3.3), we prove that $A:L^p(H, d\lambda ) \rightarrow L^{b}(\widehat {H}, \omega d\mu '),\ p\leq b\leq p',$ is bounded, where the space $L^b(\widehat {H},\, \omega d\mu ')$ is defined by the norm

$$ \begin{align*}\|\sigma\|_{\,L^b(\widehat{H},\, \omega d\mu')}:=\bigg( \int_{\widehat{H}} |\sigma(\chi)|^b w(\chi) \,d\mu'(\chi) \bigg)^{{1}/{b}}= \bigg( \int_{\widehat{H} } |\sigma(\chi)|^b w(\chi) \,d\pi(\chi) \bigg)^{{1}/{b}}\end{align*} $$

and $\omega (\chi )$ is a positive function over $\widehat {H}$ to be determined. To compute $\omega ,$ we can use Corollary 3.3 by fixing $\theta \in (0,1)$ such that ${1}/{b}=({1-\theta })/{p}+{\theta }/{p'}$ . In this case, ${\theta =({p-b})/{b(p-2)}}$ and

$$ \begin{align*} \omega= \omega_0^{{b(1-\theta)}/{p}} \omega_1^{{b\theta}/{p'}}= \psi(\chi)^{1-{b}/{p'}}. \end{align*} $$

Thus, we finish the proof.

3.3 $L^p$ – $L^q$ boundedness of Fourier multipliers on commutative hypergroups

We begin with the definition of Fourier multipliers on commutative hypergroups. For a function $h \in L^\infty (\widehat {H}, d\pi ),$ define the operator $T_h$ as

$$ \begin{align*}\widehat{T_hf}(\chi)=h(\chi) \widehat{f}(\chi),\quad \chi \in \widehat{H},\end{align*} $$

for all f belonging to a suitable function space on $\widehat {H}.$ The operator $T_h$ is called the Fourier multiplier on H with symbol $h.$ It is clear that $T_h$ is a bounded operator on $L^2(H, d\lambda )$ by the Plancherel theorem. A Fourier multiplier commutes with the translation operators. In fact, the Fourier multipliers can be characterised using translation operators [Reference Bloom and Heyer12, Reference Kumar, Sarma and Shravan Kumar34, Reference Sarma, Shravan Kumar and Kumar38].

In the next result, we show that if the symbol h of a Fourier multiplier A defined on $C_c(H)$ satisfies a certain Hörmander’s condition, then $T_h$ can be extended as a bounded linear operator from $L^p(H, d\lambda )$ to $L^q(H, d\lambda )$ for the range $1<p \leq 2 \leq q <\infty .$

Theorem 3.5. Let $1<p\leq 2 \leq q<\infty $ and let H be a commutative hypergroup. Suppose that T is a Fourier multiplier with symbol $h.$ Then,

(3-8) $$ \begin{align} \|T\|_{\,L^p(H,\, d\lambda) \rightarrow L^q(H,\, d\lambda)}\lesssim \sup_{s>0} s \bigg[ \int_{\{ \chi \in \widehat{H}: |h(\chi)|\geq s\}} \,d\pi(\chi) \bigg]^{{1}/{p}-{1}/{q}}. \end{align} $$

Proof. Since for $p=q=2$ the inequality (3-8) always holds, we assume that ${1<p \leq 2 \leq q<\infty} $ with p and q both not equal to $2$ . Let us first assume that $p \leq q',$ where ${1}/{q}+{1}/{q'}=1.$ Since $q' \leq 2,$ dualising the Hausdorff–Young inequality gives that

$$ \begin{align*} \|Tf\|_{\,L^q(H,\, d\lambda)} \leq \|\widehat{Tf}\|_{\,L^{q'}(\widehat{H}, \, d\pi)} = \|h \widehat{f}\|_{\,L^{q'}(\widehat{H}, d\pi)}. \end{align*} $$

The case $q' \leq (p')'=p$ can be reduced to the case $p \leq q'$ as follows. Using the duality of $L^p$ -spaces, we have $\|T\|_{\,L^p(H,\, d\lambda ) \rightarrow L^q(H,\, d\lambda )}= \|T^*\|_{\,L^{q'}(H,\, d\lambda ) \rightarrow L^{p'}(H,\, d\lambda )}.$ The symbol of adjoint operator $T^*$ is equal to $\bar {h}$ and obviously we have $|\bar {h}|= |h|$ (see [Reference Akylzhanov, Nursultanov and Ruzhansky2, Theorem 4.2]). Now, we are in a position to apply Theorem 3.4. Set ${1}/{p}-{1}/{q}={1}/{r}.$ Now, by applying Theorem 3.4 with $\psi = |h|^r$ with $b=q'$ ,

$$ \begin{align*}\|h \widehat{f}\|_{\,L^{q'}(H, d\lambda)} \lesssim \bigg( \sup_{s>0} s \int_{\underset{|h(\chi)|^r > s}{\chi \in \widehat{H}}} \,d\pi(\chi) \bigg)^{{1}/{r}} \|f\|_{\,L^p(H,\, d\lambda)} \end{align*} $$

for all $f \in L^p(H, d\lambda ),$ in view of ${1}/{p}-{1}/{q}={1}/{q'}-{1}/{p'}={1}/{r.}$ Thus, for $1<p \leq 2 \leq q<\infty ,$

$$ \begin{align*}\|Tf\|_{\,L^q(H, d\lambda)} \lesssim \bigg( \sup_{s>0} s \int_{\underset{|h(\chi)|^r > s}{\chi \in \widehat{H}}} \,d\pi(\chi) \bigg)^{{1}/{r}} \|f\|_{\,L^p(H, d\lambda)}.\end{align*} $$

Further, the proof follows from the following easy identities:

$$ \begin{align*} \bigg( \sup_{s>0} s \int_{\underset{|h(\chi)|^r > s}{\chi \in \widehat{H}}} d\pi(\chi) \bigg)^{{1}/{r}} &= \bigg( \sup_{s>0} s \int_{\underset{|h(\chi)| > s^{{1}/{r}}}{\chi \in \widehat{H}}} d\pi(\chi) \bigg)^{{1}/{r}} = \bigg( \sup_{s>0} s^{r} \int_{\underset{|h(\chi)| > s} {\chi \in \widehat{H}}} d\pi(\chi) \bigg)^{{1}/{r}} \\&= \sup_{s>0} s \bigg( \int_{\underset{|h(\chi)| > s} {\chi \in \widehat{H}}} d\pi(\chi) \bigg)^{{1}/{r}}, \end{align*} $$

proving Theorem 3.5.

4.1 Interlude on Chébli–Trimèche hypergroups

An important and motivating example of a hypergroup is the algebra of finite radial measures on a noncompact rank-one symmetric space under the usual convolution; as radial measures on a noncompact symmetric space can be viewed as measures on ${\mathbb R}_+:=[0, \infty ),$ this endows ${\mathbb R}_+$ with a hypergroup structure with involution being the identity map. The hypergroup structures arising in this way on ${\mathbb R}_+$ are a particular case of a general class of hypergroup structures on ${\mathbb R}_+$ arising from the Strum–Liouville boundary value problems where the solutions coincide with the characters of the hypergroup in question [Reference Bloom, Xu, Connett, Gebuhrer and Schwartz13, Section 3.5].

In this paper, we are interested in a special class of ‘one-dimensional hypergroups’ [Reference Zeuner44] on ${\mathbb R}_+$ called Chébli–Trimèche hypergroups with the convolution structure related to the following second-order differential operator:

(4-1) $$ \begin{align} L=L_{A,x}:= -\frac{d^2}{dx^2}- \frac{A'(x)}{A(x)} \frac{d}{dx}, \end{align} $$

where the function $A,$ called a Chébli–Trimèche function, is continuous on ${\mathbb R}_+,$ twice continuously differentiable on ${\mathbb R}^*_+:=(0, \infty )$ and satisfies the following properties:

1. (i) $A(0)=0$ and A is positive on ${\mathbb R}^*_+;$

2. (ii) A is an increasing function and $A(x) \rightarrow \infty $ as $x \rightarrow \infty ;$

3. (iii) ${A'}/{A}$ is a decreasing $C^\infty $ -function on ${\mathbb R}^*_+$ ; hence ${\rho := \tfrac 12 \lim \nolimits _{x \rightarrow \infty } {A'(x)}/ {A(x)} \geq 0}$ exists;

4. (iv) ${A'(x)}/{A(x)}= ({2\alpha +1})/{x}+B(x)$ on a neighbourhood of $0$ , where $\alpha>-\tfrac 12$ and B is an odd $C^\infty $ -function on ${\mathbb R}.$

Now, we define the main object of this section, namely, the Chébli–Trimèche hypergroups. For a detailed study of these hypergroups, one can refer to [Reference Bloom and Heyer12, Reference Chébli19, Reference Trimèche41].

Definition 4.1. [Reference Bloom, Xu, Connett, Gebuhrer and Schwartz13, Reference Bloom and Xu14, Reference Zeuner44] A hypergroup $({\mathbb R}_+, *)$ is called a Chébli–Trimèche hypergroup if there exists a Chébli–Trimèche function A such that for any real-valued $C^\infty $ -function f on ${\mathbb R}_+,$ that is, the restriction of an even nonnegative $C^\infty $ -function on ${\mathbb R},$ the generalised translation $u(x,y)=T_xf(y):= \int _0^\infty f(t)\, d(\delta _x*\delta _y)(t),\,\,\,\, y \in {\mathbb R}_+$ is the solution of the following Cauchy problem:

$$ \begin{align*} &\qquad\quad(L_{A,x}-L_{A,y})u(x, y)=0,\\& u(x,0)=f(x),\quad u_y(x,0)= 0,\quad x>0. \end{align*} $$

The Chébli–Trimèche hypergroup associated with the Chébli–Trimèche function A is denoted by $({\mathbb R}_+, *(A)).$ The growth of $({\mathbb R}_+, *(A))$ is determined by the number $\rho := \tfrac 12 \lim \nolimits _{x \rightarrow \infty } {A'(x)}/{A(x)}.$ We say that $({\mathbb R}_+, *(A))$ is of exponential growth if and only if $\rho>0.$ Otherwise, we say that the hypergroup is of subexponential growth, which also includes polynomial growth.

The class of Chébli–Trimèche hypergroups contains many important classes of hypergroups. We discuss three of them here.

1. (i) If $A(x):= x^{2 \alpha +1}$ with $2 \alpha \in \mathbb {N}$ and $\alpha> -\tfrac 12$ , then $L_{A,x}$ is the radial part of the Laplace operator on the Euclidean space and $({\mathbb R}_+, *(A))$ is a Bessel–Kingman hypergroup.

2. (ii) If $A(x):= (\sinh \, x)^{2\alpha +1} (\cosh \,x)^{2 \beta +1}$ with $2 \alpha , 2 \beta \in \mathbb {N},\,\ \alpha \geq \beta \geq -\tfrac 12$ and $ \alpha \neq -\tfrac 12$ , then $L_{A,x}$ is the radial part of the Laplace–Beltrami operator on a noncompact Riemannian symmetric space of rank one (also of Damek–Ricci spaces) and $({\mathbb R}_+, *(A))$ is a Jacobi hypergroup [Reference Anker, Damek and Yacoub7, Reference Bloom and Heyer12].

3. (iii) If A is the density function on the simply connected harmonic manifold X of purely exponential volume growth, then $L_{A,x}$ is the radial part of the Laplace–Beltrami operator on X and $({\mathbb R}_+, *(A))$ is the ‘radial hypergroup’ of X (see [Reference Biswas, Knieper and Peyerimhoff11]).

The Chébli–Trimèche hypergroup $({\mathbb R}_+, *(A))$ is a noncompact commutative hypergroup with identity element $0$ and involution as the identity map. The Haar measure m on $({\mathbb R}_+, *(A))$ is given by $m(x):= A(x)\,dx,$ where $dx$ is the usual Lebesgue measure on ${\mathbb R}_+.$ For any $x, y \in {\mathbb R}_+,$ the probability measure $\delta _x*\delta _y$ is absolutely continuous with respect to m and ${\text{supp}}(\delta _x*\delta _y) \subset [\,|x-y|, x+y].$ For $1 \leq p \leq \infty ,$ the Lebesgue space $L^p({\mathbb R}_+, m)$ on $({\mathbb R}_+, *(A))$ is defined as usual; we denote by $\|f\|_{p, A}$ the $L^p$ -norm of $f \in L^p({\mathbb R}_+, A\,dx).$

For the Chébli–Trimèche hypergroup $({\mathbb R}_+, *(A)),$ the multiplicative functions on $({\mathbb R}_+, *(A))$ are given by the eigenfunctions of the operator $L:=L_{A,x}$ defined in (4-1). For any $\lambda \in \mathbb {C},$ the equation

(4-2) $$ \begin{align} Lu = (\lambda^2+\rho^2)u \end{align} $$

has a unique solution $\phi _{\lambda }$ on ${\mathbb R}_+^*$ that extends continuously to $0$ and satisfies $\phi _{\lambda }(0)=1.$ We point out here that since the coefficient $A'/A$ of L is singular at $x =0$ as $A(0)=0,$ the existence of a solution continuous at $0$ is not immediate. Since (4-2) reads the same for $\lambda $ and $-\lambda ,$ by uniqueness, we have $\phi _{\lambda }= \phi _{-\lambda }.$ The multiplicative functions, that is, semicharacters, on $({\mathbb R}_+, *(A))$ are then exactly the functions $\phi _{\lambda },\,\, \lambda \in \mathbb {C}.$ However, a semicharacter $\phi _{\lambda }$ is bounded, and therefore becomes a character, if and only if $|\text {Im} \lambda | \leq \rho .$ Since the involution of $({\mathbb R}_+, *(A))$ is just the identity map, it follows that the characters $\phi _\lambda $ of the hypergroup $({\mathbb R}_+, *(A))$ are real-valued, which is the case for every $\lambda \in {\mathbb R} \cup i {\mathbb R}.$ Therefore, in view of the above discussion, the dual space $\widehat {{\mathbb R}}_+$ of $({\mathbb R}_+, *(A))$ is described by $\{\phi _{\lambda }: \lambda \in [0, \infty ) \cup [0, i \rho ] \}$ , which can be identified with the parameter set ${\mathbb R}_+ \cup [0, i \rho ].$

We define the Fourier transform $\widehat {f}$ of $f \in L^1({\mathbb R}_+, A\,dx)$ at a point $\lambda \in \widehat {{\mathbb R}}_+$ by

$$ \begin{align*}\widehat{f}(\lambda):= \int_{0}^\infty f(x)\, \phi_{\lambda}(x)\, A(x)\,dx.\end{align*} $$

It is worth noting that the aforementioned Fourier transform turns out to be a Jacobi transform [Reference Koornwinder, Askey, Koornwinder and Schempp28] when the hypergroup arises from convolution of radial measures on a rank-one symmetric space or, equivalently, $A(x):= (\sinh \, x)^{2\alpha +1} (\cosh \,x)^{2 \beta +1}$ with $\alpha \geq \beta \geq -\tfrac 12$ and $ \alpha \neq -\tfrac 12.$ The following theorem is the Levitan–Plancherel theorem for $({\mathbb R}_+, *(A)).$

Theorem 4.2 [Reference Bloom and Heyer12, Theorem 2.1].

There exists a unique nonnegative measure $\pi $ on $\widehat {{\mathbb R}}_+$ with support $[0, \infty )$ such that the Fourier transform induces an isometric isomorphism from $L^2({\mathbb R}_+, A\,dx)$ onto $L^2(\widehat {{\mathbb R}}_+, \pi )$ and for any $f \in L^1({\mathbb R}_+, A\,dx) \cap L^2({\mathbb R}_+, A\,dx)$ ,

$$ \begin{align*}\int_0^\infty |f(x)|^2 \, A(x)\,dx = \int_{\widehat{{\mathbb R}}_+}\,|\widehat{f}(\lambda)|^2\, d\pi(\lambda).\end{align*} $$

In addition to the aforementioned theorem, we also have the following identity known as Parseval’s identity. For $f_1, f_2 \in L^2(\mathbb {R}_+, A\,dx)$ ,

$$ \begin{align*} \int_0^\infty f_1(x)\, f_2(x)\, A(x)\,dx = \int_{\widehat{{\mathbb R}}_+} \widehat{f}_1(\lambda) \, \widehat{f}_2(\lambda)\, d\pi(\lambda). \end{align*} $$

Condition (P): We say that a function f satisfies Condition (P) if for some $a>0,\ f$ can be expressed as

$$ \begin{align*} f(x)=\frac{a^2-\frac{1}{4}}{x^2}+\zeta(x)\end{align*} $$

for all large x, where

$$ \begin{align*} \int_{x_0}^\infty x^{\gamma(a)} |\zeta(x)|\, dx<\infty\end{align*} $$

for some $x_0>0$ and $\zeta (x)$ is bounded for $x>x_0;$ here $\gamma (a)= a+\tfrac 12$ if $a \geq \tfrac 12$ and $\gamma (a)=1$ otherwise.

Now consider the function G defined by

$$ \begin{align*} G(x):= \frac{1}{4} \bigg( \frac{A'(x)}{A(x)} \bigg)^2+ \frac{1}{2} \frac{d}{dx} \bigg( \frac{A'(x)}{A(x)}\bigg) -\rho^2. \end{align*} $$

It is possible to determine the Plancherel measure $\pi $ explicitly. In fact, Bloom and Xu [Reference Bloom, Xu, Connett, Gebuhrer and Schwartz13] determined it by placing an extra growth condition on A described as follows.

Theorem 4.3 [Reference Bloom, Xu, Connett, Gebuhrer and Schwartz13, Proposition 3.17].

If the function G defined previously satisfies Condition (P) with any of the following conditions:

1. (i) $a>\tfrac 12;$

2. (ii) $a \neq |\alpha |,$ where $\alpha $ is the constant appearing in the definition of Chébli–Triméche function;

3. (iii) $a=\alpha \leq \tfrac 12$ and $\int _0^\infty x^{1/2 -\alpha } \zeta (x) \phi _0(x) A(x)^{1/2}\,dx \neq -2 \alpha \sqrt {M_A}$ or

   $\int _0^\infty x^{1/2 +\alpha } \zeta (x) \phi _0(x) A(x)^{1/2}\,dx=0$ where $M_A= \lim \nolimits _{x \rightarrow 0^+} x^{-2 \alpha -1} A(x)$ and

   $\zeta (x)= G(x)+ (\tfrac 14-a^2)/x^2,$

then the Plancherel measure $\pi $ is absolutely continuous with respect to the Lebesgue measure and has density $|c(\lambda )|^2,$ where the function c satisfies the following: there exist positive constants $C_1, C_2$ and K such that for any $\lambda \in \mathbb {C}$ with $\mathrm{Im}(\lambda ) \leq 0,$

$$ \begin{align*}C_1 |\lambda|^{a+{1}/{2}} \leq |c(\lambda)|^{-1} \leq C_2 |\lambda|^{a+{1}/{2}}\quad \text{for } |\lambda| \leq K,\end{align*} $$

$$ \begin{align*}C_1 |\lambda|^{\alpha+{1}/{2}} \leq |c(\lambda)|^{-1} \leq C_2 |\lambda|^{\alpha+{1}/{2}}\quad \text{for } |\lambda|> K.\end{align*} $$

In the following, we always assume that the function A (and so G) satisfies Condition (P) of Theorem 4.3 for $\alpha \geq 0$ . Therefore, $d\pi = C_0|c(\lambda )|^{-2} d\lambda ,$ where $C_0$ is a positive constant and c is a certain complex function on $\mathbb {C} \backslash \{0\}.$ We also assume that if $\rho =0,\ A$ also satisfies $A(x)=O(x^{2\alpha +1}),$ as $ x \rightarrow \infty .$

Note that the space of infinitely differentiable and compactly supported functions on ${\mathbb R}_+,$ denoted by $C_c^\infty ({\mathbb R}_+)$ , is the space of all even $f \in C_c^\infty ({\mathbb R})$ restricted to ${\mathbb R}_+.$

We have the following Fourier inversion formula for $f \in C_c^\infty ({\mathbb R}_+):$

$$ \begin{align*} f(x)= C_0 \int_0^\infty \widehat{f}(\lambda) \phi_{\lambda}(x)\, |c(\lambda)|^{-2}\, d\lambda. \end{align*} $$

For any $\lambda \in \mathbb {C},\ \phi _\lambda $ is an even $C^\infty $ -function and $\lambda \mapsto \phi _\lambda (x)$ is analytic. Also, $|\phi _{\lambda }(x)| \leq ~1$ for all $x \in {\mathbb R}_+, \lambda \in \mathbb {C}$ with $|\text{Im}\,\lambda | \leq \rho .$ For each $\lambda \in \mathbb {C},\ \phi _{\lambda }$ has a Laplace representation

$$ \begin{align*}\phi_{\lambda}(x)= \int_{-x}^{x} e^{(i \lambda-\rho)t} d\nu_x(t)\quad\text{for } x \in {\mathbb R}_+,\end{align*} $$

where $\nu _x$ is a probability measure on ${\mathbb R}$ supported in $[-x,x].$ Further, if $\lambda \in \mathbb {C}$ , then $|\phi _{\lambda }| \leq C (1+x) e^{(Im \, \lambda -\rho )x}.$

4.2 $L^p$ – $L^q$ boundedness of multipliers on Chébli–Trimèche hypergroups

The following theorem is an analogue of the Paley inequality for Chébli–Trimèche hypergroups on half line.

Theorem 4.4. Suppose that $\psi $ is a positive function on $\mathbb {R}_+$ satisfying the condition

$$ \begin{align*} \nonumber M_\psi := \sup_{t>0} t \int_{\underset{\psi(\lambda)\geq t}{\lambda \in \mathbb{R}_+}} |c(\lambda)|^{-2}\, d\lambda <\infty. \end{align*} $$

Then for $f \in L^p(\mathbb {R}_+, A\,dx),\ 1<p\leq 2,$

$$ \begin{align*} \bigg( \int_0^\infty |\widehat{f}(\lambda)|^p\, \psi(\lambda)^{2-p} |c(\lambda)|^{-2}\, d\lambda \bigg)^{{1}/{p}} \lesssim M_{\psi}^{({2-p})/{p}}\, \|f\|_{\,L^p(\mathbb{R}_+, A\,dx)}. \end{align*} $$

The following Hausdorff–Young–Paley inequality holds for the Chébli–Trimèche hypergroups.

Theorem 4.5. Let $1<p\leq 2$ and let $1<p \leq b \leq p' < \infty ,$ where $p'= {p}/({p-1}).$ If $\psi (\lambda )$ is a positive function on $\mathbb {R}_+$ such that

$$ \begin{align*} M_\psi := \sup_{t>0} t \int_{\underset{\psi(\lambda)\geq t}{\lambda \in \mathbb{R}_+}} |c(\lambda)|^{-2}\, d\lambda \end{align*} $$

is finite, then for every $f \in L^p(\mathbb {R}_+, A\,dx)$ ,

$$ \begin{align*} \bigg( \int_{\mathbb{R}_+} ( |\widehat{f}(\lambda)| \psi(\lambda)^{{1}/{b}-{1}/{p'}} )^b |c(\lambda)|^{-2}\, d\lambda \bigg)^{{1}/{b}} \lesssim M_\psi^{{1}/{b}-{1}/{p'}} \|f\|_{\,L^p(\mathbb{R}_+, A\,dx)}. \end{align*} $$

Next, we establish the following $L^p$ – $L^q$ boundedness result for Fourier multipliers on Chébli–Trimèche hypergroups.

Theorem 4.6. Let $1<p\leq 2 \leq q<\infty $ and let T be a Fourier multiplier with symbol $h.$ Then,

$$ \begin{align*}\|T\|_{\,L^p(\mathbb{R}_+, A\,dx) \rightarrow L^q(\mathbb{R}_+, A\,dx)}\lesssim \sup_{s>0} s \bigg[ \int_{\{ \lambda \in \mathbb{R}_+: |h(\lambda)|\geq s\}} |c(\lambda)|^{-2}\, d\lambda \bigg]^{{1}/{p}-{1}/{q}}.\end{align*} $$

4.3 Spectral multipliers of the generalised radial Laplacian

Now, we apply Theorem 3.5 to prove the $L^p$ – $L^q$ boundedness of spectral multipliers for the operator $L:=L_{A, x}.$ If $\varphi \in L^\infty ({\mathbb R}_+, A\,dx),$ the spectral multiplier $\varphi (L),$ defined by $\varphi $ coincides with the Chébli–Trimèche Fourier multiplier $T_h$ with $h(\lambda )= \varphi (\lambda ^2+\rho ^2)$ for $\lambda \in {\mathbb R}_+.$ The $L^p$ -boundedness of spectral multipliers has been proved by several authors in many different settings, for example, Bessel transforms [Reference Betancor, Castro and Curbelo10], Dunkl harmonic oscillators [Reference Wróbel42] and multidimesional Hankel transforms [Reference Dziubanśki, Preisner and Wrob́el24]. The $L^p$ – $L^q$ boundedness of spectral multipliers for compact Lie groups, Heisenberg groups and graded Lie groups has been proved by Akylzhanov and the second author [Reference Akylzhanov and Ruzhansky4]. Chatzakou and the first author recently studied $L^p$ – $L^q$ boundedness of a spectral multiplier for the anharmonic oscillator [Reference Chatzakou and Kumar17, Reference Chatzakou and Kumar18] (see also [Reference Cardona, Kumar, Ruzhansky and Tokmagambetov16]). Now, we state the main result of this subsection.

Theorem 4.7. Let $1<p \leq 2 \leq q <\infty $ and let $\varphi $ be a monotonically decreasing continuous function on $[\rho ^2, \infty )$ such that $\lim _{u \rightarrow \infty }\varphi (u)=0.$ Then,

$$ \begin{align*} \|\varphi(L)\|_{\text{op}} \lesssim \sup_{u>\rho^2} \varphi(u) \begin{cases} (u-\rho^2)^{(a+1)({1}/{p}-{1}/{q})} & \text{if } (u-\rho^2)^{{1}/{2}} \leq K, \\ [K^{2a+2}- K^{2\alpha+2}+(u-\rho^2)^{(\alpha+1)} ]^{{1}/{p}-{1}/{q}} & \text{if } (u-\rho^2)^{{1}/{2}}>K, \end{cases} \end{align*} $$

where K is a constant appearing in the estimate of the c-function and $\|\cdot \|_{\text{op}} $ denotes the operator norm from $L^p(\mathbb {R}_+, A\,dx)$ to $L^q(\mathbb {R}_+, A\,dx).$

Proof. Since $\varphi (L)$ is a Fourier multiplier with the symbol $\varphi (\lambda ^2+\rho ^2),$ as an application of Theorem 4.6,

$$ \begin{align*} \|\varphi(L)\|_{\text{op}} & \lesssim \sup_{s>0} s \bigg[ \int_{ \{ \lambda \in \mathbb{R}_+ :\, \varphi(\lambda^2+\rho^2) \geq s\} } |c(\lambda)|^{-2}\,d\lambda \bigg]^{{1}/{p}-{1}/{q}} \\ & = \sup_{0<s<\varphi(\rho^2)} s \bigg[ \int_{ \{ \lambda \in \mathbb{R}_+ :\, \varphi(\lambda^2+\rho^2) \geq s\} } |c(\lambda)|^{-2}\,d\lambda \bigg]^{{1}/{p}-{1}/{q}}, \end{align*} $$

since $\varphi \leq \varphi (\rho ^2).$ Now, as $s \in (0, \varphi (\rho ^2)]$ , we can write $s= \varphi (u)$ for some $u \in [\rho ^2, \infty )$ and, therefore,

$$ \begin{align*} \|\varphi(L)\|_{\text{op}} \lesssim \sup_{\varphi(u) <\varphi(\rho^2)} \varphi(u) \bigg[ \int_{ \{ \lambda \in \mathbb{R}_+ :\, \varphi(\lambda^2+\rho^2) \geq \varphi(u)\} } |c(\lambda)|^{-2}\,d\lambda \bigg]^{{1}/{p}-{1}/{q}}. \end{align*} $$

Since $\varphi $ is monotonically decreasing,

$$ \begin{align*} \|\varphi(L)\|_{\text{op}} \lesssim \sup_{u>\rho^2} \varphi(u) \bigg[ \int_{ \{ \lambda \in \mathbb{R}_+ :\, \lambda \leq (u-\rho^2)^{{1}/{2}}\} } |c(\lambda)|^{-2}\,d\lambda \bigg]^{{1}/{p}-{1}/{q}}. \end{align*} $$

Now, we use the estimate of the c-function (see Theorem 4.3) to get

$$ \begin{align*} \|\varphi(L)\|_{\text{op}} &\lesssim \sup_{u>\rho^2} \varphi(u) \begin{cases} \bigg[ \int_0^{ (u-\rho^2)^{{1}/{2}} } \lambda^{2a+1} \,d\lambda \bigg]^{{1}/{p}-{1}/{q}} &\text{if } (u-\rho^2)^{{1}/{2}} \leq K, \\ \bigg[ \int_0^K \lambda^{2a+1} d\lambda +\int_K^{ (u-\rho^2)^{{1}/{2}} } \lambda^{2\alpha+1}\,d\lambda \bigg]^{{1}/{p}-{1}/{q}} &\text{if } (u-\rho^2)^{{1}/{2}}>K \end{cases} \\&=\sup_{u>\rho^2} \varphi(u) \begin{cases} (u-\rho^2)^{(a+1)({1}/{p}-{1}/{q})} &\text{if } (u-\rho^2)^{{1}/{2}} \leq K, \\ [K^{2a+2}- K^{2\alpha+2}+(u-\rho^2)^{(\alpha+1)} ]^{{1}/{p}-{1}/{q}} &\text{if } (u-\rho^2)^{{1}/{2}}>K, \end{cases} \end{align*} $$

proving Theorem 4.7.

4.3.1 Heat equation

Let us consider the L-heat equation

(4-3) $$ \begin{align} \partial_t u+L u=0, \quad u(0)=u_0 \in L^p({\mathbb R}_+, A\,dx),\quad 1<p\leq 2. \end{align} $$

One can verify that for each $t>0,\ u(t, x)=e^{-t L}u_0$ is a solution of initial value problem (4-3). To apply Theorem 4.7, we consider the function $\varphi (u)= e^{-tu}$ , which satisfies the condition of Theorem 4.7 and therefore,

$$ \begin{align*} \|e^{-tL}\|_{\text{op}} \leq \sup_{u>\rho^2} e^{-tu} \begin{cases} (u-\rho^2)^{(a+1)({1}/{p}-{1}/{q})} & \text{if } (u-\rho^2)^{{1}/{2}} \leq K, \\ [K^{2a+2}- K^{2\alpha+2}+(u-\rho^2)^{(\alpha+1)} ]^{{1}/{p}-{1}/{q}} & \text{if } (u-\rho^2)^{{1}/{2}}>K, \end{cases} \end{align*} $$

by setting $s= (u-\rho ^2)^{1/2}$ ,

(4-4) $$ \begin{align} \|e^{-tL}\|_{\text{op}} \leq e^{-t \rho^2}\sup_{s>0} e^{-ts^2} \begin{cases} s^{2(a+1)({1}/{p}-{1}/{q})} & \text{if } s \leq K, \\ [K^{2a+2}- K^{2\alpha+2}+s^{2(\alpha+1)} ]^{{1}/{p}-{1}/{q}} & \text{if } s >K. \end{cases} \end{align} $$

Now, we first calculate $e^{-t \rho ^2}\,\,\sup _{s>0} e^{-ts^2} s^{{2(a+1)}/{r}},$ where ${1}/{r}={1}/{p}-{1}/{q}.$ Consider the function

$$ \begin{align*}\phi(s)= e^{-ts^2} s^{{2(a+1)}/{r}}.\end{align*} $$

Then,

$$ \begin{align*}\phi'(s)= e^{-ts^2}\bigg(-2s^2t+\frac{2(a+1)}{r} \bigg) s^{({2(a+1)}/{r})-1}.\end{align*} $$

So, the derivative $\phi '$ is zero only at $s_0= \sqrt {{(a+1)}/{rt}}$ and changes sign from positive to negative at $s_0.$ Thus, $s_0$ is the point of maximum of $\phi $ if $s_0 \leq K$ , that is, ${\sqrt {{(a+1)}/{rt}} \leq K}$ implies that $t \geq {(a+1)}/{r K^2}.$ Thus,

(4-5) $$ \begin{align} e^{-t \rho^2}\,\,\sup_{s>0} e^{-ts^2} s^{{2(a+1)}/{r}}= e^{-t \rho^2} e^{-{(a+1)}/{ r}} \bigg(\frac{a+1}{rt} \bigg)^{{(a+1)}/{r}} \leq C_{a,r}\ e^{-t \rho^2}\ t^{{-(a+1)}/{r}}. \end{align} $$

Now, for $s>K,$ consider the function $\psi (s)= e^{-ts^2} [K^{2a+2}-K^{2\alpha +2}+s^{2(\alpha +1)}]^{{1}/{r}}.$ Then it is easy to see that

$$ \begin{align*} \psi'(s)= 2e^{ts^2} s [K^{2a+2}-K^{2\alpha+2}+s^{2(\alpha+1)}]^{{1}/{r}-1} \bigg( -t [K^{2a+2}-K^{2\alpha+2}+s^{2(\alpha+1)}]+ \frac{\alpha+1}{r} s^{2 \alpha} \bigg). \end{align*} $$

Now, we see that $\psi '(s_0)=0$ at the point $s_0>K$ if $s_0$ satisfies the equation

$$ \begin{align*} t [K^{2a+2}-K^{2\alpha+2}+s^{2(\alpha+1)}]= \frac{\alpha+1}{r} s^{2 \alpha},\end{align*} $$

that is, $t [K^{2a+2}-K^{2\alpha +2}+s_0^{2(\alpha +1)}]= ({\alpha +1})/{r} s_0^{2 \alpha }.$ Therefore, $\psi '$ changes sign from positive to negative at $s_0$ and so it is a point of maximum. Thus,

$$ \begin{align*} e^{-t \rho^2}\,\,\sup_{s>0}\,& e^{-ts^2} [K^{2a+2}-K^{2\alpha+2}+s^{2(\alpha+1)}]^{{1}/{r}}\\&= e^{-t \rho^2} e^{-t s_0^2} \bigg( \frac{\alpha+1}{r t} s_0^{2 \alpha}\bigg)^{{1}/{r}} \leq C_{\alpha, a, r, K } e^{-t \rho^2} t^{-{1}/{r}} e^{-ts_0^2} s_0^{{2\alpha}/{r}} \\& \lesssim t^{-{1}/{r}} \sup_{s>K} e^{-ts^2} s^{{2(\max\{\alpha, a+1\})}/{r}}. \end{align*} $$

Now, we compute $\sup _{s>K} e^{-ts^2} s^{{2(\max \{\alpha , a+1\})}/{r}}$ . For this purpose, we set $\eta (s)= e^{-ts^2} s^{{2(\max \{\alpha , a+1\})}/{r}}.$ Again, the derivative $\eta '(s)=0$ for $s=\!\sqrt {{\max \{\alpha , a+1\}}/{rt}}>K,$ that is, $t< {\max \{\alpha , a+1\}}/{ K^2 r}$ and changes its sign from positive to negative at $s=\!\sqrt{{\max \{\alpha , a+1\}}/{rt}}$ . Therefore,

(4-6) $$ \begin{align} \nonumber &e^{-t \rho^2}\,\,\sup_{s>0} e^{-ts^2} [K^{2a+2}-K^{2\alpha+2}+s^{2(\alpha+1)}]^{{1}/{r}} \lesssim t^{-{1}/{r}} \sup_{s>K} e^{-ts^2} s^{{2\max\{\alpha, a+1\}}/{r}} \\& \quad\lesssim e^{-t {\max\{\alpha, a+1\}}/{r t}} t^{-{1}/{r}} \bigg(\sqrt{\frac{\max\{\alpha, a+1\}}{rt}} \bigg)^{{2 \max\{\alpha, a+1\}}/{r}} \lesssim t^{-{(\max\{\alpha, a+1\}+1)}/{r}}. \end{align} $$

Next, by putting the estimates from (4-5) and (4-6) in (4-4),

$$ \begin{align*} \|e^{-tL}\|_{\text{op}} \lesssim \begin{cases} t^{-(\max\{\alpha, a+1\}+1)({1}/{p}-{1}/{q})} & \text{if } 0<t < \dfrac{\max\{\alpha, a+1\}}{K^2}\bigg(\dfrac{1}{p}-\dfrac{1}{q} \bigg) \\e^{-t \rho^2}\,\, t^{-(a+1)({1}/{p}-{1}/{q})} & \text{if } t \geq \dfrac{a+1}{K^2}\bigg(\dfrac{1}{p}-\dfrac{1}{q} \bigg).\end{cases} \end{align*} $$

Therefore,

$$ \begin{align*} & \|u(t, \cdot)\|_{\,L^q(\mathbb{R}_+, A\,dx)} \leq \|e^{-t L}u_0\|_{\,L^q(\mathbb{R}_+, A\,dx)} \leq \|e^{-tL}\|_{\text{op}} \|u_0\|_{\,L^p(\mathbb{R}_+, A\,dx)}\nonumber \\&\lesssim \|u_0\|_{\,L^p(\mathbb{R}_+, A\,dx)}\begin{cases} t^{-(\max\{\alpha, a+1\}+1)({1}/{p}-{1}/{q})} & \text{if } 0<t < \dfrac{\max\{\alpha, a+1\}}{K^2}\bigg(\dfrac{1}{p}-\dfrac{1}{q} \bigg) \\e^{-t \rho^2}\,\, t^{-(a+1)({1}/{p}-{1}/{q})} & \text{if } t \geq \dfrac{a+1}{K^2}\bigg(\dfrac{1}{p}-\dfrac{1}{q} \bigg). \end{cases} \end{align*} $$

4.3.2 Sobolev type embeddings

Let $1<p\leq 2 \leq q<\infty $ . As an application of Theorem 4.7, we obtain a Sobolev-type embedding theorem for operator $L.$ Consider the function $\varphi (u)= (1+u)^{-b},\ u> \rho ^2,$ which $\varphi $ satisfies the condition of Theorem 4.7. Therefore, from Theorem 4.7,

$$ \begin{align*}&\|(1+L)^{-b}\|_{\text{op}}\\[4pt] &\quad\lesssim \sup_{u>\rho^2} (1+u)^{-b} \begin{cases} (u-\rho^2)^{(a+1)({1}/{p}-{1}/{q})} & \text{if } (u-\rho^2)^{{1}/{2}} \leq K, \\ [K^{2a+2}- K^{2\alpha+2}+(u-\rho^2)^{(\alpha+1)} ]^{{1}/{p}-{1}/{q}} & \text{if } (u-\rho^2)^{{1}/{2}}>K, \end{cases} \end{align*} $$

which is finite provided that $b \geq (\alpha +1) ( {1}/{p}-{1}/{q} ).$

Therefore,

$$ \begin{align*}\|f\|_{\,L^q({\mathbb R}_+, A\,dx)} \leq C \|(1+L)^b f\|_{\,L^q({\mathbb R}_+, A\,dx)}\end{align*} $$

provided that $b \geq (\alpha +1) ( {1}/{p}-{1}/{q} ),\,\,1<p\leq 2 \leq q<\infty .$