Fact 2.1. Let $g:\mathbb {R}^n\to [0, \infty )$ be a log-concave function with $g\not \equiv 0$ . The following properties are equivalent:

1. (i) $\int _{\mathbb {R}^n} g < \infty $ .

2. (ii) There exists some constants $A,B>0$ such that for all $x\in \mathbb {R}^n$ ,

   (2.1) $$ \begin{align} g(x)\le A\, e^{-B\, |x|}. \end{align} $$

3. (iii) For every $a\in \mathbb {R}^n$ and $u\in \mathbb {S}^{n-1}$ , one has $g(a+tu) \to 0$ as $t\to +\infty $ .

Proof. The equivalence $(i)\Leftrightarrow (ii)$ is easy and standard (see, for instance, [Reference Klartag19]), and $(ii)\Rightarrow (iii)$ is obvious. So we concentrate on $(iii)\Rightarrow (i)$ .

Note that in dimension one, if $\alpha :\mathbb {R}\to \mathbb {R}^+$ is a log-concave function such that $\alpha (t)$ tends to $0$ as $|t|\to \infty $ (equivalently, the convex function $t\mapsto -\log (\alpha (t))$ tends $\infty $ as $|t|\to \infty $ ), then there exists $C,c>0$ such that $\alpha (t) \le C \, e^{-c\, |t|}$ for all $t\in \mathbb {R}$ .

Fix $a\in {\textrm {int}}(\mathrm {supp}(g))$ . Then,

$$ \begin{align*} \int_{\mathbb{R}^n} g(x) dx = \int_{\mathbb{R}^n} g(a+x) dx = \int_{\mathbb{S}^{n-1}}\left(\int_0^\infty t^{n-1}g(a+tu)dt\right)du. \end{align*} $$

The remark above with $\alpha (t)=g(a+tu)$ gives that $t\mapsto t^{n-1}g(a+tu)$ is integrable on $\mathbb {R}^+$ . Since g is $\log $ -concave, there exists a convex set $K_a$ (see [Reference Ball3, Theorem 3], [Reference Gardner and Zhang13, Corollary 4.2] or [Reference Cordero-Erausquin, Fradelizi, Paouris and Pivovarov7, Theorem 3.1]) such that, for any $x\in \mathbb {R}^n$ ,

$$ \begin{align*}\frac{1}{n}\|x\|_{K_a}^{-n} = \int_0^\infty t^{n-1}g(a+tx)dt.\end{align*} $$

From our choice of a, we have that $\|\cdot \|_{K_a}$ is finite, and therefore continuous since it is convex. Moreover, since $t^{n-1}g(a+tu)$ is integrable, $\|u\|_{K_a}>0$ for all $u\in \mathbb {S}^{n-1}$ , and so there exists $c>0$ such that $\|u\|_{K_a} \ge c $ for all $u\in \mathbb {S}^{n-1}$ . This implies that $K_a$ is bounded, and therefore,

$$ \begin{align*}\int_{\mathbb{R}^n}g(x)dx = \frac{1}{n}\int_{\mathbb{S}^{n-1}}\|u\|_{K_a}^{-n} du = \textrm{Vol}_n(K_a) < \infty.\\[-42pt]\end{align*} $$

Fact 2.2. Let g be a log-concave function with $g\not \equiv 0$ . Assume ${\textrm {dom}}(Lg)\neq \emptyset $ . Then

1. 1. The set ${\textrm {dom}}( Lg)$ is an open and convex set, on which $Lg$ is smooth and strictly convex, and we have

   $$\begin{align*}{\textrm{dom}}( Lg)\subseteq \{g^\circ>0\}\subseteq \overline{{\textrm{dom}}( Lg)}. \end{align*}$$

2. 2. If the origin is in the interior of the support of g, then $ Lg$ tends to $\infty $ at the boundary of ${\textrm {dom}}( Lg)$ . Consequently, $ Lg$ attains its minimum, at a unique point in ${\textrm {dom}}(Lg)$ . This point $s_0$ is characterized by the property

   $$ \begin{align*}\textrm{bar} (g(x) e^{x\cdot s_0})=0.\end{align*} $$

3. 3. However, if the origin is not in the interior of the support of g, then there exists a vector $z_0\in \mathbb {R}^n$ and a direction $u\in \mathbb {S}^{n-1}$ such that $\lim _{t\to \infty }Lg (z_0+tu)=0$ .

Proof. When $g\not \equiv 0$ is integrable, it was easily noticed by Klartag [Reference Klartag19], using (2.1), that the domain of the convex function $\log Lg$ , which equals the domain of $Lg$ , is open and that the function $\log Lg$ is strictly convex and smooth on its domain; for this, one uses that the Hessian of $\log Lg$ is a covariance matrix that is strictly positive when the support of g has nonempty interior, which, for a log-concave function g, amounts to $\int g>0$ . It then follows that $Lg$ is strictly convex and smooth on its domain.

Denote by $\sigma _z(x)=e^{z\cdot x}$ . Let $z_0\in {\textrm {dom}}(Lg)$ ; then $g \sigma _{z_0}\in L^1(\mathbb {R}^n)$ and $L(g\sigma _{z_0})=\tau _{-z_0}Lg$ . Applying the previous observation to $g \sigma _{z_0}$ , it follows that $Lg=\tau _{z_0} L(g\sigma _{z_0})$ is strictly convex and smooth on its domain which is open.

Next, note that $\{g^\circ>0\}= \{z\; ;\; g \sigma _z \in L^\infty (\mathbb {R}^n)\}$ while ${\textrm {dom}}(Lg)=\{z \; ;\; \sigma _z g\in L^1(\mathbb {R}^n)\}$ . As mentioned above, for a log-concave function, which is $\not \equiv 0$ , being integrable implies being bounded, so we have ${\textrm {dom}}(Lg)\subseteq \{g^\circ>0\}$ . As before, since $\sigma _{z_0} g$ is integrable, there exists $a,b>0$ such that $g(x) e^{z_0\cdot x} \le b e^{-a|x|}$ , for all $x\in \mathbb {R}^n$ . Take now $z\in \{g^\circ>0\}$ . For $t\in (0,1)$ , if we set $z(t) = (1-t) z_0 + t z$ , then we have

$$ \begin{align*}g(x)\, e^{z(t)\cdot x} \le \frac{b^{1-t}}{(g^\circ (z))^t} e^{-a (1-t)\, |x|}, \qquad \forall x\in \mathbb{R}^n.\end{align*} $$

Thus, $z(t) \in {\textrm {dom}}(L g)$ . Since $z(t) \to z$ as $t\to 1$ , we conclude that $z\in \overline {{\textrm {dom}}(Lg)}$ . We have established the first claim. We now study the behavior at the boundary.

Suppose the origin is in the interior of the support of g. Then, there exists $\varepsilon>0$ such that $2\varepsilon B_2^n$ is included in the interior of the support of g. Since g is continuous on the interior of its support, it follows that there exists $c>0$ such that $\int _{x\cdot u>\varepsilon }g(x)dx\ge c$ for all $u\in \mathbb {S}^{n-1}$ . Let $z\in \mathbb {R}^n$ , with $z\neq 0$ . Then

$$\begin{align*}Lg(z)\ge\int_{x\cdot z>\varepsilon|z|} g(x)\,dx\; e^{\varepsilon|z|}\ge c\, e^{\varepsilon|z|}. \end{align*}$$

It follows that $\lim _{|z|\to +\infty }Lg(z)=\infty $ .

We now consider the possibility that the domain is not the whole space and we have a vector a in the boundary, necessarily outside the domain since it is open. If $(a_n)$ is any sequence in the domain tending to a, then by Fatou’s Lemma,

$$ \begin{align*}\liminf \int_{\mathbb{R}^n} g(y)\, e^{a_n \cdot y} \, dy \ge \int_{\mathbb{R}^n} g(y)\, e^{a\cdot y}\, dy = \infty.\end{align*} $$

As a consequence of this boundary behavior, we see that $\log Lg$ attains its minimum, at a point in its domain that we denote by $s_0$ . This point is unique since $\log Lg $ is strictly convex. Moreover, $\log Lg$ is differentiable in the interior of its domain, so the point $s_0$ is characterized by

$$ \begin{align*}\nabla \log Lg(s_0)=0,\end{align*} $$

which rewrites as

$$ \begin{align*}0=\int_{\mathbb{R}^n} x \, \frac{g(x)\, e^{x\cdot s_0}\, dx}{\int_{\mathbb{R}^n} g(x)e^{x\cdot s_0}\, dx}.\end{align*} $$

Recall here that an integrable log-concave function has moments of all orders, by (2.1).

Finally, if the support of g does not contain the origin, then, from the Hahn-Banach theorem, there exists a direction $u\in \mathbb {S}^{n-1}$ and a hyperplane $H=\{x\in \mathbb {R}^n\;; \; x\cdot u =0\}$ with outer-unit normal u such that $\mathrm {supp}(g) \subseteq H^{-}=\{x\in \mathbb {R}^n\;; \; x\cdot u \leq 0\}$ . Using again $z_0\in {\textrm {dom}}(Lg)$ , we then have, for every $t>0$ ,

$$\begin{align*}Lg(z_0+tu) = \int_{\mathbb{R}^n}e^{x\cdot (z_0+tu)}g(x)dx = \int_{\{x\cdot u < 0\}}e^{tx\cdot u}\, e^{x\cdot z_0}\, g(x)dx. \end{align*}$$

Since on $H^-$ we have $ e^{tx\cdot u}\, e^{x\cdot z_0}\, g(x)\le e^{x\cdot z_0}\, g(x)$ and this upper bound is integrable, we can use dominated convergence and obtain

$$ \begin{align*}\lim_{t\to \infty}Lg(z_0+tu) = 0.\\[-42pt]\end{align*} $$

Fact 2.3. Let $F:\mathbb {R}^n\to \mathbb {R}\cup \{\infty \}$ be a convex lower semi-continuous function. If ${\textrm {dom}}(L(e^{-F}))=\emptyset $ , then F is affine along a line.

Proof. We can assume that F is proper, for, if not, we would have $e^{-F}=0$ and so ${\textrm {dom}}(L(e^{-F}))=\mathbb {R}^n$ .

Consider the epigraph of F:

$$ \begin{align*}C=\{(x,t); t \geq F(x)\}\subset \mathbb{R}^n\times \mathbb{R}.\end{align*} $$

Then, C is a nonempty closed, convex set. If F is not affine along a line, then C does not contain a line; indeed, if the closed convex set C contains a line $\ell $ , then all lines parallel to $\ell $ through points of C are also in C, which implies in particular that the boundary of C contains also a line (and F is therefore affine along the projection on $\mathbb {R}^n$ of this line). Thus, C must contain extreme points, and hence exposed points. Let $(x_0,F(x_0))$ be an exposed point of the boundary of C. This means there exists $z_0\in \mathbb {R}^n$ such that the convex function $x\to G(x):=F(x)-x\cdot z_0 \in \mathbb {R}\cup \{\infty \}$ has a unique minimum at $x_0$ . In turn, this implies there exists $a,b>0$ such that

(2.2) $$ \begin{align} G(x)\geq a|x| -b, \quad \forall x\in \mathbb{R}^n. \end{align} $$

Indeed, since $m:= G(x_0)<G(y)$ for all $y\in \mathbb {R}^n$ , we have, using the lower-semi continuity of G, that $M:=\inf _{|\theta | = 1} G(x_0+\theta )>m$ . A standard argument then gives (2.2) with $a=M-m>0$ : for $|x-x_0|>1$ , write $x_0+\frac {x-x_0}{|x-x_0|} = \frac {1}{|x-x_0|} x + \big (1- \frac {1}{|x-x_0|}\big )x_0 $ and, for $|x-x_0|\le 1$ , simply invoke that G is lower-bounded.

Property (2.2) implies $\int _{\mathbb {R}^n}e^{-(F(x) - x\cdot z_0)}dx < \infty $ , and so ${\textrm {dom}}(L(e^{-F}))\not \equiv \emptyset $ .

Fact 2.4. Let $F_k : \mathbb {R}^n \to \mathbb {R}\cup \{+\infty \}$ be a sequence of convex functions converging pointwise to a convex function $F : \mathbb {R}^n \to \mathbb {R}\cup \{+\infty \}$ on a dense subset S of $\mathbb {R}^n$ . Assume ${\textrm {int}}({\textrm {dom}}(F))\neq \emptyset $ . Then

1. 1. $F_k\to F$ uniformly on any compact subset of ${\textrm {int}}( {\textrm {dom}}(F))$ .

2. 2. $F_k$ converges to $+\infty $ uniformly on any compact subset of ${\textrm {int}}\{F=+\infty \}={\textrm {int}}({\textrm {dom}}(F)^c)$ .

Proof. Let $x_0\in {\textrm {int}}( {\textrm {dom}}(F))$ and let $z_1, \ldots , z_{n+1}$ be affinely independent points such that $x_0$ is in the interior of the simplex $\Delta =\textrm {conv}(z_1, \ldots , z_{n+1})$ and $\Delta $ is contained in the interior of the domain of F. Furthermore, we may move if needed the $z_i$ ’s a little bit so that they belong to S. By definition, there exists N such that for every $k\ge N$ , $F_k(z_i)< \infty $ for $i=1, \ldots , n+1$ . This implies, by convexity, that $F_k$ is finite on $\Delta $ for every $k\ge N$ . On the interior of $\Delta $ , we have a sequence $(F_k)_{k\ge N}$ of finite convex functions converging pointwise to a finite convex function F, and it is classical that the convergence is then uniform over compact subsets; see [Reference Rockafellar32, Theorem 10.8]. We thus pick any ball B of positive radius containing $x_0$ and contained in the interior of $\Delta $ .

Now, for the second case, let $x_0\in {\textrm {int}}\{F=+\infty \}$ . Fix $z_0\in {\textrm {int}}({\textrm {dom}}(F))$ and $r>0$ such that $z_0+rB_2^n\subset {\textrm {int}}({\textrm {dom}}(F))$ and consider the set $C=\textrm {conv}(z_0+\frac {r}{2}B_2^n,x_0)$ . Since $x_0$ is in the interior of the complement of the domain of F, there exists a point $y\in S\cap C\cap {\textrm {int}}\{F=+\infty \}$ , that can therefore be written as

(2.3) $$ \begin{align} y=(1-\lambda) z_1 + \lambda x_0 \end{align} $$

for some $z_1\in z_0+\frac {r}{2}B_2^n$ and $\lambda \in (0,1)$ . Let us prove that $F_k$ converges uniformly to F on the ball (included in $\{F=+\infty \}$ ) given by

$$ \begin{align*}B:=x_0 + \frac{r}{2}\left(\frac{1}{\lambda}-1\right)B_2^n.\end{align*} $$

For any $x\in B$ , let us define $z=z(x)=\frac {y-\lambda x}{1-\lambda }$ , so that $y=(1-\lambda )z + \lambda x$ . Then $z\in z_1+\frac {r}{2}B_2^n\subset z_0+rB_2^n \subset {\textrm {int}}({\textrm {dom}}(F))$ . Indeed, one has

$$\begin{align*}z-z_1=\frac{y-\lambda x}{1-\lambda}-\frac{y-\lambda x_0}{1-\lambda}=\frac{\lambda}{1-\lambda}(x_0-x)\in \frac{r}{2}B_2^n. \end{align*}$$

Then the convexity of F and $F_k$ give that

$$ \begin{align*}\ \frac{1}{\lambda}F(y) \le \left(\frac{1}{\lambda}-1\right) F(z) + F(x)\quad \mbox{and}\quad \frac{1}{\lambda}F_k(y) \le \left(\frac{1}{\lambda}-1\right) F_k(z) + F_k(x).\end{align*} $$

The first inequality ensures that $F(x)=F(y)=\infty $ , since $F(z)<\infty $ , and so $B\subset \{F=+\infty \}$ . The second inequality ensures that $F_k(x)\to +\infty $ uniformly on B, since $F_k(z)\to F(z) <+\infty $ uniformly in $z_0+rB_2^n$ (from case 1) and $F_k(y)\to F(y)=+\infty $ .

Fact 2.5. Let $(g_k)_k$ be a sequence of log-concave functions converging pointwise on a dense subset of $\mathbb {R}^n$ to a log-concave function g with $g\not \equiv 0$ . Then, $g_k$ converges to g uniformly on any compact subset of ${\textrm {int}}(\mathrm {supp} (g))$ and on any compact compact subset of $\mathbb {R}^n\setminus \mathrm {supp} (g)$ , hence almost everywhere.

Moreover,

$$ \begin{align*}\int g_k \to \int g.\end{align*} $$

In particular, $Lg_k \to Lg$ pointwise on $\mathbb {R}^n$ .

Proof. The uniform convergence follows from Fact 2.4 applied to the convex functions $-\log (g_k)$ . This immediately implies that, if $\int g =\infty ,$ then the claimed convergence of integrals holds, since $\int g = \int _{{\textrm {int}}(\mathrm {supp}(g))} g$ , and so for every $C>0$ , we can find a compact set K in the interior of the support of g such that $\int _K g \ge C$ . Thus, we assume that $\int g<\infty $ . Since $g_k\to g$ pointwise outside the boundary of $\{g=0\}$ , the convergence occurs almost everywhere.

Since $g \not \equiv 0$ , there exists a closed ball in $\textrm {int}(\mathrm {supp}(g))$ . Without loss of generality, we may assume that this ball is $B_2^n$ . Then, by continuity of g, there exists $m,M>0$ such that $m< g(x)< M$ for all x in this ball, and since $g_k$ converges uniformly on $B_2^n$ , there exists $k_0$ such that for all $k\ge k_0$ and for all $x\in B_2^n$ one has $m<g_k(x)<M$ .

Since g is log-concave and integrable, we have that $\sup _{|x|>R}g(x) \to 0$ as $R \to \infty $ , by Fact 2.1. Thus, we can find R such that $|x|\ge R$ implies $g(x)<\frac {m}{e}$ . Define the annulus $K_{R}=\{x;R\leq |x|\leq R+1\}$ . Let $z_1,\dots , z_N\notin \partial (\mathrm {supp}(g))$ be such that $K_R$ is covered by the balls $z_i+\frac {1}{2}B_2^n$ , for $1\le i\le N$ . Thus, there exists $k_1$ such that for every $1\le i\le N$ and for every $k\ge k_1$ , one has $g_k(z_i)\le \frac {m}{e}$ . Introducing the sphere $S_{2R}:=\{x;\; |x|=2R\}$ , we have that $S_{2R}\subset 2K_R\subset \cup (2 z_i + B_2^n)$ . For every $x\in S_{2R}$ , there exists $1\le i\le N$ such that $x-2z_i\in B_2^n$ . Consequently, $g_k(z_i)^2\ge g_k(2z_i-x)g_k(x)$ , and for every $x\in S_{2R}$ and for every $k\ge k_1$ , we get

$$\begin{align*}g_k(x)\le\frac{g_k(z_i)^2}{g_k(2z_i-x)}\le \frac{m}{e^2}. \end{align*}$$

Using again the log-concavity of $g_k$ , we deduce that for every x such that $|x|\ge 2R$ , one has

$$\begin{align*}g_k(x)\le g_k(0)\left(\frac{g_k(2Rx/|x|)}{g_k(0)}\right)^{\frac{|x|}{2R}}\le Me^{-\frac{|x|}{R}}. \end{align*}$$

The same argument also shows that for every x such that $|x|\ge 1$ and for every $k\ge k_1$ one has $g_k(x)\le g_k(0)(g_k(x/|x|)/g_k(0))^{|x|}\le M \left (\frac {M}{m}\right )^{|x|}$ , and hence a uniform bound for $|x|\le 2R$ . The convergence of integrals then follows from dominated convergence.

The ‘in particular’ follows from applying the result to the log-concave function $y\mapsto g_k(y) e^{x\cdot y}$ .

Proof. If $\mathcal {L}_p(f)\equiv 0$ , then ${\textrm {dom}} (L\mathcal {L}_p(f))=\mathbb {R}^n$ and the claim is trivial. We now suppose that $\mathcal {L}_p (f) \not \equiv 0$ . Note that

So, without loss of generality, it suffices to prove that

(2.4)

Assume that $\int _{\mathbb {R}^n} {\mathcal {L}}_p( f) =\infty $ . Since $\mathcal {L}_p(f)$ is log-concave, from Fact 2.1, there exists $a\in \mathbb {R}^n$ and a direction $u\in \mathbb {S}^{n-1}$ such that $\mathcal {L}_p(f)(a+tu)$ does not tend to $0$ as $t\to +\infty $ . But the log-concavity of $\mathcal {L}_p(f)$ implies that $\mathcal {L}_p(f)(a+tu)$ has a limit in $(0,+\infty ]$ . We deduce that $L(f^{1/p}) (a+tu) \to \ell \in [0, \infty )$ , as $t\to +\infty $ .

Let us introduce the nonnegative function $g(x)=e^{a\cdot x} f^{1/p}(x)$ , for which we have $L(g)(tu)\to \ell $ . Introduce the open half-space $H^+=\{x\in \mathbb {R}^n\,; \; x\cdot u>0\}$ . We have

$$ \begin{align*}Lg (tu) =\int_{\mathbb{R}^n} g(x)\, e^{t u\cdot x}\, dx \ge \int_{H^+} g(x)\, e^{t u\cdot x}\, dx. \end{align*} $$

By monotone convergence, we have

$$ \begin{align*}\lim_{t\to \infty}\int_{H^+} g(x) \, e^{t u\cdot x} \,dx = \int_{H^+} \big( g\times \infty ).\end{align*} $$

Therefore, $g=0$ almost everywhere on $H^+$ , and so $\textrm {supp} (g)\subseteq \mathbb {R}^n \setminus H^+$ . Since $\mathrm {supp}(g)=\mathrm {supp}(f)$ , by definition, we also have that $\mathrm {supp}(f)$ is contained in the convex set $\mathbb {R}^n \setminus H^+$ , whose interior does not contain the origin. Thus, we have proved that $0\notin {\text {int co }}(\mathrm {supp}(f))$ .

Assuming that f is log-concave and integrable, we can prove the converse implication in (2.4). Notice that, by hypothesis, we have, from (2.1), that $f(x) \leq Ce^{-c|x|}$ . Thus, $f^{1/p}(x)\leq C^\prime e^{-c^\prime |x|}$ , and so $f^{1/p}$ is integrable and more generally, $\mathcal {L}_p(f)>0$ in a neighbourhood of zero.

If $0 \notin {\text {int co }}(\mathrm {supp}(f))$ , then there exists $u\in \mathbb {S}^{n-1}$ such that $\mathrm {supp}(f) \subseteq H^-:=\{x\in \mathbb {R}^n; x\cdot u \leq 0\}$ . Then,

$$ \begin{align*}L(f^{\frac 1p})(tu)=\int_{H^-}f^{1/p}(x)e^{tu\cdot x}dx.\end{align*} $$

We deduce from dominated convergence that $\lim _{t\to \infty } L(f^{\frac 1p})(tu) = 0$ . Therefore, the log-concave function $\mathcal {L}_p(f)\not \equiv 0$ does not tend to zero at infinity, and so $\int _{\mathbb {R}^n} \mathcal {L}_p(f) = \infty $ .

Proof. We give two different proofs of the property $1.$

It can be seen as a direct consequence of Proposition 2.6. Indeed, since $f\not \equiv 0$ , the support $\mathrm {supp}(f)$ cannot be contained in an affine hyperplane, since it is of nonzero measure, and therefore, its convex hull is of nonempty interior.

We give an alternative proof that relies on Fact 2.3. Define the function $F = -\log \mathcal {L}_p(f) = (-q)\log L(f^{1/p}):\mathbb {R}^n\to \mathbb {R}\cup \{\infty \}.$ This function is convex, continuous on the interior of its domain, and from Fatou’s lemma, it is lower-semi-continuous on its domain. Assume that the domain of $L\mathcal {L}_p(f)=L(e^{-F})$ is empty. Then, by Fact 2.3, F must be affine along some line. Therefore, there exists $u\in \mathbb {S}^{n-1}$ , $v\in u^\bot $ and $\alpha ,\beta \in \mathbb {R}$ such that for all $t\in \mathbb {R}$ , $\log L(f^{1/p})(tu+v) = \alpha t+ \beta $ , or equivalently,

(2.5) $$ \begin{align} \int_{\mathbb{R}^n}f^{1/p}(y)e^{(tu+v)\cdot y}dy = e^{\alpha t +\beta}. \end{align} $$

We now use Fubini’s theorem; by defining the function

$$ \begin{align*}g(s)=\int_{u^\perp}f^{1/p}(su+w)e^{v\cdot w}dw,\qquad\forall s\in \mathbb{R},\end{align*} $$

we deduce, from (2.5), that

$$ \begin{align*}\int_{\mathbb{R}}g(s+\alpha) e^{ts}ds=e^{\beta}.\end{align*} $$

This means that the Laplace transform of $s\mapsto g(s+\alpha )$ is constant, which implies that $g\equiv 0$ , since otherwise the Laplace transform is strictly convex. In turn, this implies that f is zero almost everywhere on $u^\perp +su$ for almost all s, contradicting $f\not \equiv 0$ .

We now move on to the proof of 2. We assume that $\mathcal {L}_p(f)\not \equiv 0$ since all properties require it, explicitly or implicitly. From Fact 2.2 applied to the log-concave function $\mathcal {L}_p(f)$ , we have $(i)\Leftrightarrow (ii)\Rightarrow (iii)\Rightarrow (iv)\Leftrightarrow (v)$ , using the smoothness and (strict) convexity of $L(\mathcal {L}_p(f))$ . The presence of q is immaterial in the Laplace transform. Obviously, $(iii)$ implies $(i)$ . Finally, assume $(v)$ . This implies that $z\mapsto \log L(\mathcal {L}_p(f))(z)$ has a critical point at $s_0$ , and this point has therefore to be the (unique) point where the function attains its infimum. In particular, we have $(i)$ .

Fact 2.8. Let f be a nonnegative function on $\mathbb {R}^n$ and $p\in (0,1)$ . Then we have

$$ \begin{align*}\int_{\mathbb{R}^n} f = \infty \Longrightarrow \inf_z \int_{\mathbb{R}^n}\mathcal{L}_p(\tau_z f) = 0.\end{align*} $$

If f is log-concave, the converse is also true.

Proof. Note that we can enforce $f\not \equiv 0$ , since $f\equiv 0 \Rightarrow \mathcal {L}_p(f)\equiv \infty $ .

Let us assume that $\inf _z \int _{\mathbb {R}^n}\mathcal {L}_p(\tau _z f)> 0$ and prove that f is integrable. The hypothesis gives $\inf _z L(\mathcal {L}_p(f))(z)>0$ ; hence, from Proposition 2.7, we must have $0\in \textrm {int}(\mathrm {supp}(\mathcal {L}_p(f)))$ . Thus, we can find $r>0$ so that $[-r,r]^n \subset \textrm {int}(\mathrm {supp}(\mathcal {L}_p(f)))$ . We then obtain for $x\in [-r,r]$ that $L(f^{\frac {1}{p}})(x) \in [0,\infty )$ ; that is, $[-r,r]^n \subset \textrm {int}({\textrm {dom}}(L(f^{\frac {1}{p}})))$ . Since $\mathcal {L}_p(f)$ is log-concave, it is continuous on the interior of its domain. Consequently, $L(f^{\frac {1}{p}})$ is bounded on $[-r,r]^n$ . Observe then that

$$ \begin{align*} \infty &> \int_{[-r,r]^n}L(f^{\frac{1}{p}})(x)dx = \int_{\mathbb{R}^n}f^{\frac{1}{p}}(y) \int_{\{\|x\|_\infty \le r\}} e^{x\cdot y} dx dy \\ &=2^n\int_{\mathbb{R}^n}f^{\frac{1}{p}}(y) \prod_{i=1}^n \frac{\sinh(ry_i)}{y_i} dy. \end{align*} $$

We also note that $\int _{\mathbb {R}}\left (\frac {\sinh (y)}{y}\right )^{\frac {p}{p-1}}dy < \infty $ , since $p/(p-1)<0$ . Finally, we obtain, from Hölder’s inequality,

$$ \begin{align*} \int_{\mathbb{R}^n}f(y)dy &= \int_{\mathbb{R}^n}\left[f^{\frac{1}{p}}(y) \prod_{i=1}^n \frac{\sinh(ry_i)}{y_i}\right]^p\left[\prod_{i=1}^n \frac{\sinh(ry_i)}{y_i}\right]^{-p}dy \\ &\leq \left(\int_{\mathbb{R}^n}f^{\frac{1}{p}}(y) \prod_{i=1}^n \frac{\sinh(ry_i)}{y_i} dy\right)^p\left(\int_{\mathbb{R}^n}\left[\prod_{i=1}^n \frac{\sinh(ry_i)}{y_i}\right]^{\frac{p}{p-1}}dy\right)^{1-p}, \end{align*} $$

and the claim follows from the above observations.

Conversely, assume that f is log-concave, with $0<\int _{\mathbb {R}^n} f <\infty $ . This implies that $f(x)\le a e^{-b |x|}$ for some constants $a,b>0$ . Thus, we have a similar upper bound for $f^{1/p}$ , and this implies that $L(f^{1/p})$ is finite in a neighborhood of the origin. In turn, this means that $\mathcal {L}_p(f)$ is strictly positive in a neighborhood of the origin, and therefore, by Proposition 2.7, the infimum of $L\mathcal {L}_p(f)$ is strictly positive.

Proof. If $\mathcal {L}_p(f)\equiv 0$ , then the equality is trivial. Let us assume that $\mathcal {L}_p(f) \not \equiv 0$ . The support of the log-concave function $\mathcal {L}_p(f)$ is a convex set with nonempty interior, and symmetric, so it contains the origin in its interior. Thus, by Proposition 2.7, the infimum is attained at a unique point $s_p(f)$ . On the other hand, $\mathcal {L}_p(f)$ has a well-defined barycenter, which is the origin. Therefore, we find that $s_p(f)=0$ , and the equality also follows in this case.

Fact 2.10. Let $f:\mathbb {R}^n\to [0,\infty )$ be a function such that $f \not \equiv 0$ . Then for every $x\in \mathbb {R}^n$ such that $x\in \textrm {int}(\mathrm {supp} (f^\square ))$ or $f^\square (x)=0$ , and thus for almost-every $x\in \mathbb {R}^n$ ,

(2.7) $$ \begin{align} f^\square(x)=\lim_{p\to0^+}\mathcal{L}_p(f)\left(\frac{x}{p}\right). \end{align} $$

Proof. Recall first the following classical fact. Let g be any function on $\mathbb {R}^n$ such that $g\not \equiv 0$ . Then, if $\|g\|_{\infty } = \infty $ , one has $\|g\|_{p^\prime } \to \infty $ (with no assumptions on g) as $p^\prime \to \infty $ . If $\|g\|_{\infty } < \infty $ and there exists $p_0$ such that $\|g\|_{p_0} <\infty $ , then $\|g\|_{p^\prime } \to \|g\|_\infty $ as $p^\prime \to \infty $ .

Fix $p\in (0,1)$ . For a fixed $x\in \mathbb {R}^n$ , we set $g_x(y) = e^{x\cdot y}f(y)$ and write $p^\prime = 1/p$ . With this notation, we have $\mathcal {L}_p(f)\left (\frac {x}{p}\right ) = \|g_x\|_{p^\prime }^{\frac {1}{p-1}}$ . Clearly, the exponent $\frac {1}{p-1}$ will not play such a serious role in the analysis. The key observation is that $\|g_x\|_{\infty } = \frac {1}{f^\square (x)}$ .

We will break the proof into two parts: $x_0\in \{f^\square =0\}$ and $x_0\in \textrm {int}(\textrm {supp} (f^\square ))$ . The first case is easy: if $x_0\in \{f^\square =0\}$ , then $\|g_{x_0}\|_\infty = \infty $ , and thus, as stated early, it holds $\|g_{x_0}\|_{p^\prime } \to \infty $ . We deduce that $\mathcal {L}_p(f)\left (\frac {x_0}{p}\right ) \to 0 (=f^\square (x_0)).$ Next, assume that $x_0\in \textrm {int}(\textrm {supp} (f^\square ))$ . It suffices to show

(2.8) $$ \begin{align} x_0\in \textrm{int}(\textrm{supp} (f^\square)) \Longrightarrow \int f(x) e^{x\cdot x_0}\, dx < \infty, \end{align} $$

which gives that $\|g_{x_0}\|_1<\infty $ and allows to conclude as recalled above. To prove (2.8), note that $\tau _{-x_0} (f^\square ) = (g_{x_0})^\square $ , so it suffices to consider the case $x_0=0$ . Since $f^\square $ is log-concave, we have then $f^\square (x) \ge c 1_{C B_2^n}(x)$ for some constant $c,C>0$ . Let S be a countable dense subset of the sphere. We have, by definition, that, for almost all $y\in \mathbb {R}^n$ , for all $x\in S$ ,

$$ \begin{align*}f(y) \le \frac1c e^{- C\, x\cdot y}.\end{align*} $$

By letting x approach $y/|y|$ , we find

$$ \begin{align*}f(y) \le \frac1c e^{- C |y|} \quad \text{for a.e }\, y.\end{align*} $$

Therefore, f is integrable, as wanted.

Proof. Like before, we start with the proof of $1.$ If $f^\square \equiv 0$ , then the claim is trivial, so in the sequel, we assume that $f^\square \not \equiv 0$ ; that is, the support of the log-concave function $f^\square $ has nonempty interior. Like in the proof of Proposition 2.6, we may shift f so that it suffices to prove

$$ \begin{align*}0 \in {\text{int co }}(\mathrm{supp}(f) )\Longrightarrow \int_{\mathbb{R}^n} f^\square <\infty.\end{align*} $$

When $\int _{\mathbb {R}^n} f^\square =\infty $ , it follows from Fact 2.1, since $f^\square $ is log-concave, that there exists $u,v\in \mathbb {R}^n$ , $v\neq 0$ , and $\ell \in (0,+\infty ]$ such that $f^\square (u+ t v)\to \ell $ as $t\to \infty $ . Consider the open half-space $H^-=\{ y\in \mathbb {R}^n\;; \; y\cdot v <0\}$ . By definition, we have that, for every $k\in \mathbb {N}$ ,

$$ \begin{align*} \frac{e^{u\cdot y}}{f(y)}\, e^{ k v \cdot y} \ge f^\square(u + k v), \quad \textrm{ for almost all } y\in \mathbb{R}^n. \end{align*} $$

But, when $y\in H^-$ , $e^{k v\cdot y} \to 0$ as $k\to \infty $ . Therefore, $f(y) =0$ for almost all $y\in H^-$ , that is, $\mathrm {supp}(f)\subseteq \{ x\in \mathbb {R}^n \;; \; x\cdot v \ge 0\}$ , and so $0 \notin {\text {int co }}(\mathrm {supp}(f) )$ .

We now give two proofs for the equality when f is $\log $ -concave and integrable.

We first note that it follows from Proposition 2.6 by taking limits. Indeed, we set $D_p(f)= {\textrm {dom}}\left (L\left (\mathcal {L}_p(f)\left (\frac {\cdot }{p}\right )\right )\right )$ and $D(f)={\textrm {dom}}(L (f^\square ))$ . Assume $0\in D(f)$ . From Fact 2.5, there exists $\delta ,N>0$ such that $\delta B_2^n \subset D_p(f)$ for $0<p<1/N$ . From Proposition 2.6, $ D_p(f)= \frac {1}{1-p}{\textrm {int}}(\mathrm {supp}(f))$ . Thus, $(1-p)\delta B_2^n \subset {\textrm {int}}(\mathrm {supp}(f))$ for every $0<p<1/N.$ Consequently, $0\in {\textrm {int}}(\delta B_2^n) \subset {\textrm {int}}(\mathrm {supp}(f))$ .

For a direct proof, note that for the integrable log-concave function $f\not \equiv 0$ , we have that $f(x) \leq Ce^{-c|x|}$ , and so in particular, $f^\square>0$ in a neighborhood of zero. If $0 \notin {\text {int co }}(\mathrm {supp}(f))$ , then there exists $u\in \mathbb {S}^{n-1}$ such that $\mathrm {supp}(f) \subseteq H^-:=\{x\in \mathbb {R}^n; x\cdot u \leq 0\}$ . Then

$$ \begin{align*}f^\square(-tu) = \textrm{ess}\!\inf_{x\in H^-} \frac{e^{-t x \cdot u}}{f(x)}\ge \frac1C .\end{align*} $$

Therefore, the log-concave function $f^\square \not \equiv 0$ does not tend to zero at infinity, and hence, $\int _{\mathbb {R}^n} f^\square = \infty $ .

For the proof of $2.$ , this is, as before, a straightforward application of Fact 2.2 to the log-concave function $g=f^\square $ .

Fact 2.12. Let f be a nonnegative function on $\mathbb {R}^n$ . Then, we have

$$ \begin{align*}\int_{\mathbb{R}^n} f = \infty \Longrightarrow \inf_z \int_{\mathbb{R}^n}(\tau_z f)^\square = 0.\end{align*} $$

If f is log-concave, the converse is also true.

Proof. If $f\equiv 0$ , both implications are trivial, so we assume $f\not \equiv 0$ .

We will prove the contrapositive. By Proposition 2.11, the function $f^\square $ contains the origin in the interior of its support. Then (2.8) with $x_0=0$ gives the desired conclusion $\int f<\infty $ . Let us mention that one can alternatively take the limit as $p\to 0^+$ directly in Fact 2.8, using Fact 2.5, Proposition 2.7 and Fact 2.10.

Conversely, assume that f is log-concave, $f\not \equiv 0$ and that $\int _{\mathbb {R}^n} f <\infty $ . This means from (2.1) that $f(x)\le a e^{-b |x|}$ for some constants $a,b>0$ . This implies that $f^\circ $ , and thus, $f^\square $ is strictly positive in a neighborhood of the origin, and therefore, by Proposition 2.11, the infimum of $Lf^\square $ is strictly positive.

Proof. For ease of presentation, we set $g=g_\infty $ . We recall from Fact 2.5 that $Lg_k(x) \to Lg(x)$ for every $x\in \mathbb {R}^n$ .

For each k, $Lg_k:\mathbb {R}^n\to \mathbb {R}\cup \{\infty \}$ is a lower-semi-continuous, strictly convex function, and by hypothesis, ${\textrm {dom}}(Lg_k)\neq \emptyset $ . Furthermore, the assumption that the infimum is not $0$ yields that the infimum of $Lg_k$ is obtained at a unique point, that we denote by $z(g_k)$ , on its domain, which is open, via Fact 2.2. We break the remaining proof into two steps. First, we show that $\lim _{k\to \infty } z(g_k) =z(g)$ . Finally, we show that

(2.10) $$ \begin{align}\lim_{k\to\infty}\inf_z Lg_k(z) = \inf_z Lg(z). \end{align} $$

By Fact 2.4, there exists a closed ball $B(z(g),\alpha )\subset {\textrm {dom}}(Lg)$ , $\alpha>0$ , on which the convergence of $Lg_k$ to $Lg$ is uniform. Recall domains are open here. We parameterize the boundary of $B(z(g),\alpha )$ as $z(g)+\alpha \theta $ for $\theta \in \mathbb {S}^{n-1}$ . We have that $Lg(z(g)+\alpha \theta )>Lg(z(g))$ . Since $Lg$ is continuous on $B(z(g),\alpha )$ , it follows that

$$\begin{align*}r:=\inf_{\|x-z(g)\|=\alpha}(Lg(x)-Lg(z(g)))=\inf_{\theta\in \mathbb{S}^{n-1}}(Lg(z(g)+\alpha\theta)-Lg(z(g)))>0. \end{align*}$$

Since the convergence is uniform on $B(z(g),\alpha )$ , there exists J such that for every $k\ge J$ and every $x\in B(z(g),\alpha )$ , one has $|Lg_k(x)-Lg(x)|\le r/4$ . Thus, for every $\theta \in \mathbb {S}^{n-1}$ and $k\ge J$ , one has

$$\begin{align*}r_k:=\inf_{\theta\in \mathbb{S}^{n-1}}Lg_k(z(g)+\alpha\theta)-Lg_k(z(g))\ge \inf_{\theta\in \mathbb{S}^{n-1}}Lg(z(g)+\alpha\theta)-Lg(z(g))-\frac{r}{2}= \frac{r}{2}. \end{align*}$$

By convexity, the map $t\mapsto \frac {Lg_k(z(g)+t\alpha \theta )-Lg_k(z(g))}{t}$ is nondecreasing. Thus, for every $t\ge 1$ , one has

$$\begin{align*}Lg_k(z(g)+t\alpha\theta)-Lg_k(z(g))\ge t(Lg_k(z(g)+\alpha\theta)-Lg_k(z(g)))\ge tr_k\ge \frac{tr}{2}. \end{align*}$$

This implies that for any $x\notin B(z(g),\alpha )$ , $Lg_k(x)\ge Lg_k(z(g))+r/2$ , and thus $z(g_k)\in B(z(g),\alpha )$ for every $k\ge J$ . We have thus proved that, for any $\alpha $ such that $B(z(g),\alpha )\subset {\textrm {dom}}(Lg)$ , there exists J such that, for every $k\ge J$ , one has $\|z(g_k)-z(g)\|\le \alpha $ . This proves that the sequence $\{z(g_k)\}_k$ converges to $z(g)$ .

Finally, we prove (2.10). For $k\ge J$ , from the previous step of the proof, we have $z(g_k)\in B(z(g),\alpha )$ ; using that $Lg_k$ is minimal at $z(g_k)$ and $Lg$ is minimal at $z(g)$ , we get

$$ \begin{align*} Lg_k(z(g_k)) - Lg(z(g_k))\leq Lg_k(z(g_k))-Lg(z(g)) \leq Lg_k(z(g)) - Lg(z(g)). \end{align*} $$

It follows that $|Lg_k(z(g_k))-Lg(z(g))|\le \sup _{x\in B(z(g), \alpha )}|Lg_k(x)-Lg(x)|$ , which converges to $0$ when k tends to $+\infty $ by uniform convergence.

Proof. Since $f_t = (f_s)_{t-s}$ , it suffices to consider the case $s=0<t$ . It is readily checked from the definition of the heat semi-group, since $(2\pi t)^{-{n/2}} \int _{\mathbb {R}^n} e^{x\cdot u}\, e^{-|u-y|^2/2t}\, du = e^{t\frac {|x|^2}{2}}\, e^{x\cdot y} $ , that for any heat flow evolution $f_t = E_t f$ ,

$$ \begin{align*}L (f_t) = e^{t\frac{|x|^2}{2}} L f.\end{align*} $$

From Jensen’s inequality, we have that $(f_t)^{1/p}\le (f^{1/p})_t$ , from which we derive that

$$ \begin{align*}L((f_t)^{\frac{1}{p}})(x) \leq e^{t\frac{|x|^2}{2}}L(f^{\frac1p})(x).\end{align*} $$

Therefore, we have

$$ \begin{align*}\mathcal{L}_p(f_t)(x) \ge e^{qt\frac{|x|^2}{2}}\mathcal{L}_p (f)(x).\end{align*} $$

Since $e^{q\frac {t|x|^2}{2}}>0$ , the claim on the supports follows. To conclude, we use the equivalence of $(i)$ and $(ii)$ in Proposition 2.7.

Proof of Theorem 1.5.

If $f\equiv 0$ then $M_p(f_t)=0$ at all times and the result is trivial. When $\int _{\mathbb {R}^n} f = \infty $ , we have $\int _{\mathbb {R}^n} f_t = \infty $ at all times and so, by Fact 2.8, we also have that $M_p(f_t)=0$ at all times. Thus, in the sequel, we can assume that

$$ \begin{align*}0<\int_{\mathbb{R}^n} f < \infty.\end{align*} $$

Therefore, the result for $M_p$ amounts to proving that for any $t>0$ ,

(4.1) $$ \begin{align} \inf L \mathcal{L}_p(f) \le \inf L \mathcal{L}_p(f_t), \end{align} $$

and

(4.2) $$ \begin{align} \inf L \mathcal{L}_p(f_t) \le \Big( (2\pi)^{-n/2} \int_{\mathbb{R}^n} f \Big)^{q/p} \, \int_{\mathbb{R}^n} \mathcal{L}_p (\gamma_1). \end{align} $$

Indeed, by the semi-group property $f_t = (f_s)_{t-s}$ , inequality (4.1) improves to

$$ \begin{align*}\inf L\mathcal{L}_p(f_s)\le \inf L \mathcal{L}_p(f_t),\end{align*} $$

for any $0\le s < t$ .

So let us fix $t>0$ . We consider the following, classical, bounded compactly supported approximation procedure: for $k\in \mathbb {N}$ , set

$$ \begin{align*}f^{(k)}:= f \cdot 1_{|f|\le k} \cdot 1_{|x|\le k}.\end{align*} $$

We implicitly take k large enough so that $f^{(k)}\not \equiv 0$ . By Theorem 3.1, we have that

(4.3) $$ \begin{align} \inf L \mathcal{L}_p(f^{(k)}) \le \inf L \mathcal{L}_p((f^{(k)})_t). \end{align} $$

Fact 4.2. Let f be a nonnegative function, $f\not \equiv 0$ , and let $s\in [0,\infty )$ . If $\inf L \mathcal {L}_p(f_s)>0$ , then, as $k\to \infty $ , we have

$$ \begin{align*}\inf L \mathcal{L}_p((f^{(k)})_s) \to \inf L \mathcal{L}_p(f_s).\end{align*} $$

Proof. We have $f^{(k)}(x)\nearrow f(x)$ at every $x\in \mathbb {R}^n$ as $k\to \infty $ , and so, by monotone convergence, we have, $(f^{k})_s \nearrow f_s,$ and

$$ \begin{align*}\mathcal{L}_p((f^{(k)})_s) \searrow \mathcal{L}_p(f_s).\end{align*} $$

Note that this implies that $\inf L\mathcal {L}_p((f^{(k)})_s) \ge \inf L\mathcal {L}_p(f_s)>0$ . So, we can apply Proposition 2.13 to conclude.

We continue with the proof of (4.1). We can assume that

$$ \begin{align*}\inf L\mathcal{L}_p(f)>0 \quad \textrm{and}\quad \inf L\mathcal{L}_p(f_t)>0.\end{align*} $$

Indeed, if $\inf L\mathcal {L}_p(f)=0$ , there is nothing to prove. If $\inf L\mathcal {L}_p(f_t)=0$ , it follows from Lemma 4.1 that $\inf L\mathcal {L}_p(f)=0$ , and so the inequality is true in this case too. So, we can apply the Fact 4.2 with $s=0$ and $s=t$ , and conclude by passing to the limit in (4.3).

There remains to prove (4.2). We can again assume that $\inf L\mathcal {L}_p(f_t)>0$ . We have, from Theorem 3.1, that

$$ \begin{align*}\inf L \mathcal{L}_p((f^{(k)})_t)\le \lim_{s\to\infty} L \mathcal{L}_p((f^{(k)})_s) = \Big( (2\pi)^{-n/2} \int_{\mathbb{R}^n} f^{(k)}\Big)^{q/p} \int_{\mathbb{R}^n} \mathcal{L}_p (\gamma_1). \end{align*} $$

We obtain (4.2), by letting $k\to \infty $ , using Fact 4.2 in the left-hand side, and monotone convergence in the right-hand side.

Let us note, for consistency, that $\int _{\mathbb {R}^n} f= \int _{\mathbb {R}^n} f_t < \infty $ , and so $\Big (\int _{\mathbb {R}^n} f \Big )^{q/p}>0$ , when $\inf L \mathcal {L}_p(f_t)>0$ , because of Fact 2.8.