Estimates of the asymptotic Nikolskii constants for spherical polynomials

Abstract: Let $\Pi_n^d$ denote the space of spherical polynomials of degree at most $n$ on the unit sphere $\mathbb{S}^d\subset \mathbb{R}^{d+1}$ that is equipped with the surface Lebesgue measure $d\sigma$ normalized by $\int_{\mathbb{S}^d} \, d\sigma(x)=1$. This paper establishes a close connection between the asymptotic Nikolskii constant, $$ \mathcal{L}^\ast(d):=\lim_{n\to \infty} \frac 1 {\dim \Pi_n^d} \sup_{f\in \Pi_n^d} \frac { |f|{L^\infty(\mathbb{S}^d)}}{|f|{L^1(\mathbb{S}^d)}},$$ and the following extremal problem: $$ \mathcal{I}\alpha:=\inf{a_k} \Bigl| j_{\alpha+1} (t)- \sum_{k=1}^\infty a_k j_{\alpha} \bigl( q_{\alpha+1,k}t/q_{\alpha+1,1}\bigr)\Bigr|{L^\infty(\mathbb{R}+)} $$ with the infimum being taken over all sequences ${a_k}{k=1}^\infty\subset \mathbb{R}$ such that the infinite series converges absolutely a.e. on $\mathbb{R}+$. Here $j_\alpha $ denotes the Bessel function of the first kind normalized so that $j_\alpha(0)=1$, and ${q_{\alpha+1,k}}{k=1}^\infty$ denotes the strict increasing sequence of all positive zeros of $j{\alpha+1}$. We prove that for $\alpha\ge -0.272$, $$\mathcal{I}\alpha= \frac{\int{0}^{q_{\alpha+1,1}}j_{\alpha+1}(t)t^{2\alpha+1}\,dt}{\int_{0}^{q_{\alpha+1,1}}t^{2\alpha+1}\,dt}= {}{1}F{2}\Bigl(\alpha+1;\alpha+2,\alpha+2;-\frac{q_{\alpha+1,1}^{2}}{4}\Bigr). $$ As a result, we deduce that the constant $\mathcal{L}^\ast(d)$ goes to zero exponentially fast as $d\to\infty$: [ 0.5^d\le \mathcal{L}^{*}(d)\le (0.857\cdots)^{d\,(1+\varepsilon_d)} \ \ \ \ \ \text{with $\varepsilon_d =O(d^{-2/3})$.} ]