Essential self-adjointness of even-order, strongly singular, homogeneous half-line differential operators (2311.09771v2)
Abstract: We consider essential self-adjointness on the space $C_0{\infty}((0,\infty))$ of even order, strongly singular, homogeneous differential operators associated with differential expressions of the type [ \tau_{2n}(c) = (-1)n \frac{d{2n}}{d x{2n}} + \frac{c}{x{2n}}, \quad x > 0, \; n \in \mathbb{N}, \; c \in \mathbb{R}, ] in $L2((0,\infty);dx)$. While the special case $n=1$ is classical and it is well-known that $\tau_2(c)\big|{C_0\infty((0,\infty))}$ is essentially self-adjoint if and only if $c \geq 3/4$, the case $n \in \mathbb{N}$, $n \geq 2$, is far from obvious. In particular, it is not at all clear from the outset that [ \text{ there exists } c_n \in \mathbb{R}, \, n \in \mathbb{N}, \text{ such that } \tau{2n}(c)\big|{C_0\infty((0,\infty))} \, \text{ is essentially self-adjoint if and only if } c \geq c_n. \tag{*}\label{0.1} ] As one of the principal results of this paper we indeed establish the existence of $c_n$, satisfying $c_n \geq (4n-1)!!\big/2{2n}$, such that property \eqref{0.1} holds. In sharp contrast to the analogous lower semiboundedness question, [ \text{ for which values of } c \, \text{\it is } \tau{2n}(c)\big|_{C_0{\infty}((0,\infty))} \, \text{ bounded from below?}, ] which permits the sharp (and explicit) answer $c \geq [(2n -1)!!]{2}\big/2{2n}$, $n \in \mathbb{N}$, the answer for \eqref{0.1} is surprisingly complex and involves various aspects of the geometry and analytical theory of polynomials. For completeness we record explicitly, [ c_1 = 3/4, \quad c_2= 45, \quad c_3 = 2240 \big(214+7 \sqrt{1009}\,\big)\big/27, ] and remark that $c_n$ is the root of a polynomial of degree $n-1$. We demonstrate that for $n=6,7$, $c_n$ are algebraic numbers not expressible as radicals over $\mathbb{Q}$ (and conjecture this is in fact true for general $n \geq 6$).