Essential self-adjointness of even-order, strongly singular, homogeneous half-line differential operators
Abstract
We consider essential self-adjointness on the space C0∞((0,∞)) of even order, strongly singular, homogeneous differential operators associated with differential expressions of the type \[ τ2n(c) = (-1)n d2nd x2n + cx2n, x > 0, \; n ∈ N, \; c ∈ R, \] in L2((0,∞);dx). While the special case n=1 is classical and it is well-known that τ2(c)|C0∞((0,∞)) is essentially self-adjoint if and only if c ≥ 3/4, the case n ∈ N, n ≥ 2, is far from obvious. In particular, it is not at all clear from the outset that \[ there exists cn ∈ R, \, n ∈ N, such that τ2n(c)|C0∞((0,∞)) \, is essentially self-adjoint if and only if c ≥ cn. *0.1 \] As one of the principal results of this paper we indeed establish the existence of cn, satisfying cn ≥ (4n-1)!!/22n, such that property 0.1 holds. In sharp contrast to the analogous lower semiboundedness question, \[ for which values of c \, is τ2n(c)|C0∞((0,∞)) \, bounded from below?, \] which permits the sharp (and explicit) answer c ≥ [(2n -1)!!]2/22n, n ∈ N, the answer for 0.1 is surprisingly complex and involves various aspects of the geometry and analytical theory of polynomials. For completeness we record explicitly, \[ c1 = 3/4, c2= 45, c3 = 2240 (214+7 1009\,)/27, \] and remark that cn is the root of a polynomial of degree n-1. We demonstrate that for n=6,7, cn are algebraic numbers not expressible as radicals over Q (and conjecture this is in fact true for general n ≥ 6).
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