Essential self-adjointness of strongly singular homogeneous polyharmonic operators

Abstract

We consider essential self-adjointness of strongly singular, homogeneous, polyharmonic operators of the form \[ Tm = ((-)m + c|x|-2m)|C0∞(Rn \0\), m,n∈N,\ n 2,\ c∈R, \] in L2(Rn; dn x), with special emphasis on the biharmonic case m=2 and the case m=3. In the biharmonic case m=2 we prove the sharp result that T2 is essentially self-adjoint if and only if \[ c cases 3(n+2)(6-n), & 2 n 5,\\[4pt] -(n+4)n(n-4)(n-8)16, & n 6. cases \] In particular, in the special (nonsingular) case c=0, (-)2|C0∞(Rn \0\) is essentially self-adjoint in L2(Rn; dn x) if and only if n 8. Similarly, we derive the analogous sharp essential self-adjointness result for T3 for all n 2. Our methods extend to homogeneous polyharmonic differential operators, but certain nontrivial subtleties arise. In particular, the natural expectation that for each m,n∈N, n 2, there exists cm,n∈R such that ((-)m + c|x|-2m)|C0∞(Rn \0\) is essentially self-adjoint in L2(Rn; dn x) if and only if c cm,n is false. For example, for n=20 we prove that \[ ((-)5 + c|x|-10)|C0∞(R20 \0\) \] is essentially self-adjoint in L2(R20; d20 x) if and only if c∈ [0,β][γ,∞), where β ≈ 1.0436× 1010 and γ ≈ 1.8324× 1010 are the two real roots of a certain quartic equation with integer coefficients.