Analysis of the essential spectrum of singular matrix differential operators

A complete analysis of the essential spectrum of matrix-differential operators A of the form(0.1)(−ddtpddt+q−ddtb⁎+c⁎bddt+cD)in L2((α,β))⊕(L2((α,β)))n singular at β∈R∪{∞} is given; the coefficient functions p, q are scalar real-valued with p>0, b, c are vector-valued, and D is Hermitian matrix-va...

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Bibliographic Details
Published in:Journal of Differential Equations 2016-02, Vol.260 (4), p.3881-3926
Main Authors: Ibrogimov, O.O., Siegl, P., Tretter, C.
Format: Article
Language:English
Subjects:
Essential spectrum
Magnetohydrodynamics
Operator matrix
Schur complement
Stellar equilibrium model
System of singular differential equations
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Summary:A complete analysis of the essential spectrum of matrix-differential operators A of the form(0.1)(−ddtpddt+q−ddtb⁎+c⁎bddt+cD)in L2((α,β))⊕(L2((α,β)))n singular at β∈R∪{∞} is given; the coefficient functions p, q are scalar real-valued with p>0, b, c are vector-valued, and D is Hermitian matrix-valued. The so-called “singular part of the essential spectrum” σesss(A) is investigated systematically. Our main results include an explicit description of σesss(A), criteria for its absence and presence; an analysis of its topological structure and of the essential spectral radius. Our key tools are: the asymptotics of the leading coefficient π(⋅,λ)=p−b⁎(D−λ)−1b of the first Schur complement of (0.1), a scalar differential operator but non-linear in λ; the Nevanlinna behaviour in λ of certain limits t↗β of functions formed out of the coefficients in (0.1). The efficacy of our results is demonstrated by several applications; in particular, we prove a conjecture on the essential spectrum of some symmetric stellar equilibrium models.
ISSN:0022-0396
1090-2732
1090-2732
DOI:10.1016/j.jde.2015.10.050