Discrete spectrum (mathematics)

Last updated November 03, 2020

In mathematics, specifically in spectral theory, a discrete spectrum of a closed linear operator is defined as the set of isolated points of its spectrum such that the rank of the corresponding Riesz projector is finite.

Definition

A point $\lambda \in \mathbb {C}$ in the spectrum $\sigma (A)$ of a closed linear operator $A:\,{\mathfrak {B}}\to {\mathfrak {B}}$ in the Banach space ${\mathfrak {B}}$ with domain ${\mathfrak {D}}(A)\subset {\mathfrak {B}}$ is said to belong to discrete spectrum $\sigma _{\mathrm {disc} }(A)$ of $A$ if the following two conditions are satisfied:^[1]

$\lambda$ is an isolated point in $\sigma (A)$ ;
The rank of the corresponding Riesz projector $P_{\lambda }={\frac {-1}{2\pi \mathrm {i} }}\oint _{\Gamma }(A-zI_{\mathfrak {B}})^{-1}\,dz$ is finite.

Here $I_{\mathfrak {B}}$ is the identity operator in the Banach space ${\mathfrak {B}}$ and $\Gamma \subset \mathbb {C}$ is a smooth simple closed counterclockwise-oriented curve bounding an open region $\Omega \subset \mathbb {C}$ such that $\lambda$ is the only point of the spectrum of $A$ in the closure of $\Omega$ ; that is, $\sigma (A)\cap {\overline {\Omega }}=\{\lambda \}.$

Relation to normal eigenvalues

The discrete spectrum $\sigma _{\mathrm {disc} }(A)$ coincides with the set of normal eigenvalues of $A$ :

\sigma _{\mathrm {disc} }(A)=\{{\mbox{normal eigenvalues of }}A\}.

^[2]^[3]^[4]

Relation to isolated eigenvalues of finite algebraic multiplicity

In general, the rank of the Riesz projector can be larger than the dimension of the root lineal ${\mathfrak {L}}_{\lambda }$ of the corresponding eigenvalue, and in particular it is possible to have $\mathrm {dim} \,{\mathfrak {L}}_{\lambda }<\infty$ , $\mathrm {rank} \,P_{\lambda }=\infty$ . So, there is the following inclusion:

\sigma _{\mathrm {disc} }(A)\subset \{{\mbox{isolated points of the spectrum of }}A{\mbox{ with finite algebraic multiplicity}}\}.

In particular, for a quasinilpotent operator

Q:\,l^{2}(\mathbb {N} )\to l^{2}(\mathbb {N} ),\qquad Q:\,(a_{1},a_{2},a_{3},\dots )\mapsto (0,a_{1}/2,a_{2}/2^{2},a_{3}/2^{3},\dots ),

one has ${\mathfrak {L}}_{\lambda }(Q)=\{0\}$ , $\mathrm {rank} \,P_{\lambda }=\infty$ , $\sigma (Q)=\{0\}$ , $\sigma _{\mathrm {disc} }(Q)=\emptyset$ .

Relation to the point spectrum

The discrete spectrum $\sigma _{\mathrm {disc} }(A)$ of an operator $A$ is not to be confused with the point spectrum $\sigma _{\mathrm {p} }(A)$ , which is defined as the set of eigenvalues of $A$ . While each point of the discrete spectrum belongs to the point spectrum,

\sigma _{\mathrm {disc} }(A)\subset \sigma _{\mathrm {p} }(A),

the converse is not necessarily true: the point spectrum does not necessarily consist of isolated points of the spectrum, as one can see from the example of the left shift operator, $L:\,l^{2}(\mathbb {N} )\to l^{2}(\mathbb {N} ),\quad L:\,(a_{1},a_{2},a_{3},\dots )\mapsto (a_{2},a_{3},a_{4},\dots ).$ For this operator, the point spectrum is the unit disc of the complex plane, the spectrum is the closure of the unit disc, while the discrete spectrum is empty:

\sigma _{\mathrm {p} }(L)=\mathbb {D} _{1},\qquad \sigma (L)={\overline {\mathbb {D} _{1}}};\qquad \sigma _{\mathrm {disc} }(L)=\emptyset .

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References

↑ Reed, M.; Simon, B. (1978). Methods of modern mathematical physics, vol. IV. Analysis of operators. Academic Press [Harcourt Brace Jovanovich Publishers], New York.
↑ Gohberg, I. C; Kreĭn, M. G. (1960). "Fundamental aspects of defect numbers, root numbers and indexes of linear operators". American Mathematical Society Translations. 13: 185–264.
↑ Gohberg, I. C; Kreĭn, M. G. (1969). Introduction to the theory of linear nonselfadjoint operators. American Mathematical Society, Providence, R.I.
↑ Boussaid, N.; Comech, A. (2019). Nonlinear Dirac equation. Spectral stability of solitary waves. American Mathematical Society, Providence, R.I. ISBN 978-1-4704-4395-5.

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[1] Reed, M.; Simon, B. (1978). Methods of modern mathematical physics, vol. IV. Analysis of operators. Academic Press [Harcourt Brace Jovanovich Publishers], New York.

[2] Gohberg, I. C; Kreĭn, M. G. (1960). "Fundamental aspects of defect numbers, root numbers and indexes of linear operators". American Mathematical Society Translations. 13: 185–264.

[3] Gohberg, I. C; Kreĭn, M. G. (1969). Introduction to the theory of linear nonselfadjoint operators. American Mathematical Society, Providence, R.I.

[4] Boussaid, N.; Comech, A. (2019). Nonlinear Dirac equation. Spectral stability of solitary waves. American Mathematical Society, Providence, R.I. ISBN 978-1-4704-4395-5.

v t e Functional analysis (topics – glossary)
Spaces	Hilbert space Banach space Fréchet space topological vector space
Theorems	Hahn–Banach theorem closed graph theorem uniform boundedness principle Kakutani fixed-point theorem Krein–Milman theorem min-max theorem Gelfand–Naimark theorem Banach–Alaoglu theorem
Operators	bounded operator compact operator adjoint operator unitary operator Hilbert–Schmidt operator trace class unbounded operator
Algebras	Banach algebra C-algebra spectrum of a C-algebra operator algebra group algebra of a locally compact group von Neumann algebra
Open problems	invariant subspace problem Mahler's conjecture
Applications	Besov space Hardy space spectral theory of ordinary differential equations heat kernel index theorem calculus of variation functional calculus integral operator Jones polynomial topological quantum field theory noncommutative geometry Riemann hypothesis
Advanced topics	locally convex space approximation property balanced set Schwartz space weak topology barrelled space Banach–Mazur distance Tomita–Takesaki theory