Discrete spectrum (mathematics)

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 .

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.

[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.

[1]

[2]

[3]

[4]