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resolvents

Resolvents are a fundamental concept in functional analysis and operator theory. For a linear operator T on a Banach space, a complex number λ lies in the resolvent set ρ(T) if T − λI is bijective and its inverse (T − λI)−1 is a bounded operator. The spectrum σ(T) is the complement of ρ(T) in the complex plane. The definition extends to unbounded operators in the same spirit, with the inverse required to exist on the whole space and be bounded.

The resolvent operator is defined by R(λ; T) = (T − λI)−1 for λ in ρ(T). It depends analytically

In finite dimensions, T is represented by a matrix and σ(T) consists of its eigenvalues; ρ(T) is

Applications of resolvents include the spectral theorem and functional calculus, analysis of evolution equations via semigroups,

on
λ;
the
map
λ
↦
R(λ;
T)
is
holomorphic
on
ρ(T)
with
values
in
the
bounded
operators.
A
key
relation
is
the
resolvent
identity:
R(λ;
T)
−
R(μ;
T)
=
(μ
−
λ)
R(λ;
T)
R(μ;
T)
for
λ,
μ
in
ρ(T).
As
λ
approaches
the
spectrum,
the
norm
of
the
resolvent
tends
to
infinity,
reflecting
the
failure
of
invertibility.
the
complement
in
the
complex
plane,
and
R(λ;
T)
=
(T
−
λI)−1
when
defined.
For
self-adjoint
or
normal
operators
on
Hilbert
spaces,
the
spectrum
lies
on
the
real
axis
(or
the
spectrum
is
contained
in
the
real
axis
for
self-adjoint
operators),
and
the
resolvent
is
well-behaved
off
this
set.
and
perturbation
theory.
They
provide
tools
for
contour
integral
representations
of
functions
of
operators
and
for
understanding
how
small
changes
in
an
operator
affect
its
spectrum.