Are the Eigenvalues of a Unitary Operator of the Form e^i(a)?

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SUMMARY

The eigenvalues of a unitary operator U are definitively of the form e^i(a), where a is a real number. This conclusion arises from the properties of unitary operators, specifically that they preserve inner products, which implies that their eigenvalues must have a magnitude of 1. The proof leverages the spectral equation Uψ = aψ within a Hilbert space, confirming that the eigenvalues are indeed complex numbers on the unit circle in the complex plane.

PREREQUISITES
  • Understanding of unitary operators and their properties
  • Basic knowledge of linear algebra in finite-dimensional spaces
  • Familiarity with Hilbert spaces and eigenvalue equations
  • Concept of isometry and its implications in quantum mechanics
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  • Study the properties of unitary operators in quantum mechanics
  • Learn about the spectral theorem and its application to linear operators
  • Explore the concept of isometry in the context of functional analysis
  • Investigate the implications of eigenvalues in quantum state evolution
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This discussion is beneficial for physics students, particularly those studying quantum mechanics, mathematicians focusing on linear algebra, and anyone interested in the properties of unitary operators and their applications in Hilbert spaces.

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Homework Statement


A unitary operator U has the property
U(U+)=(U+)U=I [where U+ is U dagger and I is the identity operator]

Prove that the eigenvalues of a unitary operator are of the form e^i(a) with a being real.

NB: I haven't been taught dirac notation yet. Is there a way i can do this without it?



Homework Equations


U(U+)=(U+)U=I [where U+ is U dagger and I is the identity operator]



The Attempt at a Solution


Assume eigenvalues exist
U(a)=x(a) => (U+)U(a)=(U+)x(a) => (a)=(U+)x(a)??
 
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note that you don't need to understand Dirac notation, all you need to know is some basic linear algebra in finite dimensional space. hint: "of the form e^{i\theta}" means that magnitude of complex e-vals are 1
 
HINT: U unitary means U isometry. Assume the spectral equation

U\psi =a\psi (1)

has solutions in a Hilbert space \mathcal{H}.

Then use (1), the assumption regarding the space of solutions and the isometry condition to get the desired result.
 
Sorry I've never heard of isometry or the name spectral equation. I just know it as the eigenvalue equation.
 
Isometry means <x,y>=<Ux,Uy>. Why is this true for U unitary? Once you believe it's true set y=x and x to be an eigenvector of U. What do you conclude?
 

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