!main_ta<script  src="/js/main/general/cookie-consent.js" ></script><script  src="/js/main/products/general/general.js" ></script><script  src="/js/main/general/header.js" ></script><script  src="/js/main/general/footer.js" ></script>gs!<link rel="stylesheet" href="/css/main/pages/academic-info.css"><title>Eigenvalues Eigenfunctions - quantum-physics | What's Your IQ</title><meta name="description" content="Learn eigenvalues eigenfunctions: quantum operators, spectral theory, Hermitian operators, wavefunctions, measurement postulate, linear algebra, Schrödinger equation, observables."></head><body class="academic-info-page" data-subject="quantum-physics"> !main_header! <nav class="academic-breadcrumb"><a href="/en/">Home</a><span class="separator">/</span><a href="/en/academic/">Academic</a><span class="separator">/</span><a href="/en/academic/quantum-physics/">Quantum Physics</a><span class="separator">/</span><a href="/en/academic/quantum-physics/explained/">Topics</a><span class="separator">/</span><a href="/en/academic/quantum-physics/explained/operators-and-observables/">Operators And Observables</a><span class="separator">/</span><span class="current">Eigenvalues Eigenfunctions</span></nav><div class="academic-info-container"><header class="page-header">  <h1>Eigenvalues Eigenfunctions</h1>  <p class="page-subtitle">Fundamental concepts linking quantum observables to operator theory and system states</p></header><nav class="table-of-contents">  <h2>Contents</h2>  <ol>  <li><a href="#introduction">Introduction</a></li>  <li><a href="#operators-in-quantum-mechanics">Operators in Quantum Mechanics</a></li>  <li><a href="#eigenvalue-eigenfunction-definition">Eigenvalue and Eigenfunction: Definition</a></li>  <li><a href="#hermitian-operators-and-spectrum">Hermitian Operators and Spectrum</a></li>  <li><a href="#physical-interpretation">Physical Interpretation</a></li>  <li><a href="#measurement-postulate">Measurement Postulate</a></li>  <li><a href="#schrodinger-equation-application">Schrödinger Equation Application</a></li>  <li><a href="#degeneracy-and-orthogonality">Degeneracy and Orthogonality</a></li>  <li><a href="#spectral-decomposition-theorem">Spectral Decomposition Theorem</a></li>  <li><a href="#examples-of-operators">Examples of Operators</a></li>  <li><a href="#numerical-methods">Numerical Methods</a></li>  <li><a href="#summary">Summary</a></li>  <li><a href="#references">References</a></li>  </ol></nav><main class="article-content">  <section id="introduction">  <h2>Introduction</h2>  <p>Eigenvalues and eigenfunctions form the mathematical bedrock of quantum mechanics. Operators represent observables. Eigenvalues correspond to measurable quantities. Eigenfunctions describe quantum states with definite measurement outcomes. This framework enables prediction of experimental results and underpins quantum theory.</p>  <blockquote>   <p>"The quantum state is described by a wavefunction which is an eigenfunction of an observable operator, revealing the quantized nature of physical quantities." -- P. A. M. Dirac</p>  </blockquote>  </section>  <section id="operators-in-quantum-mechanics">  <h2>Operators in Quantum Mechanics</h2>  <h3>Definition of Operators</h3>  <p>Operators: linear mappings on Hilbert space. Act on state vectors (wavefunctions). Represent physical observables such as position, momentum, energy.</p>  <h3>Types of Operators</h3>  <p>Hermitian (self-adjoint) operators: correspond to measurable quantities. Unitary operators: preserve norm, represent transformations. Projection operators: represent measurement outcomes.</p>  <h3>Operator Properties</h3>  <p>Linearity: \( \hat{O}(a\psi + b\phi) = a\hat{O}\psi + b\hat{O}\phi \). Adjoint: \( \hat{O}^\dagger \) defined by \( \langle \phi | \hat{O}\psi \rangle = \langle \hat{O}^\dagger \phi | \psi \rangle \). Hermitian: \( \hat{O} = \hat{O}^\dagger \).</p>  </section>  <section id="eigenvalue-eigenfunction-definition">  <h2>Eigenvalue and Eigenfunction: Definition</h2>  <h3>Mathematical Formulation</h3>  <p>Given operator \( \hat{O} \), eigenvalue \( \lambda \), eigenfunction \( \psi \):</p>  <pre><code> \hat{O} \psi = \lambda \psi</code></pre>  <p>Eigenfunction: nonzero function satisfying above. Eigenvalue: scalar associated to eigenfunction.</p>  <h3>Hilbert Space Context</h3>  <p>Eigenfunctions belong to Hilbert space \( \mathcal{H} \). Usually normalized: \( \langle \psi | \psi \rangle = 1 \). Eigenvalues are real for Hermitian operators.</p>  <h3>Spectrum Classification</h3>  <p>Discrete spectrum: isolated eigenvalues. Continuous spectrum: ranges of values. Residual spectrum: pathological cases excluded from physical operators.</p>  </section>  <section id="hermitian-operators-and-spectrum">  <h2>Hermitian Operators and Spectrum</h2>  <h3>Hermiticity and Reality of Eigenvalues</h3>  <p>Hermitian operators guarantee real eigenvalues. Proof via inner product symmetry:<br>   \( \langle \psi | \hat{O} \psi \rangle = \langle \hat{O} \psi | \psi \rangle \Rightarrow \lambda = \lambda^* \)</p>  <h3>Orthogonality of Eigenfunctions</h3>  <p>Eigenfunctions of distinct eigenvalues are orthogonal:<br>   \( \langle \psi_m | \psi_n \rangle = 0 \) if \( \lambda_m \neq \lambda_n \).</p>  <h3>Completeness</h3>  <p>Set of eigenfunctions forms a complete basis in \( \mathcal{H} \). Any state expressible as linear combination of eigenfunctions.</p>  </section>  <section id="physical-interpretation">  <h2>Physical Interpretation</h2>  <h3>Observables and Measurement</h3>  <p>Operators represent physical observables. Eigenvalues represent possible measurement results. Eigenfunctions represent states with definite outcomes.</p>  <h3>Collapse Postulate</h3>  <p>Measurement collapses wavefunction to eigenfunction associated with observed eigenvalue. Probability given by projection squared.</p>  <h3>Expectation Values</h3>  <p>Expectation value for observable \( \hat{O} \) in state \( \psi \):<br>   \( \langle \hat{O} \rangle = \langle \psi | \hat{O} | \psi \rangle \).</p>  </section>  <section id="measurement-postulate">  <h2>Measurement Postulate</h2>  <h3>Postulate Statement</h3>  <p>Measurement outcome is eigenvalue \( \lambda \) of observable operator \( \hat{O} \). Result probabilistic unless state is eigenfunction.</p>  <h3>Probability Rule</h3>  <p>Probability of measuring \( \lambda \) when system in state \( \phi \):<br>   \( P(\lambda) = |\langle \psi_\lambda | \phi \rangle|^2 \) where \( \psi_\lambda \) eigenfunction.</p>  <h3>Post-Measurement State</h3>  <p>State collapses to eigenfunction \( \psi_\lambda \) corresponding to measurement outcome.</p>  </section>  <section id="schrodinger-equation-application">  <h2>Schrödinger Equation Application</h2>  <h3>Time-Independent Schrödinger Equation</h3>  <p>Eigenvalue problem for Hamiltonian operator \( \hat{H} \):<br>   \( \hat{H} \psi = E \psi \), where \( E \) is energy eigenvalue.</p>  <h3>Stationary States</h3>  <p>Eigenfunctions \( \psi \) are stationary states with definite energies. Time evolution:<br>   \( \Psi(x,t) = \psi(x) e^{-iEt/\hbar} \).</p>  <h3>Energy Quantization</h3>  <p>Discrete eigenvalues correspond to quantized energy levels. Basis for atomic spectra and quantum stability.</p>  </section>  <section id="degeneracy-and-orthogonality">  <h2>Degeneracy and Orthogonality</h2>  <h3>Degeneracy</h3>  <p>Multiple eigenfunctions share same eigenvalue. Degeneracy arises from symmetry or conserved quantities.</p>  <h3>Orthogonality Within Degenerate Subspace</h3>  <p>Degenerate eigenfunctions can be chosen orthogonal. Gram-Schmidt procedure applicable.</p>  <h3>Physical Implications</h3>  <p>Degeneracy linked to conserved quantum numbers. Splitting via perturbations breaks degeneracy (lifting).</p>  </section>  <section id="spectral-decomposition-theorem">  <h2>Spectral Decomposition Theorem</h2>  <h3>Theorem Statement</h3>  <p>Hermitian operator \( \hat{O} \) can be decomposed as:<br>   \( \hat{O} = \sum_n \lambda_n |\psi_n \rangle \langle \psi_n| \) discrete,<br>   or integral over continuous spectrum.</p>  <h3>Projection Operators</h3>  <p>Each \( |\psi_n \rangle \langle \psi_n| \) is projection operator onto eigenspace.</p>  <h3>Application to Quantum Dynamics</h3>  <p>Used in propagators, time evolution, and measurement theory.</p>  <table style="width: 100%; border-collapse: collapse; margin: 1.5em 0;">   <tr style="background-color: #f5f5f5;">   <th style="border: 1px solid #ddd; padding: 8px;">Operator Type</th>   <th style="border: 1px solid #ddd; padding: 8px;">Spectral Decomposition</th>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Discrete Spectrum</td>   <td style="border: 1px solid #ddd; padding: 8px;">Sum over eigenvalues and projectors</td>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Continuous Spectrum</td>   <td style="border: 1px solid #ddd; padding: 8px;">Integral over spectral measure</td>   </tr>  </table>  </section>  <section id="examples-of-operators">  <h2>Examples of Operators</h2>  <h3>Position Operator \( \hat{x} \)</h3>  <p>Acts multiplicatively: \( \hat{x} \psi(x) = x \psi(x) \). Eigenfunctions: delta functions \( \delta(x - x_0) \). Eigenvalues: position \( x_0 \).</p>  <h3>Momentum Operator \( \hat{p} \)</h3>  <p>Defined by \( \hat{p} = -i \hbar \frac{d}{dx} \). Eigenfunctions: plane waves \( e^{ipx/\hbar} \). Eigenvalues: momentum \( p \).</p>  <h3>Hamiltonian Operator \( \hat{H} \)</h3>  <p>Energy operator, typically \( \hat{H} = \frac{\hat{p}^2}{2m} + V(\hat{x}) \). Eigenvalues: energy levels. Eigenfunctions: stationary states.</p>  </section>  <section id="numerical-methods">  <h2>Numerical Methods</h2>  <h3>Matrix Representation</h3>  <p>Operators represented as matrices in finite basis. Eigenvalue problems reduce to matrix diagonalization.</p>  <h3>Common Algorithms</h3>  <p>Power iteration, QR algorithm, Lanczos method. Efficient for sparse or large matrices.</p>  <h3>Applications</h3>  <p>Computing energy spectra, simulating quantum systems, solving Schrödinger equation numerically.</p>  <pre><code>Algorithm: Power IterationInput: matrix A, initial vector v0Repeat: v_{k+1} = A v_k / ||A v_k||Until convergenceOutput: dominant eigenvalue and eigenvector</code></pre>  </section>  <section id="summary">  <h2>Summary</h2>  <p>Eigenvalues and eigenfunctions connect quantum observables and measurable quantities. Hermitian operators ensure real eigenvalues and orthogonal eigenfunctions. Measurement collapses states onto eigenfunctions with probabilities linked to projections. Spectral theorem underpins operator decompositions. Applications span energy quantization, dynamics, and numerical simulations.</p>  </section>  <section id="references">  <h2>References</h2>  <ul>   <li>J. J. Sakurai and J. Napolitano, <i>Modern Quantum Mechanics</i>, 2nd ed., Addison-Wesley, 2010, pp. 45-89.</li>   <li>R. Shankar, <i>Principles of Quantum Mechanics</i>, 2nd ed., Springer, 1994, pp. 189-237.</li>   <li>L. E. Ballentine, <i>Quantum Mechanics: A Modern Development</i>, World Scientific, 1998, pp. 101-150.</li>   <li>M. Reed and B. Simon, <i>Methods of Modern Mathematical Physics, Vol. 1: Functional Analysis</i>, Academic Press, 1980, pp. 245-290.</li>   <li>E. Merzbacher, <i>Quantum Mechanics</i>, 3rd ed., Wiley, 1998, pp. 75-120.</li>  </ul>  </section></main></div> !main_footer!