!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>Time Independent Schrodinger - quantum-physics | What's Your IQ</title><meta name="description" content="Learn time independent schrodinger: quantum mechanics, eigenvalue problem, wavefunctions, potential energy, stationary states, energy quantization, quantum wells, particle in a box."></head><body class="academic-info-page" data-subject="quantum-physics"> !main_header! <nav class="academic-breadcrumb"><a href="/de/">Home</a><span class="separator">/</span><a href="/de/academic/">Academic</a><span class="separator">/</span><a href="/de/academic/quantum-physics/">Quantum Physics</a><span class="separator">/</span><a href="/de/academic/quantum-physics/explained/">Topics</a><span class="separator">/</span><a href="/de/academic/quantum-physics/explained/schrodinger-equation/">Schrodinger Equation</a><span class="separator">/</span><span class="current">Time Independent Schrodinger</span></nav><div class="academic-info-container"><header class="page-header">  <h1>Time Independent Schrodinger</h1>  <p class="page-subtitle">Fundamental eigenvalue equation describing stationary quantum states and energy quantization in non-relativistic systems</p></header><nav class="table-of-contents">  <h2>Contents</h2>  <ol>  <li><a href="#introduction">Introduction</a></li>  <li><a href="#derivation">Derivation and Formulation</a></li>  <li><a href="#mathematical-structure">Mathematical Structure</a></li>  <li><a href="#physical-interpretation">Physical Interpretation</a></li>  <li><a href="#applications">Applications in Quantum Systems</a></li>  <li><a href="#boundary-conditions">Boundary Conditions and Quantization</a></li>  <li><a href="#potential-wells">Potential Wells and Barriers</a></li>  <li><a href="#eigenvalues-eigenfunctions">Eigenvalues and Eigenfunctions</a></li>  <li><a href="#approximation-methods">Approximation Methods</a></li>  <li><a href="#numerical-solutions">Numerical Solutions</a></li>  <li><a href="#limitations">Limitations and Extensions</a></li>  <li><a href="#examples">Worked Examples</a></li>  <li><a href="#references">References</a></li>  </ol></nav><main class="article-content">  <section id="introduction">  <h2>Introduction</h2>  <p>Time Independent Schrodinger Equation (TISE): fundamental quantum mechanics equation for stationary states. Separates time variable to yield energy eigenvalue problem. Core to predicting energy spectra, wavefunctions, and quantum behavior in conservative potentials.</p>  <blockquote><p>"If we are to understand the world of the very small, we must understand the language of wavefunctions and their governing equations." -- Erwin Schrödinger</p></blockquote>  </section>  <section id="derivation">  <h2>Derivation and Formulation</h2>  <h3>Starting Point: Time Dependent Schrodinger Equation</h3>  <p>Original equation: <em>iħ ∂Ψ/∂t = ĤΨ</em>. Assumes Hamiltonian Ĥ time-independent. Separation of variables: Ψ(x,t) = ψ(x)φ(t).</p>  <h3>Separation of Variables</h3>  <p>Inserting Ψ(x,t) into TDSE yields: iħ (1/φ) dφ/dt = (1/ψ) Ĥ ψ = E (constant). Implies φ(t) = e^(-iEt/ħ) and time-independent spatial equation for ψ(x).</p>  <h3>Time Independent Schrodinger Equation</h3>  <p>Resulting eigenvalue equation: Ĥ ψ(x) = E ψ(x). Represents stationary states with definite energy E. Central to quantum mechanics formalism.</p>  <pre><code>Ĥ ψ(x) = E ψ(x)</code></pre>  </section>  <section id="mathematical-structure">  <h2>Mathematical Structure</h2>  <h3>Hamiltonian Operator</h3>  <p>Ĥ = - (ħ² / 2m) ∇² + V(x). Kinetic term: Laplacian operator ∇² acting on ψ. Potential term: multiplication by V(x).</p>  <h3>Eigenvalue Problem</h3>  <p>Linear operator Ĥ acts on Hilbert space of square-integrable functions. Eigenvalues E are real, eigenfunctions ψ orthogonal and complete.</p>  <h3>Boundary Conditions</h3>  <p>ψ must be continuous, single-valued, and square-integrable. Physical solutions require normalization ∫|ψ|² dx = 1.</p>  <pre><code>Normalization: ∫ |ψ(x)|² dx = 1</code></pre>  </section>  <section id="physical-interpretation">  <h2>Physical Interpretation</h2>  <h3>Stationary States</h3>  <p>ψ(x) represents spatial probability amplitude. |ψ(x)|² is probability density of particle position. Stationary states have time-independent probability distributions.</p>  <h3>Energy Quantization</h3>  <p>Discrete allowed energies emerge from boundary conditions. Explains atomic spectra, molecular vibrations, and quantum confinement effects.</p>  <h3>Quantum Observables</h3>  <p>Energy eigenvalues correspond to measurable energy levels. Eigenfunctions form basis for expanding general quantum states.</p>  </section>  <section id="applications">  <h2>Applications in Quantum Systems</h2>  <h3>Particle in a Box</h3>  <p>Infinite potential well with rigid boundaries. Simple model illustrating quantized energy levels and sinusoidal wavefunctions.</p>  <h3>Quantum Harmonic Oscillator</h3>  <p>Parabolic potential V(x)=½mω²x². Solutions yield ladder of equally spaced energy levels and Hermite polynomial eigenfunctions.</p>  <h3>Hydrogen-like Atoms</h3>  <p>Central Coulomb potential. Solutions provide atomic orbitals, energy levels, and radial/angular wavefunctions.</p>  </section>  <section id="boundary-conditions">  <h2>Boundary Conditions and Quantization</h2>  <h3>Physical Constraints</h3>  <p>Wavefunction continuity ensures finite probability. Derivative continuity maintains kinetic energy finiteness.</p>  <h3>Quantization Mechanism</h3>  <p>Discrete energy levels arise from boundary conditions restricting allowed ψ forms. Integral quantum numbers index solutions.</p>  <h3>Examples of Boundary Conditions</h3>  <p>ψ(0) = ψ(L) = 0 for infinite wells. ψ → 0 as |x| → ∞ for bound states in finite potentials.</p>  </section>  <section id="potential-wells">  <h2>Potential Wells and Barriers</h2>  <h3>Infinite Potential Well</h3>  <p>V=0 inside region, infinite outside. Particle confined strictly; solutions are sine waves with nodes at boundaries.</p>  <h3>Finite Potential Well</h3>  <p>Finite barrier height allows tunneling and evanescent wave decay outside well. Energy levels fewer and shifted compared to infinite well.</p>  <h3>Potential Barrier and Tunneling</h3>  <p>Allows non-zero probability of crossing classically forbidden regions. Basis of quantum tunneling phenomena.</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;">Potential Type</th>   <th style="border: 1px solid #ddd; padding: 8px;">Energy Spectrum</th>   <th style="border: 1px solid #ddd; padding: 8px;">Wavefunction Behavior</th>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Infinite Well</td>   <td style="border: 1px solid #ddd; padding: 8px;">Discrete, infinite countable</td>   <td style="border: 1px solid #ddd; padding: 8px;">Sinusoidal, zero at boundaries</td>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Finite Well</td>   <td style="border: 1px solid #ddd; padding: 8px;">Discrete, finite number</td>   <td style="border: 1px solid #ddd; padding: 8px;">Sinusoidal inside, exponential decay outside</td>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Potential Barrier</td>   <td style="border: 1px solid #ddd; padding: 8px;">Continuum with resonances</td>   <td style="border: 1px solid #ddd; padding: 8px;">Partial reflection, tunneling probabilities</td>   </tr>  </table>  </section>  <section id="eigenvalues-eigenfunctions">  <h2>Eigenvalues and Eigenfunctions</h2>  <h3>Energy Eigenvalues</h3>  <p>Solutions E correspond to quantized energies allowed by potential and boundary conditions. Typically discrete for bound states, continuous for free particles.</p>  <h3>Wavefunction Properties</h3>  <p>Orthogonality: ∫ψ_m* ψ_n dx = δ_mn. Completeness: any state expanded as sum or integral over eigenfunctions.</p>  <h3>Normalization and Orthogonality</h3>  <pre><code>∫ ψ_m^*(x) ψ_n(x) dx = δ_{mn}</code></pre>  <p>Ensures probabilistic interpretation and mathematical rigor of solutions.</p>  </section>  <section id="approximation-methods">  <h2>Approximation Methods</h2>  <h3>WKB Approximation</h3>  <p>Semi-classical method for slowly varying potentials. Provides approximate eigenvalues and wavefunctions.</p>  <h3>Variational Method</h3>  <p>Uses trial wavefunctions to estimate ground state energies. Minimizes energy expectation value.</p>  <h3>Perturbation Theory</h3>  <p>Handles small deviations from solvable Hamiltonians. Calculates corrections to energies and states.</p>  </section>  <section id="numerical-solutions">  <h2>Numerical Solutions</h2>  <h3>Finite Difference Method</h3>  <p>Discretizes spatial domain. Converts differential equation to matrix eigenvalue problem. Useful for arbitrary potentials.</p>  <h3>Shooting Method</h3>  <p>Integrates differential equation from boundary. Adjusts energy guess to satisfy boundary conditions.</p>  <h3>Matrix Diagonalization</h3>  <p>Represents Ĥ in basis set. Diagonalizes matrix to find eigenvalues and eigenvectors.</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;">Numerical Method</th>   <th style="border: 1px solid #ddd; padding: 8px;">Advantages</th>   <th style="border: 1px solid #ddd; padding: 8px;">Limitations</th>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Finite Difference</td>   <td style="border: 1px solid #ddd; padding: 8px;">Simple, general, direct</td>   <td style="border: 1px solid #ddd; padding: 8px;">Computational cost grows with mesh size</td>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Shooting Method</td>   <td style="border: 1px solid #ddd; padding: 8px;">Accurate for 1D problems</td>   <td style="border: 1px solid #ddd; padding: 8px;">Sensitive to initial guess, unstable for complex potentials</td>   </tr>   <tr>   <td style="border: 1px solid #ddd; padding: 8px;">Matrix Diagonalization</td>   <td style="border: 1px solid #ddd; padding: 8px;">Scalable, handles complex potentials</td>   <td style="border: 1px solid #ddd; padding: 8px;">Requires suitable basis, large matrices</td>   </tr>  </table>  </section>  <section id="limitations">  <h2>Limitations and Extensions</h2>  <h3>Non-relativistic Approximation</h3>  <p>Valid for particles moving much slower than light. Neglects spin-orbit coupling and relativistic effects.</p>  <h3>Multi-Particle Systems</h3>  <p>Exact solutions rare for interacting particles. Requires approximation or many-body techniques.</p>  <h3>Extensions: Time Dependent and Relativistic Equations</h3>  <p>Time dependent Schrodinger equation governs dynamics. Dirac equation incorporates relativity and spin.</p>  </section>  <section id="examples">  <h2>Worked Examples</h2>  <h3>Particle in an Infinite Well</h3>  <p>Potential V=0 for 0 < x < L, infinite elsewhere. Solutions:</p>  <pre><code>ψ_n(x) = √(2/L) sin(n π x / L)E_n = (n² π² ħ²) / (2 m L²), n = 1,2,3,...</code></pre>  <h3>Quantum Harmonic Oscillator</h3>  <p>Potential V(x) = ½ m ω² x². Energy levels:</p>  <pre><code>E_n = ħ ω (n + ½), n = 0,1,2,...ψ_n(x) = N_n H_n(ξ) e^{-ξ²/2}, ξ = √(m ω / ħ) x</code></pre>  <h3>Finite Square Well Approximation</h3>  <p>Numerical or graphical solution for bound states. Energy levels depend on well depth and width.</p>  </section>  <section id="references">  <h2>References</h2>  <ul>   <li>Griffiths, D.J., Introduction to Quantum Mechanics, Pearson Prentice Hall, 2nd Ed., 2005, pp. 45-98.</li>   <li>Shankar, R., Principles of Quantum Mechanics, Springer, 2nd Ed., 1994, pp. 120-175.</li>   <li>Landau, L.D., Lifshitz, E.M., Quantum Mechanics: Non-Relativistic Theory, Pergamon Press, 3rd Ed., 1977, pp. 50-130.</li>   <li>Messiah, A., Quantum Mechanics, Dover Publications, Vol. I, 1999, pp. 200-265.</li>   <li>Cohen-Tannoudji, C., Diu, B., Laloë, F., Quantum Mechanics, Wiley-Interscience, Vol. I, 1977, pp. 150-210.</li>  </ul>  </section></main></div> !main_footer!