The infinite square well potential is a foundational model in quantum mechanics. It introduces key concepts like energy quantization, wavefunctions, and probability densities. This simple system helps us understand more complex quantum phenomena.

By confining a particle to a one-dimensional box, we see how quantization emerges naturally. The solutions reveal discrete energy levels, standing wave patterns, and the intriguing concept of zero-point energy. These ideas form the basis for understanding atomic structure and quantum confinement.

Solving the Infinite Square Well

Potential and Schrödinger Equation

• Infinite square well potential defined as V(x) = 0 for 0 < x < L, and V(x) = ∞ elsewhere (L represents well width)
• Time-independent Schrödinger equation for one-dimensional potential $-\frac{\hbar^2}{2m} \frac{d^2\psi}{dx^2} + V(x)\psi = E\psi$ (ψ denotes wavefunction, E represents energy, m signifies particle mass)
• Simplified Schrödinger equation within well (0 < x < L) $-\frac{\hbar^2}{2m} \frac{d^2\psi}{dx^2} = E\psi$
• General solution form $\psi(x) = A \sin(kx) + B \cos(kx)$ where $k = \sqrt{\frac{2mE}{\hbar}}$

Boundary Conditions and Normalization

• Boundary conditions require ψ(0) = ψ(L) = 0 leading to energy quantization and specific wavefunction forms
• Normalization condition $\int |\psi(x)|^2 dx = 1$ determines wavefunction amplitude
• Application of boundary conditions yields $\psi(x) = A \sin(kx)$ and $kL = n\pi$ where n represents positive integers
• Normalization results in amplitude A = √(2/L)

Examples and Applications

• Particle in a box model applies to electrons in conjugated molecules (polyenes)
• Quantum dots in semiconductors approximate infinite square well behavior
• OLED (Organic Light Emitting Diode) displays utilize electron confinement principles similar to infinite square well

Energy Eigenvalues and Eigenfunctions

Energy Quantization

• Energy eigenvalues given by $E_n = \frac{n^2\pi^2\hbar^2}{2mL^2}$ (n represents positive integer quantum number)
• Discrete energy levels increase quadratically with quantum number n
• Energy spacing between adjacent levels $\Delta E = E_{n+1} - E_n = \frac{(2n+1)\pi^2\hbar^2}{2mL^2}$
• Ground state energy (n=1) $E_1 = \frac{\pi^2\hbar^2}{2mL^2}$ demonstrates non-zero zero-point energy

Wavefunction Characteristics

• Normalized energy eigenfunctions (stationary states) $\psi_n(x) = \sqrt{\frac{2}{L}} \sin(\frac{n\pi x}{L})$ for n = 1, 2, 3, ...
• Eigenfunctions form complete orthonormal set satisfying $\int \psi_n^(x)\psi_m(x)dx = \delta_{nm}$ (δnm represents Kronecker delta)
• Number of nodes in wavefunction directly related to quantum number n (n-1 nodes for nth eigenfunction)
• Higher energy states correspond to higher frequency oscillations within well

Examples and Applications

• Hydrogen atom energy levels approximate infinite square well behavior (with modifications for 3D and Coulomb potential)
• Particle in a ring model (used for aromatic molecules) relates to infinite square well with periodic boundary conditions
• Quantum harmonic oscillator energy levels share similarities with infinite square well (equidistant spacing for low n)

Probability Density and Expectation Values

Probability Distribution

• Probability density for particle position $|\psi_n(x)|^2 = \frac{2}{L} \sin^2(\frac{n\pi x}{L})$
• Probability density exhibits n maxima and n-1 nodes for nth energy eigenstate
• Expectation value of position $\langle x \rangle = \int x|\psi_n(x)|^2dx = \frac{L}{2}$ (independent of energy state due to wavefunction symmetry)
• Expectation value of momentum ⟨p⟩ = 0 for all stationary states (equal likelihood of motion in either direction)

Uncertainty Principle and Measurements

• Position and momentum uncertainties calculated using $\Delta A = \sqrt{\langle A^2 \rangle - \langle A \rangle^2}$ (A represents observable of interest)
• Product ΔxΔp satisfies Heisenberg uncertainty principle
• Higher energy states generally have smaller position uncertainties and larger momentum uncertainties
• Measurement of particle position collapses wavefunction, affecting subsequent measurements

Examples and Applications

• Tunneling microscopy utilizes quantum tunneling principles related to particle confinement
• Quantum wells in semiconductor lasers exploit energy level spacing for specific wavelength emission
• Casimir effect demonstrates consequences of zero-point energy in confined spaces

Quantization of Energy in the Infinite Square Well

Implications of Energy Quantization

• Confinement of particle leads to discretization of energy levels (fundamental quantum mechanical principle)
• Energy spacing between adjacent levels increases as well width L decreases (quantum confinement in nanoscale systems)
• Non-zero ground state energy $E_1 = \frac{\pi^2\hbar^2}{2mL^2}$ demonstrates zero-point energy existence in quantum systems
• Discrete energy spectrum explains phenomena like emission and absorption spectra of atoms
• Quantized conductance in quantum point contacts relates to energy level discretization

Applications and Extensions

• Infinite square well serves as simplified model for more complex quantum systems (electrons in atoms, quantum dots)
• Finite potential wells and other bounded quantum systems build upon infinite square well concepts
• Quantum wells in semiconductor heterostructures utilize energy quantization for device engineering
• Quantum confinement effects in nanoparticles influence optical and electronic properties

Examples and Limitations

• Particle in a box with moving walls models non-adiabatic processes in quantum mechanics
• Double infinite square well system introduces concepts of tunneling and coupled quantum systems
• Limitations include neglecting particle-particle interactions and assuming infinitely high potential barriers