Brief Derivation of Schrödinger Equation: Difference between revisions

	Quantum Mechanics A
	Schrödinger Equation; The most fundamental equation of quantum mechanics; given a Hamiltonian , it describes how a state evolves in time.
	Physical Basis of Quantum Mechanics
	Basic Concepts and Theory of Motion; UV Catastrophe (Black-Body Radiation); Photoelectric Effect; Stability of Matter; Double Slit Experiment; Stern-Gerlach Experiment; The Principle of Complementarity; The Correspondence Principle; The Philosophy of Quantum Theory
	Schrödinger Equation
	Brief Derivation of Schrödinger Equation; Relation Between the Wave Function and Probability Density; Stationary States; Heisenberg Uncertainty Principle; Some Consequences of the Uncertainty Principle
	Operators, Eigenfunctions, and Symmetry
	Linear Vector Spaces and Operators; Commutation Relations and Simultaneous Eigenvalues; The Schrödinger Equation in Dirac Notation; Transformations of Operators and Symmetry; Time Evolution of Expectation Values and Ehrenfest's Theorem
	Motion in One Dimension
	One-Dimensional Bound States; Oscillation Theorem; The Dirac Delta Function Potential; Scattering States, Transmission and Reflection; Motion in a Periodic Potential; Summary of One-Dimensional Systems
	Discrete Eigenvalues and Bound States
	Harmonic Oscillator Spectrum and Eigenstates; Analytical Method for Solving the Simple Harmonic Oscillator; Coherent States; Charged Particles in an Electromagnetic Field; WKB Approximation
	Time Evolution and the Pictures of Quantum Mechanics
	The Heisenberg Picture: Equations of Motion for Operators; The Interaction Picture; The Virial Theorem
	Angular Momentum
	Commutation Relations; Angular Momentum as a Generator of Rotations in 3D; Spherical Coordinates; Eigenvalue Quantization; Orbital Angular Momentum Eigenfunctions
	Central Forces
	General Formalism; Free Particle in Spherical Coordinates; Spherical Well; Isotropic Harmonic Oscillator; Hydrogen Atom; WKB in Spherical Coordinates
	The Path Integral Formulation of Quantum Mechanics
	Feynman Path Integrals; The Free-Particle Propagator; Propagator for the Harmonic Oscillator
	Continuous Eigenvalues and Collision Theory
	Differential Cross Section and the Green's Function Formulation of Scattering; Central Potential Scattering and Phase Shifts; Coulomb Potential Scattering

Latest revision as of 16:08, 23 July 2013

Imagine a particle constrained to move along the $x$ -axis, subject to a potential energy $V(x,t)\!$ . Classically, we could model this system by writing down its Hamiltonian $H,\!$ given by

$H={\frac {p^{2}}{2m}}+V(x,t).$

We then employ Hamilton's equations of motion,

${\dot {p}}=-{\frac {\partial H}{\partial x}},\,{\dot {x}}={\frac {\partial H}{\partial p}},$

where a dot denotes a time derivative, to determine the motion of the particle. Applying these equations to the above Hamiltonian, we can recover Newton's second law,

$m{\ddot {a}}=-{\frac {\partial V}{\partial x}}=F.$

Now by applying the appropriate initial conditions for our particle, we obtain a solution for the trajectory of the particle. As we will see, the above relation is only an approximation to actual physical reality. As we attempt to describe increasingly smaller objects, we enter the quantum mechanical regime, where we can no longer neglect the particles' wave properties. Allowing $\displaystyle {p\rightarrow {\frac {\hbar }{i}}{\frac {\partial }{\partial x}}}$ and $\displaystyle {H\rightarrow i\hbar {\frac {\partial }{\partial t}}},$ we can use the Hamiltonian for a classical particle above to find an equation that describes this wave nature. We find that the wave function $\Psi (x,t)\!$ satisfies the Schrödinger equation for a scalar potential $V(x,t)\!$ in one dimension:

i\hbar {\frac {\partial }{\partial t}}\Psi (x,t)=\left[-{\frac {\hbar ^{2}}{2m}}{\frac {\partial ^{2}}{\partial x^{2}}}+V(x,t)\right]\Psi (x,t)

A similar equation may be derived in multiple dimensions:

i\hbar {\frac {\partial }{\partial t}}\Psi ({\textbf {r}},t)=\left[-{\frac {\hbar ^{2}}{2m}}\nabla ^{2}+V({\textbf {r}},t)\right]\Psi ({\textbf {r}},t)

Given a solution which satisfies the above Schrödinger equation, quantum mechanics provides a mathematical description of the laws obeyed by the probability amplitudes associated with quantum motion.

We can also generalize the Schrödinger equation to a system which contains $N\!$ particles. We assume that the wave function is $\Psi ({\textbf {r}}_{1},{\textbf {r}}_{2},\ldots ,{\textbf {r}}_{N},t)$ and that the Hamiltonian of the system can be expressed as

$H=\sum _{k=1}^{N}{\frac {{\textbf {p}}_{k}^{2}}{2m_{k}}}+V({\textbf {r}}_{1},{\textbf {r}}_{2},\ldots ,{\textbf {r}}_{N}).$

Making a similar replacement as before, we may obtain the Schrödinger equation for a many-particle system:

i\hbar {\frac {\partial }{\partial t}}\Psi ({\textbf {r}}_{1},{\textbf {r}}_{2},\ldots ,{\textbf {r}}_{N},t)=\left[\sum _{k=1}^{N}{\frac {\hbar ^{2}}{2m_{k}}}\nabla _{k}^{2}+V({\textbf {r}}_{1},{\textbf {r}}_{2},\ldots ,{\textbf {r}}_{N})\right]\Psi ({\textbf {r}}_{1},{\textbf {r}}_{2},\ldots ,{\textbf {r}}_{N},t)

Here, $\nabla _{k}^{2}$ is the Lapalacian operator that acts on the coordinates of particle $k.\!$

@@ Line 1: / Line 1: @@
 {{Quantum Mechanics A}}
-Imagine a particle constrained to move along the x-axis, subject to some force <math>F(x,t)\!</math>.  Classically, we would investigate this system by applying Newton's second law, <math>F = ma\!</math>.  Assuming the force is conservative, it could also be expressed as the partial derivative with respect to <math>x\!</math>, and Newton's second law then reads:
+Imagine a particle constrained to move along the <math>x</math>-axis, subject to a potential energy <math>V(x,t)\!</math>.  Classically, we could model this system by writing down its Hamiltonian <math>H,\!</math> given by
-:<math>m\frac{d^2x}{dt^2}=-\frac{\partial V}{\partial x}</math>
+<math>H = \frac{p^2}{2m} + V(x,t).</math>
-The energy for the particle in this regime is given by the addition of its kinetic and potential energies:
+We then employ Hamilton's equations of motion,
-:<math>E = T + V = \frac{p^2}{2m} + V</math>
+<math>\dot{p}=-\frac{\partial H}{\partial x},\,\dot{x}=\frac{\partial H}{\partial p},</math>
-Now by applying the appropriate initial conditions for our particle, we then have a solution for the trajectory of the particle.  As we will see, the above relation is only an approximation to actual physical reality. As we attempt to describe increasingly smaller objects we enter the quantum mechanical regime, where we cannot neglect the particles' wave properties. Allowing <math>\displaystyle{p \rightarrow \frac{\hbar}{i}\frac{d}{dx}}</math> and <math>\displaystyle{E \rightarrow i\hbar \frac{d}{dt}}</math>, we can use the energy equation for a classical particle above to find an equation that describes this wave nature. Thus, we find that the complex amplitude satisfies the [[Schrödinger equation]] for a scalar potential <math>V(x,t)\!</math> in one dimension:
+where a dot denotes a time derivative, to determine the motion of the particle.  Applying these equations to the above Hamiltonian, we can recover Newton's second law,
-:<math> i\hbar\frac{\partial}{\partial t}\psi(x,t)=\left[-\frac{\hbar^2}{2m}\frac{\partial^2}{\partial x^2}+V(x,t)\right]\psi(x,t) </math>
+<math>m\ddot{a}=-\frac{\partial V}{\partial x}=F.</math>
+Now by applying the appropriate initial conditions for our particle, we obtain a solution for the trajectory of the particle.  As we will see, the above relation is only an approximation to actual physical reality.  As we attempt to describe increasingly smaller objects, we enter the quantum mechanical regime, where we can no longer neglect the particles' wave properties. Allowing <math>\displaystyle{p \rightarrow \frac{\hbar}{i}\frac{\partial}{\partial x}}</math> and <math>\displaystyle{H \rightarrow i\hbar \frac{\partial}{\partial t}},</math> we can use the Hamiltonian for a classical particle above to find an equation that describes this wave nature.  We find that the wave function <math>\Psi(x,t)\!</math> satisfies the [[Schrödinger equation]] for a scalar potential <math>V(x,t)\!</math> in one dimension:
+:<math> i\hbar\frac{\partial}{\partial t}\Psi(x,t)=\left[-\frac{\hbar^2}{2m}\frac{\partial^2}{\partial x^2}+V(x,t)\right]\Psi(x,t) </math>
-While in 3D:
+A similar equation may be derived in multiple dimensions:
-:<math> i\hbar\frac{\partial}{\partial t}\psi(\textbf{r},t)=\left[-\frac{\hbar^2}{2m}\nabla^2+V(\textbf{r},t)\right]\psi(\textbf{r},t)</math>
+:<math> i\hbar\frac{\partial}{\partial t}\Psi(\textbf{r},t)=\left[-\frac{\hbar^2}{2m}\nabla^2+V(\textbf{r},t)\right]\Psi(\textbf{r},t)</math>
-Given a solution which satisfies the above Schrödinger equation, Quantum Mechanics provides a mathematical description of the laws obeyed by the probability amplitudes associated with quantum motion.
+Given a solution which satisfies the above Schrödinger equation, quantum mechanics provides a mathematical description of the laws obeyed by the probability amplitudes associated with quantum motion.
+We can also generalize the Schrödinger equation to a system which contains <math> N \!</math> particles. We assume that the wave function is <math> \Psi(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N, t) </math> and that the Hamiltonian of the system can be expressed as
-We can also generalize the Schrödinger equation to a system which contains <math> N \!</math> particles. We assume that the wave function is <math> \psi(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N, t) </math> and the [[Commutation relations and simultaneous eigenvalues#Hamiltonian|Hamiltonian operator]] of the system can be expressed as:
+<math>  H= \sum_{k=1}^N \frac{\textbf{p}^2_k}{2m_k}+V(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N). </math>
-:<math>  H= \sum_{k=1}^N \frac{\textbf{p}^2_k}{2m_k}+V(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N) </math>
+Making a similar replacement as before, we may obtain the Schrödinger equation for a many-particle system:
-So the Schrödinger equation for a many-particle system is:
+:<math>  i\hbar\frac{\partial}{\partial t}\Psi(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N, t)=\left[\sum_{k=1}^N \frac{\hbar^2}{2m_k}\nabla_{k}^2+V(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N)\right]\Psi(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N, t) </math>
-:<math>  i\hbar\frac{\partial}{\partial t}\psi(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N, t)=\left[\sum_{k=1}^N \frac{\textbf{p}^2_k}{2m_k}+V(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N)\right]\psi(\textbf{r}_1,\textbf{r}_2, \ldots, \textbf{r}_N, t) </math>
+Here, <math>\nabla_{k}^2</math> is the Lapalacian operator that acts on the coordinates of particle <math>k.\!</math>

Brief Derivation of Schrödinger Equation: Difference between revisions

Latest revision as of 16:08, 23 July 2013

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