What is the Derivation of the Schrodinger Equation for Matter?

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SUMMARY

The derivation of the Schrödinger equation for matter relies on the relationship between energy and frequency, expressed as E = hf. However, confusion arises when applying this to matter, leading to the incorrect conclusion that E = hf/2 through algebraic manipulation. Key principles of quantum mechanics (QM) include the description of states in Hilbert space, observables as hermitian operators, and the evolution of systems governed by the Schrödinger equation. The discussion emphasizes the distinction between phase velocity and group velocity, clarifying that a wave packet, which localizes a particle, behaves differently than a single frequency wave.

PREREQUISITES
  • Understanding of quantum mechanics principles, particularly Hilbert space and hermitian operators.
  • Familiarity with wave-particle duality and the concept of wave functions.
  • Basic knowledge of algebraic manipulation in physics equations.
  • Awareness of phase velocity versus group velocity in wave mechanics.
NEXT STEPS
  • Study Griffiths' textbook on quantum mechanics for a comprehensive understanding of wave functions and state vectors.
  • Learn about the Hamiltonian function and its role in quantum mechanics.
  • Research the differences between phase velocity and group velocity in wave mechanics.
  • Explore Herbert S. Green's "Matrix Mechanics" for insights into the relationship between matrices and wave functions.
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Students and enthusiasts of quantum mechanics, physicists exploring wave-particle duality, and anyone seeking to deepen their understanding of the Schrödinger equation and its implications for matter.

snoopies622
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Wikipedia's derivation of the Schrödinger equation apparently includes the premise that the energy of a particle is the product of Planck's constant and the particle's frequency.

E = hf

I have seen this equation before for photons but when applied to matter, I'm confused. If we assume the following

E = \frac {p^2}{2m}

\lambda = \frac {h}{p}

p = mv

\lambda f = v

where

E = energy
p = momentum
m = mass
λ = wavelength
f = frequency
v = velocity

simple algebraic manipulation yields E = hf/2 , not hf. The only relationship not mentioned in the derivation is the λf = v, but how could that not be true for a wave of any kind?
 
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One commonly accepted set of postulates for QM is:
1. The state of a system is described by a vector belonging to a Hilbert space possessing an inner product.

2. Observables are represented by hermitian operators (dynamical variables in classical mechanics) belonging to the same Hilbert space.
The observed quantities are given by eingenvalues of this operator.
Observation causes the system to assume the associated eingenvector (collapse).

3. The evolution of the system is governed by the Schrödinger equation, derived from a Hamiltonian function which represents the distribution of the energy in the system.

4. The probability amplitude of finding the particle in a given state is given by the inner product between this state and the original one (the probability is the square of the product's modulus).

5. Two states can be represented by one state as their tensorial product.
Treating the Schrödinger equation as the starting point is found for example in Griffiths' textbook.

The kinetic energy appears when constructing the Hamiltonian function.
 
The p=mv equation should not be used. The v in your mv is not simply related to the v which is the velocity of the wave in f lambda=v. The wave function is
exp[p.x-(p^2/2m)t/hbar]. You can find the wave and group velocity from that.
 
This is a very good question which deserves a clear answer. Snoopies has done his calculations correctly and he is right to be confused. You get the wrong velocity for the particle if you take the formulas at face value.

The phase velocity which Clem alludes to in post #3 is the apparent velocity of a single frequency. But for a pure frequency the particle is everywhere at once. To localize the particle, you need to take a mixture of frequencies spread closely around an average. This gives you a wave packet...and the velocity of the wave packet is altogether different from the phase velocity of the pure wave. The phase velocity is w/k, as expected. The group velocity turns out to be dw/dk.
 
Phase velocity versus group velocity -- of course! Thanks conway, you have completely clarified this issue for me.

Incidentally intervoxel, I just took out of copy of Herbert S. Green's Matrix Mechanics (1965) and it looks like a good introduction to what you were talking about, although for the moment I don't have a clear idea of how vectors and matrices are isomorphic to waves and functions of waves. But I am just beginning to study all this.
 
It's no substitute for reading the book, but here's the gist: a function (which describes a wave - like the sine function, for example) is basically just a list of values, indexed by some number. f(0) = 0, f(1) = 2, f(2) = 5, f(3) = 1, etc. You can take those values and put them into a vector, [0 2 5 1 ...]. Linear operations on the function are equivalent to multiplying the corresponding vector by a matrix. And it turns out that even if your function is defined at all points on the real line, you can still treat its values as a vector, even though you can't list them out individually.
 
Diazona has indeed given the gist of it; I'd like to expand on his explanation by giving a specific example of the matrix which corresponds to the differentiation operator. Take a matrix with all zeros except for +1 in the superdiagonal row and -1 in the subdiagonal row. Operating with this on a target vector gives a new vector which is the difference of (nearly) adjacent elements.

This corresponds exactly to how you execute ordinary differentiation as a convolution integral with the derivative of a delta function.
 
snoopies622 said:
Incidentally intervoxel, I just took out of copy of Herbert S. Green's Matrix Mechanics (1965) and it looks like a good introduction to what you were talking about, although for the moment I don't have a clear idea of how vectors and matrices are isomorphic to waves and functions of waves. But I am just beginning to study all this.

QM isn't trivial stuff anyway, but the journey is worthwhile (I'm a beginner too).

Interestingly, while Griffiths goes from wave functions to vectors, Sakurai starts with vectors and eventually defines wavefunctions as projections of the state vectors on a suitable basis.

Good luck, snoopies622.
 
I have found that chapter XII in Schiff "Quantum Mechanics" on the relativistic wave equation is very good.
For relativistic particles, including photons,
E2 = (m0c2)2 + (pc)2
where E is total energy, m0c2 is rest mass, and pc is momentum in energy units.
 

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