Probability amplitudes, de Broglie and Schrödinger

In summary, the "matter waves" described by de Broglie, the probability amplitude function, and Schrödinger's wave equation are all related concepts. De Broglie's idea of matter waves is actually describing the probability amplitudes or wave functions of particles. The wave function is a solution to Schrödinger's equation and is considered a "wave" because it is similar to the Wave Equation. The probability amplitude is the square of the wave function, and can be thought of as analogous to the electric field in intensity.
  • #1
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What is the relationship between the "matter waves" described by de Broglie, the probability amplitude function and Schrödinger's wave equation?

I've read the following:

"The wavelengths postulated by de Broglie to be associated with the motions of particles are in reality the wavelengths of the probability amplitudes or wave functions."

I've also read:

"What is a wave function? The short answer is that it is a probability amplitude, that also happens to solve Schrodinger’s equation."

Are they all versions of the same thing?
 
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  • #2
The wavefunction in one dimension is simply some function f(x) that solves Schroedinger's equation. It is called a "wave" function because the Schroedinger equation is mathematically similar to the so-called Wave Equation (Wikipedia explains).

The probability amplitude is the square of the wavefunction. This is a postulate, so you'll have to remember it, or remember an analogy.

In fact, it is analogous to the electric field (wave) E(x), since we think about [tex]|E(x)|^2[/tex] as the intensity of the wave.
 

1. What are probability amplitudes and how are they related to quantum mechanics?

Probability amplitudes are complex numbers that represent the likelihood of a quantum system being in a certain state. They are related to quantum mechanics through the principles of superposition and measurement, where the square of the amplitude gives the probability of finding the system in a particular state upon measurement.

2. Who was Louis de Broglie and what was his contribution to quantum theory?

Louis de Broglie was a French physicist who proposed the idea of wave-particle duality in quantum mechanics. He suggested that particles, such as electrons, have both wave-like and particle-like properties, and that their wavelength is inversely proportional to their momentum. This concept was later confirmed by experiments and became an integral part of quantum theory.

3. How does the Schrödinger equation describe quantum systems?

The Schrödinger equation is a mathematical equation that describes the evolution of a quantum system over time. It takes into account the wave-like nature of particles and their probability amplitudes, allowing us to calculate the probability of finding the system in a particular state at a given time. It is a fundamental equation in quantum mechanics and has been instrumental in understanding and predicting the behavior of particles at the microscopic level.

4. What is the significance of the de Broglie wavelength?

The de Broglie wavelength is a concept that relates the momentum of a particle to its wavelength. It is significant because it shows that all particles, not just waves, have a wave-like nature. This led to the development of wave mechanics and the idea of probability amplitudes, which have greatly advanced our understanding of quantum systems.

5. How do probability amplitudes and the uncertainty principle relate to each other?

The uncertainty principle states that it is impossible to know both the position and momentum of a particle with absolute certainty. This is due to the probabilistic nature of quantum mechanics and the fact that the act of measuring a particle's position or momentum can affect its state. Probability amplitudes play a crucial role in the uncertainty principle, as they represent the uncertainty in a particle's position and momentum and determine the range of values that can be measured with a certain probability.

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