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The Quantum-Mechanical Model of an Atom02:45

The Quantum-Mechanical Model of an Atom

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Shortly after de Broglie published his ideas that the electron in a hydrogen atom could be better thought of as being a circular standing wave instead of a particle moving in quantized circular orbits, Erwin Schrödinger extended de Broglie’s work by deriving what is now known as the Schrödinger equation. When Schrödinger applied his equation to hydrogen-like atoms, he was able to reproduce Bohr’s expression for the energy and, thus, the Rydberg formula governing hydrogen spectra.
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The de Broglie Wavelength02:32

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In the macroscopic world, objects that are large enough to be seen by the naked eye follow the rules of classical physics. A billiard ball moving on a table will behave like a particle; it will continue traveling in a straight line unless it collides with another ball, or it is acted on by some other force, such as friction. The ball has a well-defined position and velocity or well-defined momentum, p = mv, which is defined by mass m and velocity v at any given moment. This is the typical...
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The Bohr Model02:18

The Bohr Model

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Following the work of Ernest Rutherford and his colleagues in the early twentieth century, the picture of atoms consisting of tiny dense nuclei surrounded by lighter and even tinier electrons continually moving about the nucleus was well established. This picture was called the planetary model since it pictured the atom as a miniature “solar system” with the electrons orbiting the nucleus like planets orbiting the sun. The simplest atom is hydrogen, consisting of a single proton as...
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Equilibrium Conditions for a Particle01:23

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When an object is in equilibrium, it is either at rest or moving with a constant velocity. There are two types of equilibrium: static and dynamic. Static equilibrium occurs when an object is at rest, while dynamic equilibrium occurs when an object is moving with a constant velocity. In both cases, there must be a balance of forces acting on the object.
To understand the concept of equilibrium, let us first consider the forces acting on an object. When different forces act on an object, they can...
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The Pauli Exclusion Principle03:06

The Pauli Exclusion Principle

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The arrangement of electrons in the orbitals of an atom is called its electron configuration. We describe an electron configuration with a symbol that contains three pieces of information:
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Entropy Change in Reversible Processes01:10

Entropy Change in Reversible Processes

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In the Carnot engine, which achieves the maximum efficiency between two reservoirs of fixed temperatures, the total change in entropy is zero. The observation can be generalized by considering any reversible cyclic process consisting of many Carnot cycles. Thus, it can be stated that the total entropy change of any ideal reversible cycle is zero.
The statement can be further generalized to prove that entropy is a state function. Take a cyclic process between any two points on a p-V diagram.
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Related Experiment Video

Updated: Jul 23, 2025

Gradient Echo Quantum Memory in Warm Atomic Vapor
10:00

Gradient Echo Quantum Memory in Warm Atomic Vapor

Published on: November 11, 2013

12.9K

Quantum evolution represented by Brownian motion.

Jiushu Shao1

  • 1College of Chemistry and Center for Advanced Quantum Studies, Beijing Normal University, Beijing 100875, China.

The Journal of Chemical Physics
|July 13, 2023
PubMed
Summary
This summary is machine-generated.

We introduce a new stochastic Schrödinger equation that simplifies quantum mechanics calculations. This novel approach allows for easier derivation of quantum propagators for systems like the harmonic oscillator.

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Area of Science:

  • Quantum Mechanics
  • Stochastic Processes
  • Theoretical Physics

Background:

  • The standard Schrödinger equation presents computational challenges for complex quantum systems.
  • Understanding quantum evolution operators and propagators is crucial for theoretical and applied physics.

Purpose of the Study:

  • To propose a novel stochastic Schrödinger equation (SSE) that simplifies quantum mechanical calculations.
  • To demonstrate the utility of the SSE in deriving exact quantum propagators.

Main Methods:

  • Coupling momentum to white Gaussian noise to reformulate the Schrödinger equation.
  • Factorizing the quantum evolution operator into momentum and potential contributions.
  • Calculating the exact quantum propagator as an expectation of the stochastic propagator.

Main Results:

  • The kinetic energy term simplifies to a linear momentum term in the stochastic representation.
  • The quantum evolution operator is factorized, simplifying calculations.
  • The SSE was successfully applied to derive quantum propagators for linear potential and harmonic oscillator systems.

Conclusions:

  • The proposed stochastic Schrödinger equation offers a feasible and simplified method for deriving quantum propagators.
  • This new representation opens avenues for developing novel semiclassical and other approximations in quantum mechanics.