This is the Schrodinger equation from 1925-1926.
Schrodinger wave equation
The electron itself isn't a wave, it's the probability of finding it in a certain spot that's governed by a wave equation.
The probability distribution for an electron orbital.
No -- an electron is a point particle with mass, charge, and spin. The probability that you will find an electron at a specific point can, however, often be calculated by wave functions. Any moving mass can be considered either a particle or a wave. Its properties can be defined via the deBorlie wave equation.
The wave function of a single electron in the universe describes the probability distribution of finding the electron at a given position and time. It is a mathematical function that contains all the information about the electron's quantum state. The wave function evolves over time according to the Schrödinger equation.
The probability of finding electrons in an atom is determined by the Schrödinger equation, a fundamental equation of quantum mechanics. This equation describes the wave function of the electron, from which the probability density of finding the electron in a particular region of space can be calculated.
Alfred W. Andrews has written: 'A study of the wave equation for the dipole' -- subject(s): Wave mechanics
The mathematical expression that describes the spatial distribution of an electron in a hydrogen atom is known as the hydrogen wave function, represented by the equation (r, , ).
The standing wave equation describes a wave that appears to be stationary, with points of no motion called nodes. The traveling wave equation describes a wave that moves through a medium, transferring energy from one point to another.
Erwin Schrodinger
The equation for the velocity of a transverse wave is v f , where v is the velocity of the wave, f is the frequency of the wave, and is the wavelength of the wave.
Tosiya Taniuti has written: 'Nonlinear waves' -- subject- s -: Nonlinear waves, Wave equation