of the
Hydrogen atom One of the earliest steps towards
atomic physics was the recognition that matter was composed of
atoms, in modern terms the basic unit of a
chemical element. This theory was developed by
John Dalton in the 18th century. At this stage, it wasn't clear what atoms were - although they could be described and classified by their observable properties in bulk; summarized by the developing
periodic table, by
John Newlands and
Dmitri Mendeleyev around the mid to late 19th century. Later, the connection between atomic physics
and optical physics became apparent, by the discovery of
spectral lines and attempts to describe the phenomenon - notably by
Joseph von Fraunhofer,
Fresnel, and others in the 19th century. From that time to the 1920s, physicists were seeking to explain
atomic spectra and
blackbody radiation. One attempt to explain hydrogen spectral lines was the
Bohr atom model.
Classical oscillator model of matter Early models to explain the origin of the
index of refraction treated an
electron in an atomic system classically according to the model of
Paul Drude and
Hendrik Lorentz. The theory was developed to attempt to provide an origin for the wavelength-dependent refractive index
n of a material. In this model, incident
electromagnetic waves forced an electron bound to an atom to
oscillate. The
amplitude of the oscillation would then have a relationship to the
frequency of the incident electromagnetic wave and the
resonant frequencies of the oscillator. The
superposition of these emitted waves from many oscillators would then lead to a wave which moved more slowly.
Early quantum model of matter and light Max Planck derived a formula to describe the
electromagnetic field inside a box when in
thermal equilibrium in 1900. His model consisted of a superposition of
standing waves. In one dimension, the box has length
L, and only sinusoidal waves of
wavenumber : k = \frac{n\pi}{L} can occur in the box, where
n is a positive
integer (mathematically denoted by \scriptstyle n \in \mathbb{N}_1). The equation describing these standing waves is given by: :E=E_0 \sin\left(\frac{n\pi}{L}x\right)\,\!. where
E0 is the magnitude of the
electric field amplitude, and
E is the magnitude of the electric field at position
x. From this basic,
Planck's law was derived. In 1911,
Ernest Rutherford concluded, based on
alpha particle scattering, that an atom has a central pointlike proton. He also thought that an electron would be still attracted to the proton by Coulomb's law, which he had verified still held at small scales. As a result, he believed that electrons revolved around the proton.
Niels Bohr, in 1913, combined the
Rutherford model of the atom with the quantisation ideas of Planck. Only specific and well-defined orbits of the electron could exist, which also do not radiate light. In jumping orbit the electron would emit or absorb light corresponding to the difference in energy of the orbits. His prediction of the energy levels was then consistent with observation. These results, based on a
discrete set of specific standing waves, were inconsistent with the
continuous classical oscillator model. Work by
Albert Einstein in 1905 on the
photoelectric effect led to the association of a light wave of frequency \nu with a photon of energy h\nu. In 1917 Einstein created an extension to Bohrs model by the introduction of the three processes of
stimulated emission,
spontaneous emission and
absorption (electromagnetic radiation). ==Modern treatments==