In physics, scattering is a wide range of physical processes where moving particles or radiation of some form, such as light or sound, are forced to deviate from a straight trajectory by localized non-uniformities (including particles and radiation) in the medium through which they pass. In conventional use, this also includes deviation of reflected radiation from the angle predicted by the law of reflection. Reflections of radiation that undergo scattering are often called diffuse reflections and unscattered reflections are called specular (mirror-like) reflections. Originally, the term was confined to light scattering, going back at least as far as Isaac Newton in the 17th century.^[1] As more "ray"-like phenomena were discovered, the concept of scattering was extended, so that William Herschel could refer to the scattering of heat rays in 1800.^[2] John Tyndall later noted the connection between light scattering and acoustic scattering in the 19th century.^[3] Near the end of the 19th century, the scattering of cathode rays and X-rays was observed and discussed, and with the discovery of subatomic particles and the development of quantum theory, the meaning of the term became broader as it was recognized that the same mathematical frameworks used in light scattering could be applied to many other phenomena.^[4][5][6]

Scattering can refer to the consequences of particle-particle collisions between molecules, atoms, electrons, photons and other particles. Examples include cosmic ray scattering in the Earth's upper atmosphere, particle collisions inside particle accelerators, electron scattering by gas atoms in fluorescent lamps, and neutron scattering inside nuclear reactors.^[7]

The types of non-uniformities which can cause scattering, sometimes known as scatterers or scattering centers, are too numerous to list, but a small sample includes particles, bubbles, droplets, density fluctuations in fluids, crystallites in polycrystalline solids, defects in monocrystalline solids, surface roughness, cells in organisms, and textile fibers in clothing. The effects of such features on the path of almost any type of propagating wave or moving particle can be described in the framework of scattering theory.

Scattering is quantified using many different concepts, including scattering cross section (σ), attenuation coefficients, the bidirectional scattering distribution function (BSDF), S-matrices, and mean free path.

In classical physics, scattering is often described in terms of trajectories and collisions. Light scattering by small particles leads to phenomena such as Rayleigh scattering, which explains why the sky appears blue. In the classical picture, scattering may arise when waves or particles encounter irregularities in a material, such as density changes in a fluid, defects in a crystal, or roughness on a surface.

In quantum mechanics, scattering is described using wavefunctions and probability amplitudes. Instead of definite trajectories, particles are represented by waves that interact with a potential. The outcome of a scattering process is characterized by quantities such as the cross section and the scattering amplitude. In particle physics, the quantum interaction and scattering of fundamental particles is described by the S-Matrix, introduced and developed by John Archibald Wheeler and Werner Heisenberg.^[8]

Scattering may also be classified as elastic or inelastic. In elastic scattering, the internal states of the scattering particles do not change, and they emerge unchanged from the interaction. In inelastic scattering, by contrast, internal energy changes occur, which may excite atoms, ionize them, or even lead to the annihilation of some particles and the creation of entirely new ones. A well-known example in particle physics is deep inelastic scattering, which has been crucial in probing the internal structure of hadrons.

When radiation is only scattered by one localized scattering center, this is called single scattering. It is more common that scattering centers are grouped together; in such cases, radiation may scatter many times, in what is known as multiple scattering.^[9]

The main difference between the effects of single and multiple scattering is that single scattering can usually be treated as a random phenomenon, whereas multiple scattering, somewhat counterintuitively, can often be modeled as a more deterministic process because the combined results of a large number of scattering events tend to average out. Multiple scattering can thus often be modeled well with diffusion theory.^[10]

Because the location of a single scattering center is not usually well known relative to the path of the radiation, the outcome often appears random to an observer. This type of scattering is exemplified by an electron being fired at an atomic nucleus: the exact position of the atom relative to the electron path is unknown, so the exact trajectory after the collision cannot be predicted. Single scattering is therefore often described by probability distributions.

With multiple scattering, the randomness of individual interactions tends to be averaged out by a large number of events, so that the final path of the radiation appears to be a more deterministic distribution of intensity. A familiar example is a light beam passing through thick fog. Multiple scattering is highly analogous to diffusion, and the terms multiple scattering and diffusion are interchangeable in many contexts. Optical elements designed to produce multiple scattering are therefore known as diffusers.^[11]

Not all single scattering is random, however. A well-controlled laser beam can be positioned to scatter from a microscopic particle with a nearly deterministic outcome. Similarly, multiple scattering can sometimes have random outcomes, especially for coherent radiation. The random fluctuations in the multiply scattered intensity of coherent radiation are called speckles. Coherent backscattering, an enhancement of backscattering that occurs when coherent radiation is multiply scattered by a random medium, is usually attributed to weak localization.

Scattering theory is a framework for studying and understanding the scattering of waves and elementary particles. More precisely, it concerns how solutions of partial differential equations, propagating freely in the distant past, come together and interact with one another or with a boundary or potential, and then propagate away again into the distant future.

Wave scattering corresponds to the interaction of a wave with some material object, for instance sunlight scattered by raindrops to form a rainbow. Scattering also includes the interaction of billiard balls on a table, the Rutherford scattering of alpha particles by atomic nuclei, the Bragg scattering of electrons and X-rays by a cluster of atoms, and the inelastic scattering of a fission fragment as it traverses a thin foil.

The direct scattering problem is the problem of determining the distribution of scattered radiation or particle flux from the characteristics of the scatterer. The inverse scattering problem is the problem of determining the characteristics of an object, such as its shape or internal constitution, from measurement data of radiation or particles scattered from it.

In regular quantum mechanics, the relevant equation is the Schrödinger equation, although equivalent formulations such as the Lippmann-Schwinger equation and the Faddeev equationss are also used. The solutions of interest describe the long-term motion of free atoms, molecules, photons, electrons, and protons that come together from large distances, interact, and then move apart again. These solutions reveal the directions in which the products are most likely to travel, how quickly they move, and the probabilities of reactions, creations, and decays. Two predominant techniques for finding solutions to scattering problems are partial wave analysis and the Born approximation.

Key concepts include:

• The scattering matrix (S-matrix), which relates incoming and outgoing states.
• The differential cross section, describing the angular distribution of scattered particles.
• The phase shift, which encodes how the wave is altered by the interaction.
• The inverse scattering problem, in which properties of a system are inferred from scattering data.
• The mean free path and attenuation coefficients, which quantify how scattering reduces an unscattered beam.

When the target is a set of many scattering centers whose relative positions vary unpredictably, it is useful to describe the decrease of an unscattered beam by an attenuation equation. In the simplest case, if particles are removed from the unscattered beam at a rate proportional to the incident intensity ${\displaystyle I}$, then

$${\displaystyle \frac{dI}{dx}=-QI}$$

where Q is an interaction coefficient and x is the distance traveled in the target.

This has solutions of the form

$${\displaystyle I=I_o{e}^{-Q\mathrm{\Delta }x}=I_o{e}^{-\frac{\mathrm{\Delta }x}{\lambda }}=I_o{e}^{-\sigma (\eta \mathrm{\Delta }x)}=I_o{e}^{-\frac{\rho \mathrm{\Delta }x}{\tau }}}$$

where I_o is the initial flux, λ is the interaction mean free path, σ is the cross section, η is the number of targets per unit volume, ρ is the target mass density, and τ is the density mean free path. These quantities provide different but related ways of measuring attenuation in scattering systems.

Electromagnetic waves are among the most familiar forms of radiation that undergo scattering.^[12] Scattering of light and radio waves is particularly important in optics and radar. Major forms of elastic light scattering are Rayleigh scattering and Mie scattering, while inelastic scattering includes Brillouin scattering, Raman scattering, inelastic X-ray scattering, and Compton scattering.

Light scattering is one of the two major physical processes that contribute to the visible appearance of most objects, the other being absorption. Surfaces described as white owe their appearance to multiple scattering of light by internal or surface inhomogeneities in the object, for example by microscopic crystals in stone or by the fibers in paper. More generally, the gloss or sheen of a surface is determined by scattering: highly scattering surfaces tend to appear dull or matte, while the absence of surface scattering leads to a glossy appearance.

Spectral absorption determines much of the color of objects, but scattering often modifies or even creates color. The blue color of the sky is a classic result of Rayleigh scattering, in which shorter wavelengths are scattered more strongly than longer ones. Light scattering can also be responsible for the appearance of the human blue iris and the structural colors of certain bird feathers. For larger particles, the appropriate description shifts from Rayleigh scattering to Mie scattering, and for particles much larger than the wavelength of light, the laws of geometric optics often become sufficient.

Scattering and scattering theory are significant in many areas of physics and engineering. Important examples include radar sensing, medical ultrasound, semiconductor wafer inspection, polymerization process monitoring, acoustic tiling, free-space communications, and computer-generated imagery.^[13]

Particle-particle scattering theory is especially important in particle physics, atomic, molecular, and optical physics, nuclear physics, and astrophysics. Experimental scattering techniques such as electron scattering and neutron scattering are essential tools for probing the microscopic structure of matter. In condensed matter and materials science, scattering methods are used to study defects, transport, and collective behavior. In atmospheric physics and optics, scattering determines visibility, color, radiative transfer, and the propagation of light through clouds, fog, and aerosols.

1. Foundations (14) Back to index

1. Physics:Quantum basics

2. Physics:Quantum photoelectric effect

3. Physics:Quantum black-body radiation

4. Physics:Quantum Planck constant

5. Physics:Quantum Postulates

6. Physics:Quantum Hilbert space

7. Physics:Quantum Observables and operators

8. Physics:Quantum mechanics

9. Physics:Quantum mechanics measurements

10. Physics:Quantum state

11. Physics:Quantum system

12. Physics:Quantum superposition

13. Physics:Quantum probability

14. Physics:Quantum Mathematical Foundations of Quantum Theory

2. Conceptual and interpretations (14) Back to index

15. Physics:Quantum Interpretations of quantum mechanics

16. Physics:Quantum Wave–particle duality

17. Physics:Quantum Complementarity principle

18. Physics:Quantum Uncertainty principle

19. Physics:Quantum Measurement problem

20. Physics:Quantum Bell's theorem

21. Physics:Quantum Hidden variable theory

22. Physics:Quantum nonlocality

23. Physics:Quantum contextuality

24. Physics:Quantum Darwinism

25. Physics:Quantum A Spooky Action at a Distance

26. Physics:Quantum A Walk Through the Universe

27. Physics:Quantum The Secret of Cohesion and How Waves Hold Matter Together

28. Physics:Quantum measurement problem

3. Mathematical structure and systems (15) Back to index

29. Physics:Quantum Density matrix

30. Physics:Quantum Exactly solvable quantum systems

31. Physics:Quantum many-body problem

32. Physics:Quantum Formulas Collection

33. Physics:Quantum A Matter Of Size

34. Physics:Quantum Symmetry in quantum mechanics

35. Physics:Quantum Noether theorem

36. Physics:Quantum Angular momentum operator

37. Physics:Quantum Runge–Lenz vector

38. Physics:Quantum Approximation Methods

39. Physics:Quantum Matter Elements and Particles

40. Physics:Quantum Dirac equation

41. Physics:Quantum Klein–Gordon equation

42. Physics:Quantum pendulum

43. Physics:Quantum configuration space

4. Atomic and spectroscopy (14) Back to index

44. Physics:Quantum Atomic structure and spectroscopy

45. Physics:Quantum Hydrogen atom

46. Physics:Quantum number

47. Physics:Quantum Multi-electron atoms

48. Physics:Quantum Fine structure

49. Physics:Quantum Hyperfine structure

50. Physics:Quantum Isotopic shift

51. Physics:Quantum defect

52. Physics:Quantum Zeeman effect

53. Physics:Quantum Stark effect

54. Physics:Quantum Spectral lines and series

55. Physics:Quantum Selection rules

56. Physics:Quantum Fermi's golden rule

57. Physics:Quantum beats

5. Wavefunctions and modes (9) Back to index

58. Physics:Quantum Wavefunction

59. Physics:Quantum Superposition principle

60. Physics:Quantum Eigenstates and eigenvalues

61. Physics:Quantum Boundary conditions and quantization

62. Physics:Quantum Standing waves and modes

63. Physics:Quantum Normal modes and field quantization

64. Physics:Number of independent spatial modes in a spherical volume

65. Physics:Quantum Density of states

66. Physics:Quantum carpet

6. Quantum dynamics and evolution (20) Back to index

67. Physics:Quantum Time evolution

68. Physics:Quantum Schrödinger equation

69. Physics:Quantum Time-dependent Schrödinger equation

70. Physics:Quantum Stationary states

71. Physics:Quantum Perturbation theory

72. Physics:Quantum Time-dependent perturbation theory

73. Physics:Quantum Adiabatic theorem

74. Physics:Quantum Berry phase

75. Physics:Quantum Aharonov-Bohm effect

76. Physics:Quantum Scattering theory

77. Physics:Quantum Scattering matrix

78. Physics:Quantum S-matrix

79. Physics:Quantum tunnelling

80. Physics:Quantum speed limit

81. Physics:Quantum revival

82. Physics:Quantum reflection

83. Physics:Quantum oscillations

84. Physics:Quantum jump

85. Physics:Quantum boomerang effect

86. Physics:Quantum chaos

7. Measurement and information (9) Back to index

87. Physics:Quantum Measurement theory

88. Physics:Quantum Measurement operators

89. Physics:Quantum Projective measurement

90. Physics:Quantum POVM

91. Physics:Quantum Weak measurement

92. Physics:Quantum Measurement collapse

93. Physics:Quantum entanglement

94. Physics:Quantum Zeno effect

95. Physics:Quantum limit

8. Quantum information and computing (10) Back to index

96. Physics:Quantum information theory

97. Physics:Quantum Qubit

98. Physics:Quantum Entanglement

99. Physics:Quantum Gates and circuits

100. Physics:Quantum Computing Algorithms in the NISQ Era

101. Physics:Quantum Noisy Qubits

102. Physics:Quantum random access code

103. Physics:Quantum pseudo-telepathy

104. Physics:Quantum network

105. Physics:Quantum money

9. Quantum optics and experiments (5) Back to index

106. Physics:Quantum Nonlinear King plot anomaly in calcium isotope spectroscopy

107. Physics:Quantum optics beam splitter experiments

108. Physics:Quantum Ultra fast lasers

109. Physics:Quantum Experimental quantum physics

110. Physics:Quantum optics

111. Template:Quantum optics operators

10. Open quantum systems (9) Back to index

112. Physics:Quantum Open systems

113. Physics:Quantum Master equation

114. Physics:Quantum Lindblad equation

115. Physics:Quantum Decoherence

116. Physics:Quantum dissipation

117. Physics:Quantum Markov semigroup

118. Physics:Quantum Markovian dynamics

119. Physics:Quantum Non-Markovian dynamics

120. Physics:Quantum Trajectories

11. Quantum field theory (23) Back to index

121. Physics:Quantum field theory (QFT) basics

122. Physics:Quantum field theory (QFT) core

123. Physics:Quantum Fields and Particles

124. Physics:Quantum Second quantization

125. Physics:Quantum Fock space

126. Physics:Quantum Harmonic Oscillator field modes

127. Physics:Quantum Creation and annihilation operators

128. Physics:Quantum vacuum fluctuations

129. Physics:Quantum Casimir effect

130. Physics:Quantum Propagators in quantum field theory

131. Physics:Quantum Feynman diagrams

132. Physics:Quantum Path integral formulation

133. Physics:Quantum Renormalization in field theory

134. Physics:Quantum Renormalization group

135. Physics:Quantum Field Theory Gauge symmetry

136. Physics:Quantum Spontaneous symmetry breaking

137. Physics:Quantum Non-Abelian gauge theory

138. Physics:Quantum Electrodynamics (QED)

139. Physics:Quantum chromodynamics (QCD)

140. Physics:Quantum Electroweak theory

141. Physics:Quantum Standard Model

142. Physics:Quantum triviality

143. Physics:Quantum confinement problem

12. Statistical mechanics and kinetic theory (9) Back to index

144. Physics:Quantum Statistical mechanics

145. Physics:Quantum Partition function

146. Physics:Quantum Distribution functions

147. Physics:Quantum Liouville equation

148. Physics:Quantum Kinetic theory

149. Physics:Quantum Boltzmann equation

150. Physics:Quantum BBGKY hierarchy

151. Physics:Quantum Relaxation and thermalization

152. Physics:Quantum Thermodynamics

13. Condensed matter and solid-state physics (15) Back to index

153. Physics:Quantum Band structure

154. Physics:Quantum Fermi surfaces

155. Physics:Quantum Landau levels

156. Physics:Quantum Semiconductor physics

157. Physics:Quantum Phonons

158. Physics:Quantum Electron-phonon interaction

159. Physics:Quantum Exchange interaction

160. Physics:Quantum Superconductivity

161. Physics:Quantum Topological phases of matter

162. Physics:Quantum well

163. Physics:Quantum spin liquid

164. Physics:Quantum spin Hall effect

165. Physics:Quantum phase transition

166. Physics:Quantum critical point

167. Physics:Quantum dot

14. Plasma and fusion physics (8) Back to index

168. Physics:Quantum Fusion reactions and Lawson criterion

169. Physics:Quantum Plasma (fusion context)

170. Physics:Quantum Magnetic confinement fusion

171. Physics:Quantum Inertial confinement fusion

172. Physics:Quantum Plasma instabilities and turbulence

173. Physics:Quantum Tokamak core plasma

174. Physics:Quantum Tokamak edge physics and recycling asymmetries

175. Physics:Quantum Stellarator

15. Timeline (8) Back to index

176. Physics:Quantum mechanics/Timeline

177. Physics:Quantum mechanics/Timeline/Pre-quantum era

178. Physics:Quantum mechanics/Timeline/Old quantum theory

179. Physics:Quantum mechanics/Timeline/Modern quantum mechanics

180. Physics:Quantum mechanics/Timeline/Quantum field theory era

181. Physics:Quantum mechanics/Timeline/Quantum information era

182. Physics:Quantum mechanics/Timeline/Quantum technology era

183. Physics:Quantum mechanics/Timeline/Quiz

16. Advanced and frontier topics (16) Back to index

184. Physics:Quantum topology

185. Physics:Quantum battery

186. Physics:Quantum Supersymmetry

187. Physics:Quantum Black hole thermodynamics

188. Physics:Quantum Holographic principle

189. Physics:Quantum gravity

190. Physics:Quantum De Sitter invariant special relativity

191. Physics:Quantum Doubly special relativity

192. Physics:Quantum arithmetic geometry

193. Physics:Quantum unsolved problems

194. Physics:Quantum Yang-Mills mass gap

195. Physics:Quantum gravity problem

196. Physics:Quantum black hole information paradox

197. Physics:Quantum dark matter problem

198. Physics:Quantum neutrino mass problem

199. Physics:Quantum matter-antimatter asymmetry problem