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Postulates quantum postulates are the core assumptions of quantum mechanics. They specify how physical systems are represented, how observables are defined, how measurements produce probabilities and state updates, and how states evolve in time. In the standard formulation, a system is described by a complex Hilbert space, observables are represented by self-adjoint operators, measurement statistics are given by the Born rule, and time evolution is governed by the Schrödinger equation. Quantum postulates are the core assumptions of quantum mechanics. They specify how physical systems are represented, how observables are defined, how measurements produce probabilities and state updates, and how states evolve in time. In the standard formulation, a system is described by a complex Hilbert space, observables are represented by self-adjoint operators, measurement statistics are given by the Born rule, and time evolution is governed by the Schrödinger equation. The postulates can be grouped into a small number of operational rules.

Overview of the postulates

The postulates can be grouped into a small number of operational rules. Together they define how a system is represented, how measurements are predicted, and how the state changes in time.

Postulate	Mathematical object	Physical role
State postulate	Hilbert-space vector $\| ψ ⟩$ or density operator $ρ$	Represents the preparation of the system
Observable postulate	Self-adjoint operator $A$	Represents a measurable quantity
Born rule	$P (a_{n}) = ⟨ ψ \| P_{n} \| ψ ⟩$ or $P (a_{n}) = t r (P_{n} ρ)$	Gives probabilities for measurement outcomes
Projection postulate	$\| ψ ⟩ \mapsto P_{n} \| ψ ⟩ / \sqrt{⟨ ψ \| P_{n} \| ψ ⟩}$	Describes ideal state update after a measurement result
Time-evolution postulate	$i ℏ d \| ψ ⟩ / d t = H \| ψ ⟩$	Gives deterministic evolution between measurements
Composite-system postulate	Tensor product $ℋ_{A} \otimes ℋ_{B}$	Describes compound systems and entanglement
Symmetrization postulate	Symmetric or antisymmetric many-particle states	Distinguishes bosons and fermions

Physical system

A physical system is described by states, observables, and dynamics. In classical mechanics, states are points in phase space and observables are real-valued functions on that space. In quantum mechanics, by contrast, states are rays or density operators on a Hilbert space, and observables are self-adjoint operators acting on that space.^[1]

State space and quantum states

Each isolated physical system is associated with a separable complex Hilbert space $ℋ$ with inner product. At a fixed time, the physical state is represented by a normalized vector $| ψ ⟩ \in ℋ$ , up to an overall phase.^[2]^[3]

Postulate I

The state of an isolated physical system is represented, at a fixed time

t

, by a state vector

| ψ ⟩

belonging to a Hilbert space

ℋ

called the state space.

Two normalized vectors represent the same physical state if they differ only by a phase factor:

$| ψ_{k} ⟩ \sim | ψ_{l} ⟩ \Leftrightarrow | ψ_{k} ⟩ = e^{i α} | ψ_{l} ⟩, α \in ℝ .$

Thus the physical state is properly a ray in projective Hilbert space rather than a single vector.^[4]

Composite systems

For a composite system, the total state space is the tensor product of the state spaces of the component subsystems.^[5]

Composite system postulate

The Hilbert space of a composite system is the Hilbert space tensor product of the state spaces associated with the component systems.

If a composite state cannot be factored into subsystem states, the system is entangled. In that case, subsystems are generally described not by state vectors but by density operators $ρ$ , which are positive self-adjoint trace-class operators normalized by $t r (ρ) = 1$ .^[6]

A separable bipartite mixed state can be written as

$ρ = \sum_{k} p_{k} ρ_{1}^{k} \otimes ρ_{2}^{k}, \sum_{k} p_{k} = 1.$

If only one term is present, the state is a product state:

$ρ = ρ_{1} \otimes ρ_{2} .$

Observables and measurement

A measurable physical quantity is represented by a self-adjoint operator on $ℋ$ . Its eigenvalues are the possible outcomes of measurement.

Postulate II.a

Every measurable physical quantity

𝒜

is described by a Hermitian operator

A

acting in the state space

ℋ

. The result of measuring

𝒜

must be one of the eigenvalues of

A

.

Since self-adjoint operators have real spectra, measurement results are real numbers. For discrete spectra, the outcomes are quantized.

Born rule

The probabilities of measurement outcomes are determined by the projection of the state onto the eigenspaces of the observable.^[7]

Postulate II.b

When the physical quantity

𝒜

is measured on a system in a normalized state

| ψ ⟩

, the probability of obtaining an eigenvalue of the corresponding observable

A

is given by the amplitude squared of the projection onto the corresponding eigenspace.

For a discrete nondegenerate spectrum,

$ℙ (a_{n}) = | ⟨ a_{n} | ψ ⟩ |^{2} .$

For a discrete degenerate spectrum,

$ℙ (a_{n}) = \sum_{i}^{g_{n}} | ⟨ a_{n}^{i} | ψ ⟩ |^{2} .$

For a continuous nondegenerate spectrum,

$d ℙ (α) = | ⟨ α | ψ ⟩ |^{2} d α .$

For a mixed state $ρ$ , the expectation value of an observable $A$ is

$⟨ A ⟩ = t r (A ρ),$

and the probability of obtaining eigenvalue $a_{n}$ is

$ℙ (a_{n}) = t r (P_{n} ρ),$

where $P_{n}$ is the projection operator onto the eigensubspace associated with $a_{n}$ .

State update after measurement

In an ideal projective measurement, once the result $a_{n}$ is obtained, the state updates to the normalized projection onto the associated eigensubspace.

Postulate II.c

If the measurement of the physical quantity

𝒜

on the system in the state

| ψ ⟩

gives the result

a_{n}

, then the state immediately after the measurement is the normalized projection of

| ψ ⟩

onto the eigensubspace associated with

a_{n}

.

$| ψ ⟩ \overset{a_{n}}{⟹} \frac{P_{n} | ψ ⟩}{\sqrt{⟨ ψ | P_{n} | ψ ⟩}} .$

For a mixed state, the corresponding update rule is

$ρ^{'} = \frac{P_{n} ρ P_{n}^{†}}{t r (P_{n} ρ P_{n}^{†})} .$

The Born rule together with this state-update rule gives the standard projective measurement scheme. More general quantum measurements are described by positive operator-valued measures.^[8]

Time evolution

The time evolution of a closed quantum system is governed by the Schrödinger equation.

Postulate III

The time evolution of the state vector

| ψ (t) ⟩

is governed by the Schrödinger equation

$i ℏ \frac{d}{d t} | ψ (t) ⟩ = H (t) | ψ (t) ⟩,$

where $H (t)$ is the Hamiltonian of the system.

Equivalently, time evolution may be expressed by a unitary operator:

$| ψ (t) ⟩ = U (t; t_{0}) | ψ (t_{0}) ⟩ .$

For a mixed state,

$ρ (t) = U (t; t_{0}) ρ (t_{0}) U^{†} (t; t_{0}) .$

Open systems generally evolve nonunitarily and are instead described by quantum operations, quantum instruments, or master-equation formalisms.^[9]

Further implications

Several important consequences follow from the postulates.

Physical symmetries act on the Hilbert space by unitary or antiunitary transformations, as stated by Wigner's theorem.^[10]
Pure states correspond to one-dimensional orthogonal projectors, while general density operators describe mixed states.
The uncertainty principle can be derived as a theorem of the operator formalism.

These show that the postulates are not merely interpretive statements but the basis of the full mathematical structure of quantum theory.

Spin

All particles possess intrinsic angular momentum called spin. Unlike classical rotation, quantum spin is an intrinsic property with no direct classical analogue. For a particle of spin $S$ , the spin degree of freedom introduces the discrete values

$σ = - S ℏ, - (S - 1) ℏ, \dots, 0, \dots, (S - 1) ℏ, S ℏ .$

A single-particle state of spin $S$ is therefore represented by a $(2 S + 1)$ -component spinor. Integer-spin particles are bosons, while half-integer-spin particles are fermions.^[11]

Symmetrization postulate

For a system of identical particles, the total wavefunction must be either symmetric or antisymmetric under exchange of any pair of particles.^[12]

Symmetrization postulate

The wavefunction of a system of

N

identical particles in three dimensions is either totally symmetric (bosons) or totally antisymmetric (fermions) under interchange of any pair of particles.

This requirement underlies the distinction between bosons and fermions and is closely related to the spin-statistics theorem. In two spatial dimensions, more general exchange behavior can occur, leading to anyons.^[13]

Pauli exclusion principle

For fermions, antisymmetry of the wavefunction implies the Pauli exclusion principle: no two identical fermions can occupy the same one-particle quantum state.

Pauli principle

ψ (\dots, 𝐫_{i}, σ_{i}, \dots, 𝐫_{j}, σ_{j}, \dots) = (- 1)^{2 S} ψ (\dots, 𝐫_{j}, σ_{j}, \dots, 𝐫_{i}, σ_{i}, \dots)

For bosons the prefactor is $+ 1$ ; for fermions it is $- 1$ . This distinction underlies atomic shell structure and many properties of matter.^[14]^[15]

Table of contents (217 articles)

Index

Core theory

1. Foundations

2. Conceptual and interpretations

3. Mathematical structure and systems

4. Atomic and spectroscopy

5. Wavefunctions and modes

6. Quantum dynamics and evolution

7. Measurement and information

8. Quantum information and computing

Applications and extensions

9. Quantum optics and experiments

10. Open quantum systems

11. Quantum field theory

12. Statistical mechanics and kinetic theory

13. Condensed matter and solid-state physics

14. Plasma and fusion physics

15. Timeline

16. Advanced and frontier topics

Book II

Matter by scale

Book III

Methods and tools

Book IV

Data Analysis Techniques

Full contents

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

7. Measurement and information (9) Back to index

88. Physics:Quantum Measurement theory

89. Physics:Quantum Measurement operators

90. Physics:Quantum Projective measurement

91. Physics:Quantum POVM

92. Physics:Quantum Weak measurement

93. Physics:Quantum Measurement collapse

94. Physics:Quantum entanglement

95. Physics:Quantum Zeno effect

96. Physics:Quantum limit

8. Quantum information and computing (15) Back to index

97. Physics:Quantum information theory

98. Physics:Quantum Qubit

99. Physics:Quantum Entanglement

100. Physics:Quantum Bell state

101. Physics:Quantum Gates and circuits

102. Physics:Quantum BB84

103. Physics:Quantum No-cloning theorem

104. Physics:Quantum Computing Algorithms in the NISQ Era

105. Physics:Quantum Noisy Qubits

106. Physics:Quantum error correction

107. Physics:Quantum Boson sampling

108. Physics:Quantum random access code

109. Physics:Quantum pseudo-telepathy

110. Physics:Quantum network

111. Physics:Quantum money

9. Quantum optics and experiments (10) Back to index

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

113. Physics:Quantum Stern-Gerlach experiment

114. Physics:Quantum Experimental quantum physics

115. Physics:Quantum optics

116. Physics:Quantum optics beam splitter experiments

117. Physics:Quantum Mach-Zehnder interferometer

118. Physics:Quantum Hong-Ou-Mandel effect

119. Physics:Quantum eraser experiment

120. Physics:Quantum delayed-choice quantum eraser

121. Physics:Quantum Ultra fast lasers

122. Template:Quantum optics operators

10. Open quantum systems (15) Back to index

123. Physics:Quantum Open systems

124. Physics:Quantum channel

125. Physics:Quantum Kraus operators

126. Physics:Quantum Amplitude damping

127. Physics:Quantum Phase damping

128. Physics:Quantum Depolarizing channel

129. Physics:Quantum Master equation

130. Physics:Quantum Lindblad equation

131. Physics:Quantum Decoherence

132. Physics:Quantum Dynamical decoupling

133. Physics:Quantum dissipation

134. Physics:Quantum Markov semigroup

135. Physics:Quantum Markovian dynamics

136. Physics:Quantum Non-Markovian dynamics

137. Physics:Quantum Trajectories

11. Quantum field theory (23) Back to index

138. Physics:Quantum field theory (QFT) basics

139. Physics:Quantum field theory (QFT) core

140. Physics:Quantum Fields and Particles

141. Physics:Quantum Second quantization

142. Physics:Quantum Fock space

143. Physics:Quantum Harmonic Oscillator field modes

144. Physics:Quantum Creation and annihilation operators

145. Physics:Quantum vacuum fluctuations

146. Physics:Quantum Casimir effect

147. Physics:Quantum Propagators in quantum field theory

148. Physics:Quantum Feynman diagrams

149. Physics:Quantum Path integral formulation

150. Physics:Quantum Renormalization in field theory

151. Physics:Quantum Renormalization group

152. Physics:Quantum Field Theory Gauge symmetry

153. Physics:Quantum Spontaneous symmetry breaking

154. Physics:Quantum Non-Abelian gauge theory

155. Physics:Quantum Electrodynamics (QED)

156. Physics:Quantum chromodynamics (QCD)

157. Physics:Quantum Electroweak theory

158. Physics:Quantum Standard Model

159. Physics:Quantum triviality

160. Physics:Quantum confinement problem

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

161. Physics:Quantum Statistical mechanics

162. Physics:Quantum Partition function

163. Physics:Quantum Distribution functions

164. Physics:Quantum Liouville equation

165. Physics:Quantum Kinetic theory

166. Physics:Quantum Boltzmann equation

167. Physics:Quantum BBGKY hierarchy

168. Physics:Quantum Relaxation and thermalization

169. Physics:Quantum Thermodynamics

13. Condensed matter and solid-state physics (17) Back to index

170. Physics:Quantum Band structure

171. Physics:Quantum Fermi surfaces

172. Physics:Quantum Landau levels

173. Physics:Quantum fractional Hall effect

174. Physics:Quantum Semiconductor physics

175. Physics:Quantum Phonons

176. Physics:Quantum Electron-phonon interaction

177. Physics:Quantum Exchange interaction

178. Physics:Quantum Superconductivity

179. Physics:Quantum Topological phases of matter

180. Physics:Quantum anyon

181. Physics:Quantum well

182. Physics:Quantum spin liquid

183. Physics:Quantum spin Hall effect

184. Physics:Quantum phase transition

185. Physics:Quantum critical point

186. Physics:Quantum dot

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

187. Physics:Quantum Fusion reactions and Lawson criterion

188. Physics:Quantum Plasma (fusion context)

189. Physics:Quantum Magnetic confinement fusion

190. Physics:Quantum Inertial confinement fusion

191. Physics:Quantum Plasma instabilities and turbulence

192. Physics:Quantum Tokamak core plasma

193. Physics:Quantum Tokamak edge physics and recycling asymmetries

194. Physics:Quantum Stellarator

15. Timeline (8) Back to index

195. Physics:Quantum mechanics/Timeline

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

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

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

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

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

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

202. Physics:Quantum mechanics/Timeline/Quiz

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

203. Physics:Quantum topology

204. Physics:Quantum battery

205. Physics:Quantum Supersymmetry

206. Physics:Quantum Black hole thermodynamics

207. Physics:Quantum Holographic principle

208. Physics:Quantum gravity

209. Physics:Quantum De Sitter invariant special relativity

210. Physics:Quantum Doubly special relativity

211. Physics:Quantum arithmetic geometry

212. Physics:Quantum unsolved problems

213. Physics:Quantum Yang-Mills mass gap

214. Physics:Quantum gravity problem

215. Physics:Quantum black hole information paradox

216. Physics:Quantum dark matter problem

217. Physics:Quantum neutrino mass problem

218. Physics:Quantum matter-antimatter asymmetry problem

References

↑ Weyl, Hermann (1950). The Theory of Groups and Quantum Mechanics. Dover. Bibcode: 1950tgqm.book.....W.
↑ Bäuerle, Gerard G. A.; de Kerf, Eddy A. (1990). Lie Algebras, Part 1: Finite and Infinite Dimensional Lie Algebras and Applications in Physics. Studies in Mathematical Physics. Amsterdam: North Holland. ISBN 0-444-88776-8.
↑ Solem, J. C.; Biedenharn, L. C. (1993). "Understanding geometrical phases in quantum mechanics: An elementary example". Foundations of Physics 23 (2): 185–195. doi:10.1007/BF01883623. Bibcode: 1993FoPh...23..185S.
↑ Bäuerle, Gerard G. A.; de Kerf, Eddy A. (1990). Lie Algebras, Part 1: Finite and Infinite Dimensional Lie Algebras and Applications in Physics. Studies in Mathematical Physics. Amsterdam: North Holland. ISBN 0-444-88776-8.
↑ Jauch, J. M.; Wigner, E. P.; Yanase, M. M. (1997). "Some Comments Concerning Measurements in Quantum Mechanics". Part I: Particles and Fields. Part II: Foundations of Quantum Mechanics. Berlin, Heidelberg: Springer Berlin Heidelberg. pp. 475–482. doi:10.1007/978-3-662-09203-3_52. ISBN 978-3-642-08179-8. https://archive-ouverte.unige.ch/unige:162146.
↑ Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.
↑ Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.
↑ Jauch, J. M.; Wigner, E. P.; Yanase, M. M. (1997). "Some Comments Concerning Measurements in Quantum Mechanics". Part I: Particles and Fields. Part II: Foundations of Quantum Mechanics. Berlin, Heidelberg: Springer Berlin Heidelberg. pp. 475–482. doi:10.1007/978-3-662-09203-3_52. ISBN 978-3-642-08179-8. https://archive-ouverte.unige.ch/unige:162146.
↑ Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.
↑ Weyl, Hermann (1950). The Theory of Groups and Quantum Mechanics. Dover. Bibcode: 1950tgqm.book.....W.
↑ Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.
↑ Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.
↑ Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.
↑ Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.
↑ Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.

Author: Harold Foppele

Source attribution: Physics:Quantum Postulates

[1] Weyl, Hermann (1950). The Theory of Groups and Quantum Mechanics. Dover. Bibcode: 1950tgqm.book.....W.

[2] Bäuerle, Gerard G. A.; de Kerf, Eddy A. (1990). Lie Algebras, Part 1: Finite and Infinite Dimensional Lie Algebras and Applications in Physics. Studies in Mathematical Physics. Amsterdam: North Holland. ISBN 0-444-88776-8.

[3] Solem, J. C.; Biedenharn, L. C. (1993). "Understanding geometrical phases in quantum mechanics: An elementary example". Foundations of Physics 23 (2): 185–195. doi:10.1007/BF01883623. Bibcode: 1993FoPh...23..185S.

[4] Bäuerle, Gerard G. A.; de Kerf, Eddy A. (1990). Lie Algebras, Part 1: Finite and Infinite Dimensional Lie Algebras and Applications in Physics. Studies in Mathematical Physics. Amsterdam: North Holland. ISBN 0-444-88776-8.

[5] Jauch, J. M.; Wigner, E. P.; Yanase, M. M. (1997). "Some Comments Concerning Measurements in Quantum Mechanics". Part I: Particles and Fields. Part II: Foundations of Quantum Mechanics. Berlin, Heidelberg: Springer Berlin Heidelberg. pp. 475–482. doi:10.1007/978-3-662-09203-3_52. ISBN 978-3-642-08179-8. https://archive-ouverte.unige.ch/unige:162146.

[6] Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.

[7] Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.

[8] Jauch, J. M.; Wigner, E. P.; Yanase, M. M. (1997). "Some Comments Concerning Measurements in Quantum Mechanics". Part I: Particles and Fields. Part II: Foundations of Quantum Mechanics. Berlin, Heidelberg: Springer Berlin Heidelberg. pp. 475–482. doi:10.1007/978-3-662-09203-3_52. ISBN 978-3-642-08179-8. https://archive-ouverte.unige.ch/unige:162146.

[9] Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.

[10] Weyl, Hermann (1950). The Theory of Groups and Quantum Mechanics. Dover. Bibcode: 1950tgqm.book.....W.

[11] Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.

[12] Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.

[13] Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.

[14] Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.

[15] Cohen-Tannoudji, Claude; Diu, Bernard; Laloë, Franck (2020). Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA. ISBN 978-3-527-82272-0.

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@@ Line 1: / Line 1: @@
 {{Short description|Core assumptions of quantum mechanics}}
+{{Quantum book backlink|Foundations}}
+{{Quantum article nav|previous=Physics:Quantum Planck constant|previous label=Planck constant|next=Physics:Quantum Hilbert space|next label=Hilbert space}}
+<div style="display:flex; gap:24px; align-items:flex-start; max-width:1200px;">
-{{Quantum book backlink|Foundations}}
+<div style="width:280px;">
+__TOC__
+</div>
+<div style="flex:1; line-height:1.45; color:#006b45; column-count:2; column-gap:32px; column-rule:1px solid #b8d8c8;">
+'''Postulates''' quantum postulates are the core assumptions of quantum mechanics. They specify how physical systems are represented, how observables are defined, how measurements produce probabilities and state updates, and how states evolve in time. In the standard formulation, a system is described by a complex Hilbert space, observables are represented by self-adjoint operators, measurement statistics are given by the Born rule, and time evolution is governed by the Schrödinger equation. Quantum postulates are the core assumptions of quantum mechanics. They specify how physical systems are represented, how observables are defined, how measurements produce probabilities and state updates, and how states evolve in time. In the standard formulation, a system is described by a complex Hilbert space, observables are represented by self-adjoint operators, measurement statistics are given by the Born rule, and time evolution is governed by the Schrödinger equation. The postulates can be grouped into a small number of operational rules.
+</div>
-<div style="float:left; clear:left; width:285px; margin:0 20px 15px 0;">
+<div style="width:300px;">
 [[File:Quantum postulates1.jpg|thumb|280px|Basic structure of the quantum postulates: states, observables, measurement, and time evolution.]]
 </div>
-<div style="max-width:920px; line-height:1.45; color:#006b45; column-count:2; column-gap:32px; column-rule:1px solid #b8d8c8;">
-'''Quantum postulates''' are the core assumptions of [[Physics:Quantum mechanics|quantum mechanics]]. They specify how physical systems are represented, how observables are defined, how measurements produce probabilities and state updates, and how states evolve in time. In the standard formulation, a system is described by a complex [[Physics:Quantum Hilbert space|Hilbert space]], observables are represented by self-adjoint operators, measurement statistics are given by the [[Physics:Born rule|Born rule]], and time evolution is governed by the [[Physics:Quantum Schrödinger equation|Schrödinger equation]].<ref>{{cite book | last1=Cohen-Tannoudji | first1=Claude | last2=Diu | first2=Bernard | last3=Laloë | first3=Franck | title=Quantum mechanics. Volume 2: Angular momentum, spin, and approximation methods | publisher=Wiley-VCH Verlag GmbH & Co. KGaA | publication-place=Weinheim | date=2020 | isbn=978-3-527-82272-0}}</ref>
 </div>
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-=Physical system=
+== Physical system ==
 A physical system is described by states, observables, and dynamics. In classical mechanics, states are points in phase space and observables are real-valued functions on that space. In quantum mechanics, by contrast, states are rays or density operators on a Hilbert space, and observables are self-adjoint operators acting on that space.<ref>{{cite book | last=Weyl | first=Hermann | title=The Theory of Groups and Quantum Mechanics | title-link=Gruppentheorie und Quantenmechanik | publisher=Dover | translator-first=H. P. | translator-last=Robertson | year=1950 | orig-year=1931 | bibcode=1950tgqm.book.....W }}</ref>
@@ Line 175: / Line 182: @@
 Several important consequences follow from the postulates.
-* Physical symmetries act on the Hilbert space by unitary or antiunitary transformations, as stated by [[Physics:Quantum Wigner's theorem|Wigner's theorem]].<ref>{{cite book | last=Weyl | first=Hermann | title=The Theory of Groups and Quantum Mechanics | title-link=Gruppentheorie und Quantenmechanik | publisher=Dover | translator-first=H. P. | translator-last=Robertson | year=1950 | orig-year=1931 | bibcode=1950tgqm.book.....W }}</ref>
+* Physical symmetries act on the Hilbert space by unitary or antiunitary transformations, as stated by Wigner's theorem.<ref>{{cite book | last=Weyl | first=Hermann | title=The Theory of Groups and Quantum Mechanics | title-link=Gruppentheorie und Quantenmechanik | publisher=Dover | translator-first=H. P. | translator-last=Robertson | year=1950 | orig-year=1931 | bibcode=1950tgqm.book.....W }}</ref>
 * Pure states correspond to one-dimensional orthogonal projectors, while general density operators describe mixed states.
 * The [[Physics:Quantum Uncertainty principle|uncertainty principle]] can be derived as a theorem of the operator formalism.
@@ Line 183: / Line 190: @@
 == Spin ==
-All particles possess intrinsic angular momentum called [[Physics:Quantum spin|spin]]. Unlike classical rotation, quantum spin is an intrinsic property with no direct classical analogue. For a particle of spin <math>S</math>, the spin degree of freedom introduces the discrete values
+All particles possess intrinsic angular momentum called spin. Unlike classical rotation, quantum spin is an intrinsic property with no direct classical analogue. For a particle of spin <math>S</math>, the spin degree of freedom introduces the discrete values
 <math display="block">\sigma=-S\hbar,\;-(S-1)\hbar,\;\dots,\;0,\;\dots,\;(S-1)\hbar,\;S\hbar.</math>
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 }}
-This requirement underlies the distinction between bosons and fermions and is closely related to the [[Physics:Quantum spin-statistics theorem|spin-statistics theorem]]. In two spatial dimensions, more general exchange behavior can occur, leading to [[Physics:Quantum anyon|anyon]]s.<ref>{{cite book | last1=Sakurai | first1=Jun John | last2=Napolitano | first2=Jim | title=Modern quantum mechanics | publisher=Cambridge University Press | isbn=978-1-108-47322-4 | edition=3rd | location=Cambridge | year=2021}}</ref>
+This requirement underlies the distinction between bosons and fermions and is closely related to the spin-statistics theorem. In two spatial dimensions, more general exchange behavior can occur, leading to anyons.<ref>{{cite book | last1=Sakurai | first1=Jun John | last2=Napolitano | first2=Jim | title=Modern quantum mechanics | publisher=Cambridge University Press | isbn=978-1-108-47322-4 | edition=3rd | location=Cambridge | year=2021}}</ref>
 === Pauli exclusion principle ===
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 [[Category:Quantum mechanics]]
-{{Sourceattribution|Quantum Postulates|1}}
+{{Sourceattribution|Physics:Quantum Postulates|1}}

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Latest revision as of 11:30, 22 May 2026

Contents

Overview of the postulates

Physical system

State space and quantum states

Composite systems

Observables and measurement

Born rule

State update after measurement

Time evolution

Further implications

Spin

Symmetrization postulate

Pauli exclusion principle

See also

Table of contents (217 articles)

Index

Full contents

References

Navigation

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Anonymous

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Physics:Quantum Postulates: Difference between revisions

Latest revision as of 11:30, 22 May 2026

Overview of the postulates

Physical system

State space and quantum states

Composite systems

Observables and measurement

Born rule

State update after measurement

Time evolution

Further implications

Spin

Symmetrization postulate

Pauli exclusion principle

See also

Table of contents (217 articles)

Index

Full contents

References

Navigation

Wiki tools

Page tools

Categories