Physics:Quantum Commutator: Difference between revisions

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[[File:Quantum_Commutator_educational_yellow.png|thumb|right|A commutator compares doing two quantum operations in different orders.]]
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In quantum mechanics, a '''commutator''' measures how much two operators fail to commute. For two operators <math>A</math> and <math>B</math>, the commutator is
In quantum mechanics, a '''commutator''' measures how much two operators fail to commute. For two operators <math>A</math> and <math>B</math>, the commutator is


<math>[A,B] = AB - BA.</math>
<math>[A,B] = AB - BA.</math>
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[[File:Quantum_Commutator_educational_yellow.png|thumb|280px|A commutator compares doing two quantum operations in different orders.]]
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== Role in quantum mechanics ==
== Role in quantum mechanics ==

Revision as of 21:41, 23 May 2026

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In quantum mechanics, a commutator measures how much two operators fail to commute. For two operators A and B, the commutator is

[A,B]=ABBA.

A commutator compares doing two quantum operations in different orders.

Role in quantum mechanics

Commutators are central because quantum observables are represented by operators. If two observables have a nonzero commutator, the corresponding quantities generally cannot both have sharply defined values in the same state.

The canonical position and momentum commutator is

[x,p]=iI.

This relation underlies the uncertainty principle and is one of the basic structures of matrix mechanics.

References


Author: Harold Foppele


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