Poincaré group

The Poincaré group, named after Henri Poincaré (1906),^[1] was first defined by Hermann Minkowski (1908) as the isometry group of Minkowski spacetime.^[2]^[3] It is a ten-dimensional non-abelian Lie group that is of importance as a model in our understanding of the most basic fundamentals of physics.

For the Poincaré group (fundamental group) of a topological space, see Fundamental group.

Overview[edit]

The Poincaré group consists of all coordinate transformations of Minkowski space that do not change the spacetime interval between events. For example, if everything were postponed by two hours, including the two events and the path you took to go from one to the other, then the time interval between the events recorded by a stopwatch that you carried with you would be the same. Or if everything were shifted five kilometres to the west, or turned 60 degrees to the right, you would also see no change in the interval. It turns out that the proper length of an object is also unaffected by such a shift.

In total, there are ten degrees of freedom for such transformations. They may be thought of as translation through time or space (four degrees, one per dimension); reflection through a plane (three degrees, the freedom in orientation of this plane); or a "boost" in any of the three spatial directions (three degrees). Composition of transformations is the operation of the Poincaré group, with rotations being produced as the composition of an even number of reflections.

In classical physics, the Galilean group is a comparable ten-parameter group that acts on absolute time and space. Instead of boosts, it features shear mappings to relate co-moving frames of reference.

In general relativity, i.e. under the effects of gravity, Poincaré symmetry applies only locally. A treatment of symmetries in general relativity is not in the scope of this article.

(displacements) in time and space, forming the abelian Lie group of spacetime translations (P);

translations

in space, forming the non-abelian Lie group of three-dimensional rotations (J);

rotations

, transformations connecting two uniformly moving bodies (K).

boosts

Poincaré symmetry is the full symmetry of special relativity. It includes:

The last two symmetries, J and K, together make the Lorentz group (see also Lorentz invariance); the semi-direct product of the spacetime translations group and the Lorentz group then produce the Poincaré group. Objects that are invariant under this group are then said to possess Poincaré invariance or relativistic invariance.

10 generators (in four spacetime dimensions) associated with the Poincaré symmetry, by Noether's theorem, imply 10 conservation laws:^[4]^[5]

Euclidean group

Galilean group

Representation theory of the Poincaré group

Wigner's classification

Symmetry in quantum mechanics

Pauli–Lubanski pseudovector

Particle physics and representation theory

Continuous spin particle

super-Poincaré algebra

Wu-Ki Tung (1985). Group Theory in Physics. World Scientific Publishing. 9971-966-57-3.

ISBN

Weinberg, Steven (1995). . Vol. 1. Cambridge: Cambridge University press. ISBN 978-0-521-55001-7.

The Quantum Theory of Fields

L.H. Ryder (1996). (2nd ed.). Cambridge University Press. p. 62. ISBN 0-52147-8146.