Pauli–Lubanski pseudovector
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History |
In physics, the Pauli–Lubanski pseudovector is an operator defined from the momentum and angular momentum, used in the quantum-relativistic description of angular momentum. It is named after Wolfgang Pauli and Józef Lubański,[1]
It describes the spin states of moving particles.
Definition
It is usually denoted by W (or less often by S) and defined by:[4][5][6]
where
- is the four-dimensional totally antisymmetric Levi-Civita symbol;
- is the relativistic angular momentum tensoroperator ();
- is the four-momentum operator.
In the language of
Note , and Where is the generator of rotations and is the generator of boosts.
Wμ evidently satisfies
as well as the following commutator relations,
Consequently,
The scalar WμWμ is a Lorentz-invariant operator, and commutes with the four-momentum, and can thus serve as a label for irreducible unitary representations of the Poincaré group. That is, it can serve as the label for the spin, a feature of the spacetime structure of the representation, over and above the relativistically invariant label PμPμ for the mass of all states in a representation.
Little group
On an eigenspace of the
- The components of with replaced by form a Lie algebra. It is the Lie algebra of the Little group of , i.e. the subgroup of the homogeneous Lorentz group that leaves invariant.
- For every irreducible unitary representation of there is an irreducible unitary representation of the full Poincaré group called an induced representation.
- A representation space of the induced representation can be obtained by successive application of elements of the full Poincaré group to a non-zero element of and extending by linearity.
The irreducible unitary representation of the Poincaré group are characterized by the eigenvalues of the two Casimir operators and . The best way to see that an irreducible unitary representation actually is obtained is to exhibit its action on an element with arbitrary 4-momentum eigenvalue in the representation space thus obtained.[11] : 62–74 Irreducibility follows from the construction of the representation space.
Massive fields
In
It is straightforward to see this in the rest frame of the particle, the above commutator acting on the particle's state amounts to [Wj , Wk] = i εjkl Wl m; hence W→ = mJ→ and W0 = 0, so that the little group amounts to the rotation group,
It is also customary to take W3 to describe the spin projection along the third direction in the rest frame.
In moving frames, decomposing W = (W0, W→) into components (W1, W2, W3), with W1 and W2 orthogonal to P→, and W3 parallel to P→, the Pauli–Lubanski vector may be expressed in terms of the spin vector S→ = (S1, S2, S3) (similarly decomposed) as
where
The transverse components W1, W2, along with S3, satisfy the following commutator relations (which apply generally, not just to non-zero mass representations),
For particles with non-zero mass, and the fields associated with such particles,
Massless fields
In general, in the case of non-massive representations, two cases may be distinguished. For massless particles,[11]: 71–72
Continuous spin representations
In the more general case, the components of W→ transverse to P→ may be non-zero, thus yielding the family of representations referred to as the cylindrical luxons ("luxon" is another term for "massless particle"), their identifying property being that the components of W→ form a Lie subalgebra isomorphic to the 2-dimensional Euclidean group ISO(2), with the longitudinal component of W→ playing the role of the rotation generator, and the transverse components the role of translation generators. This amounts to a group contraction of SO(3), and leads to what are known as the continuous spin representations. However, there are no known physical cases of fundamental particles or fields in this family. It can be argued that continuous spin states possess an internal degree of freedom not seen in observed massless particles.[11]: 69–74
Helicity representations
In a special case, is parallel to or equivalently For non-zero this constraint can only be consistently imposed for luxons (massless particles), since the commutator of the two transverse components of is proportional to For this family, and the invariant is, instead given by
All particles that interact with the
) acquire non-zero mass.Neutrinos were formerly considered to fall into this class as well. However, because neutrinos have been observed to oscillate in flavour, it is now known that at least two of the three mass eigenstates of the left-helicity neutrinos and right-helicity anti-neutrinos each must have non-zero mass.
See also
- Center of mass (relativistic)
- Wigner's classification
- Angular momentum operator
- Casimir operator
- Chirality
- Pseudovector
- Pseudotensor
- Induced representation
Notes
- ^ Lubański 1942a, pp. 310–324, Lubański 1942b, pp. 325–338
- ^ Brown 1994, pp. 180–181
- ^ Wigner 1939, pp. 149–204
- ^ Ryder 1996, p. 62
- ^ Bogolyubov 1989, p. 273
- ^ Ohlsson 2011, p. 11
- ^ Penrose 2005, p. 568
- ^ Hall 2015, Formula 1.12.
- ^ Rossmann 2002, Chapter 2.
- ^ Tung 1985, Theorem 10.13, Chapter 10.
- ^ ISBN 978-0521550017.
References
- ISBN 0-7923-0540-X.
- ISBN 978-0-521-46946-3.
- Hall, Brian C. (2015), Lie groups, Lie algebras, and Representations: An Elementary Introduction, Graduate Texts in Mathematics, vol. 222 (2nd ed.), Springer, ISSN 0072-5285
- .
- Lubański, J. K. (1942b). "Sur la théorie des particules élémentaires de spin quelconque. II". Physica (in French). 9 (3): 325–338. .
- ISBN 978-1-139-50432-4.
- ISBN 978-0-09-944068-0.
- Rossmann, Wulf (2002), Lie Groups - An Introduction Through Linear Groups, Oxford Graduate Texts in Mathematics, Oxford Science Publications, ISBN 0-19-859683-9
- Ryder, L.H. (1996). Quantum Field Theory (2nd ed.). Cambridge University Press. ISBN 0-521-47814-6.
- Tung, Wu-Ki (1985). Group Theory in Physics (1st ed.). New Jersey·London·Singapore·Hong Kong: ISBN 978-9971966577.
- ISBN 0-521-55001-7
- S2CID 121773411.