Abstract
The momentum-independent Casimir operators of the homogeneous spin-Lorentz group are employed in the construction of covariant projector operators, which can decompose anyone of its reducible finite-dimensional representation spaces into irreducible components. One of the benefits from such operators is that any one of the finite-dimensional carrier spaces of the Lorentz group representations can be equipped with Lorentz vector indices because any such space can be embedded in a Lorentz tensor of a properly-designed rank and then be unambiguously found by a projector. In particular, all the carrier spaces of the single-spin-valued Lorentz group representations, which so far have been described as 2 ( 2 j + 1 ) column vectors, can now be described in terms of Lorentz tensors for bosons or Lorentz tensors with the Dirac spinor component, for fermions. This approach facilitates the construct of covariant interactions of high spins with external fields in so far as they can be obtained by simple contractions of the relevant S O ( 1 , 3 ) indices. Examples of Lorentz group projector operators for spins varying from 1 / 2 –2 and belonging to distinct product spaces are explicitly worked out. The decomposition of multiple-spin-valued product spaces into irreducible sectors suggests that not only the highest spin, but all the spins contained in an irreducible carrier space could correspond to physical degrees of freedom.
Highlights
IntroductionParticles of high-spins j ≥ 1, be they massive or mass-less, play a significant role in field theories
Particles of high-spins j ≥ 1, be they massive or mass-less, play a significant role in field theories.In the physics of hadrons, such fields appear as real resonances whose spins can vary from 1/2–17/2 for baryons and from 0–6 for mesons [1]
We present the technique of the covariant spin-Lorentz group projectors, which allows equipping by Lorentz indices any finite-dimensional irreducible representation space through embedding in properly-designed tensor products
Summary
Particles of high-spins j ≥ 1, be they massive or mass-less, play a significant role in field theories. 1939 and 1964 (see [5,6] for recent reviews and [7] for a standard textbook) and are based on the use of carrier (representation) spaces of finite-dimensional representations of the homogeneous Lorentz group. They are associated with the names of Fierz and Pauli (FP) [8], Rarita and Schwinger (RS) [9], Laporte and Uhlenbeck (LU) [10], Cap and Donnert (CD) [11,12,13], Bargmann and Wigner (BW) [14], as well as to those of Joos [15] and Weinberg [16] (JW).
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