Abstract
In $D=2+1$ dimensions, elementary particles of a given helicity can be described by local Lagrangians (parity singlets). By means of a "soldering" procedure two opposite helicities can be joined together and give rise to massive spin-$s$ particles carrying both helicities $\pm s$ (parity doublets), such Lagrangians can also be used in $D=3+1$ to describe massive spin-$s$ particles. From this point of view the parity singlets (self-dual models) in $D=2+1$ are the building blocks of real massive elementary particles in $D=3+1$. In the three cases $s=1,\, 3/2,\, 2$ there are $2s$ self-dual models of order $1,2, \cdots, 2s$ in derivatives. In the spin-3 case the 5th order model is missing in the literature. Here we deduce a 5th order spin-3 self-dual model and fill up this gap. It is shown to be ghost free by means of a master action which relates it with the top model of 6th order. We believe that our approach can be generalized to arbitrary integer spin-$s$ in order to obtain the models of order $2s$ and $2s-1$. We also comment on the difficulties in relating the 5th order model with their lower order duals.
Highlights
In D 1⁄4 2 þ 1 dimensions, elementary particles of a given helicity can be described by local Lagrangians
By means of a “soldering” procedure, two opposite helicities can be joined together and give rise to massive spin-s particles carrying both helicities Æs, and such Lagrangians can be used in D 1⁄4 3 þ 1 to describe massive spin-s particles
We have not yet seen higher spin (s ≥ 3=2) elementary particles in nature, massive particles of arbitrarily high spin are predicted by string theory
Summary
We have not yet seen higher spin (s ≥ 3=2) elementary particles in nature, massive particles of arbitrarily high spin are predicted by string theory. The higher derivative self-dual models can be obtained from their first order counterparts order by order (LðSsDÞj → LðSsDÞðjþ1Þ) in, at least, two different ways: either by means of a master action approach [14] (spin-1) (see [15,16]) for the spin-2 case, or via a Noether gauge embedding (NGE) procedure where the amount of local symmetries increases along with the number of derivatives; see [17] (spin-1), [18] (spin-3=2) and [16] (spin-2) Those three cases are consistent with a “2s” rule for the highest possible order in derivatives of a ghost-free selfdual model for spin-s particles.
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