49 research outputs found
Cubic interactions of massless bosonic fields in three dimensions
Parity-even cubic vertices of massless bosons of arbitrary spins in three
dimensional Minkowski space are classified in the metric-like formulation. As
opposed to higher dimensions, there is at most one vertex for any given triple
in three dimensions. All the vertices with more than three
derivatives are of the type , and involving scalar
and/or Maxwell fields. All other vertices contain two (three) derivatives, when
the sum of the spins is even (odd). Minimal coupling to gravity, , has
two derivatives and is universal for all spins (equivalence principle holds).
Minimal coupling to Maxwell field, , distinguishes spins and
as it involves one derivative in the former case and three
derivatives in the latter case. Some consequences of this classification are
discussed.Comment: 18 page
A note on higher-derivative actions for free higher-spin fields
Higher-derivative theories of free higher-spin fields are investigated
focusing on their symmetries. Generalizing familiar two-derivative constrained
formulations, we first construct less-constrained Einstein-like and
Maxwell-like higher-derivative actions. Then, we construct Weyl-like actions -
the actions admitting constrained Weyl symmetries - with different numbers of
derivatives. They are presented in a factorized form making use of
Einstein-like and Maxwell-like tensors. The last (highest-derivative) member of
the hierarchy of the Weyl-like actions coincides with the Fradkin-Tseytlin
conformal higher-spin action in four dimensions.Comment: Version to appear in JHEP, 22 page
Weyl Action of Two-Column Mixed-Symmetry Field and Its Factorization Around (A)dS Space
We investigate the four-derivative free Weyl action for two-column
mixed-symmetry field that makes use of maximal gauge symmetries. In flat space,
the action can be uniquely determined from gauge and Weyl (trace shift)
symmetry requirements. We show that there is a smooth and unique deformation of
the flat action to (A)dS which keeps the same amount of gauge symmetries. This
action admits a factorization into two distinct two-derivative actions having
gauge parameters of different Young diagrams. Hence, this factorization pattern
naturally extends that of the Weyl actions of symmetric higher spin fields to
mixed-symmetry cases. The mass-deformation for these actions can be realized
preserving one of the gauge symmetries. Although generically non-unitary, in
special dimensions, unitarity is achieved selecting different mass deformations
for dS and AdS. We consider particular examples of our construction such as New
Massive Gravity in three dimensions, linearized bigravity in four dimensions
and their arbitrary dimensional generalizations.Comment: 25 pages, minor corrections, references added, version published in
JHE
Cubic interactions of massless bosonic fields in three dimensions II: Parity-odd and Chern-Simons vertices
This work completes the classification of the cubic vertices for arbitrary
spin massless bosons in three dimensions started in a previous companion paper
by constructing parity-odd vertices. Similarly to the parity-even case, there
is a unique parity-odd vertex for any given triple
of massless bosons if the triangle inequalities are satisfied ()
and none otherwise. These vertices involve two (three) derivatives for odd
(even) values of the sum . A non-trivial relation between
parity-even and parity-odd vertices is found. Similarly to the parity-even
case, the scalar and Maxwell matter can couple to higher spins through current
couplings with higher derivatives. We comment on possible lessons for 2d CFT.
We also derive both parity-even and parity-odd vertices with Chern-Simons
fields and comment on the analogous classification in two dimensions.Comment: 29 page
Notes on higher-spin algebras: minimal representations and structure constants
The higher-spin (HS) algebras so far known can be interpreted as the
symmetries of the minimal representation of the isometry algebra. After
discussing this connection briefly, we generalize this concept to any classical
Lie algebras and consider the corresponding HS algebras. For sp(2N) and so(N),
the minimal representations are unique so we get unique HS algebras. For sl(N),
the minimal representation has one-parameter family, so does the corresponding
HS algebra. The so(N) HS algebra is what underlies the Vasiliev theory while
the sl(2) one coincides with the 3D HS algebra hs[lambda]. Finally, we derive
the explicit expression of the structure constant of these algebras --- more
precisely, their bilinear and trilinear forms. Several consistency checks are
carried out for our results.Comment: minor corrections, references adde
Conformal invariant interaction of a scalar field with the higher spin field in AdS_{D}
The explicit form of linearized gauge invariant interactions of scalar and
general higher even spin fields in the space is obtained. In the case
of general spin a generalized 'Weyl' transformation is proposed and the
corresponding 'Weyl' invariant action is constructed. In both cases the
invariant actions of the interacting higher even spin gauge field and the
scalar field include the whole tower of invariant actions for couplings of the
same scalar with all gauge fields of smaller even spin. For the particular
value of all results are in exact agreement with hep-th/0403241Comment: 18 pages, Latex,v.2 accepted in Mod. Phys. Lett.
Higher-derivative massive actions from dimensional reduction
A procedure to obtain higher-derivative free massive actions is proposed. It
consists in dimensional reduction of conventional two-derivative massless
actions, where solutions to constraints bring in higher derivatives. We apply
this procedure to derive the arbitrary dimensional generalizations of
(linearized) New Massive Gravity and New Topologically Massive Gravity.Comment: 18 page
Partially-massless higher-spin algebras and their finite-dimensional truncations
The global symmetry algebras of partially-massless (PM) higher-spin (HS)
fields in (A)dS are studied. The algebras involving PM generators up to
depth are defined as the maximal symmetries of free conformal
scalar field with order wave equation in dimensions. We review
the construction of these algebras by quotienting certain ideals in the
universal enveloping algebra of isometries. We discuss another
description in terms of Howe duality and derive the formula for computing trace
in these algebras. This enables us to explicitly calculate the bilinear form
for this one-parameter family of algebras. In particular, the bilinear form
shows the appearance of additional ideal for any non-negative integer values of
, which coincides with the annihilator of the one-row -box
Young diagram representation of . Hence, the
corresponding finite-dimensional coset algebra spanned by massless and PM
generators is equivalent to the symmetries of this representation.Comment: 22 pages, references added, revised version, accepted to JHE
Higher Spin Interacting Quantum Field Theory and Higher Order Conformal Invariant Lagrangians
This thesis includes several original results. All of them are already
published or submitted for publication. I present here the short summary of
main results: The ultraviolet singular structure of the bulk-to-bulk
propagators for higher spin gauge fields in AdS4 space is analyzed in details.
One loop mass renormalization is studied on a simple example. The conformal
invariant Lagrangian with the k-th power of Laplacian for the hierarchy of
conformally coupled scalars with increasing scaling dimensions connected with
the k-th Euler density is rederived using the Fefferman-Graham ambient space
approach. The corresponding gauged ambient metric, Fefferman- Graham expansion
and extended Penrose-Brown-Henneaux transformations are proposed and analyzed.
Linearized gauge invariant interactions of scalar and general higher even spin
fields in the AdSD space are obtained. A generalized Weyl transformation is
proposed and the corresponding Weyl invariant action for cubic coupling of a
scalar to a spin \ell field is constructed. Using Noether's procedure several
cubic interactions between different HS gauge fields are derived, including
cubic selfinteraction of even spin gauge fields in a flat background. Then the
main result - the complete off-shell gauge invariant Lagrangian for the
trilinear interactions of Higher Spin Fields with arbitrary spins s1, s2, s3 in
a flat background is presented. All possibilities with different numbers of
derivatives are discussed. Restrictions on the number of derivatives are
obtained. For any possible number of derivatives this interaction is uniquely
fixed by gauge invariance up to partial integration and field redefinition.
Finally an off-shell generating function for all cubic interactions of Higher
Spin gauge fields is presented. It is written in a compact way, and turns out
to have a remarkable structure.Comment: PhD thesis, Department of Theoretical Physics, Yerevan Physics
Institute (2010), 130 pages, late
Vertex-Constraints in 3D Higher Spin Theories
We analyse the constraints imposed by gauge invariance on higher-order
interactions between massless bosonic fields in three-dimensional higher-spin
gravities. We show that vertices of quartic and higher order that are
independent of the cubic ones can only involve scalars and Maxwell fields. As a
consequence, the full non-linear interactions of massless higher-spin fields
are completely fixed by the cubic vertex.Comment: 5 page