SO(1,4) isometries yield explicit transformation laws and Ward identities for de Sitter amplitudes that reduce to Poincaré invariance at high momenta.
Eigenmodes of lens and prism spaces
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abstract
Cosmologists are taking a renewed interest in multiconnected spherical 3-manifolds (spherical spaceforms) as possible models for the physical universe. To understand the formation of large scale structures in such a universe, cosmologists express physical quantities, such as density fluctuations in the primordial plasma, as linear combinations of the eigenmodes of the Laplacian, which can then be integrated forward in time. This need for explicit eigenmodes contrasts sharply with previous mathematical investigations, which have focused on questions of isospectrality rather than eigenmodes. The present article provides explicit orthonormal bases for the eigenmodes of lens and prism spaces. As a corollary it extends known results on spectra from homogeneous lens spaces L(p,1) [Ikeda 1995] to arbitrary lens spaces L(p,q).
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UNVERDICTED 2representative citing papers
Tree-level three-gluon amplitudes in de Sitter spacetime are given by a general formula in terms of Wigner 3j symbols derived from SO(1,4) intertwiner integrals.
citing papers explorer
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Symmetries of de Sitter Particles and Amplitudes
SO(1,4) isometries yield explicit transformation laws and Ward identities for de Sitter amplitudes that reduce to Poincaré invariance at high momenta.
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Three-Gluon Scattering Amplitude in de Sitter Spacetime
Tree-level three-gluon amplitudes in de Sitter spacetime are given by a general formula in terms of Wigner 3j symbols derived from SO(1,4) intertwiner integrals.