Beecroft Institute for Particle Astrophysics and Cosmology

From particles to orbits: precise dark matter density profiles using dynamical information

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 527:3 (2023) 9250-9262

Authors:

Claudia Muni, Andrew Pontzen, Jason L Sanders, Martin P Rey, Justin I Read, Oscar Agertz

Impact of Galactic dust non-Gaussianity on searches for B-modes from inflation

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 527:3 (2023) 5751-5766

Authors:

Irene Abril-Cabezas, Carlos Hervías-Caimapo, Sebastian von Hausegger, Blake D Sherwin, David Alonso

Spatially homogeneous universes with late-time anisotropy

Classical and Quantum Gravity IOP Publishing 40:24 (2023) 245015

Authors:

Andrei Constantin, Thomas R Harvey, Sebastian von Hausegger, Andre Lukas

Abstract:

The cosmological principle asserts that on sufficiently large scales the Universe is homogeneous and isotropic on spatial slices. To deviate from this principle requires a departure from the FLRW ansatz. In this paper we analyze the cosmological evolution of two spatially homogeneous but anisotropic universes, namely the spatially closed Kantowski–Sachs Universe and the open axisymmetric Bianchi type III Universe. These models are characterized by two scale factors and we study their evolution in universes with radiation, matter and a cosmological constant. In all cases, the two scale factors evolve differently and this anisotropy leads to a lensing effect in the propagation of light. We derive explicit formulae for computing redshifts, angular diameter distances and luminosity distances and discuss the predictions of these models in relation to observations for type Ia supernovae and the CMB. We comment on the possibility of explaining the observed luminosity distance plot for type Ia supernovae within the context of cosmologies featuring late-time anisotropy and a vanishing cosmological constant.

Spatially homogeneous universes with late-time anisotropy

Classical and Quantum Gravity IOP Publishing 40 (2023) 245015

Authors:

Andrei Constantin, Thomas Harvey, Sebastian Von Hausegger, Andre Lukas

Abstract:

The cosmological principle asserts that on sufficiently large scales the Universe is homogeneous and isotropic on spatial slices. To deviate from this principle requires a departure from the FLRW ansatz. In this paper we analyze the cosmological evolution of two spatially homogeneous but anisotropic universes, namely the spatially closed Kantowski–Sachs Universe and the open axisymmetric Bianchi type III Universe. These models are characterized by two scale factors and we study their evolution in universes with radiation, matter and a cosmological constant. In all cases, the two scale factors evolve differently and this anisotropy leads to a lensing effect in the propagation of light. We derive explicit formulae for computing redshifts, angular diameter distances and luminosity distances and discuss the predictions of these models in relation to observations for type Ia supernovae and the CMB. We comment on the possibility of explaining the observed luminosity distance plot for type Ia supernovae within the context of cosmologies featuring late-time anisotropy and a vanishing cosmological constant.

Solving the initial conditions problem for modified gravity theories

Physical Review D American Physical Society (APS) 108:10 (2023) 104022

Authors:

Sam E Brady, Llibert Aresté Saló, Katy Clough, Pau Figueras, PS Annamalai