Beecroft Institute for Particle Astrophysics and Cosmology

Simulated observations of high-redshift galaxies with the HARMONI spectrograph for the European Extremely Large Telescope

Proceedings of SPIE--the International Society for Optical Engineering SPIE, the international society for optics and photonics 9908 (2016) 99089y-99089y-9

Authors:

Sarah Kendrew, Simon Zieleniewski, Ryan CW Houghton, Niranjan Thatte, Julien Devriendt, Matthias Tecza, Fraser Clarke, Kieran O'Brien, Boris Häußler

The Python Sky Model: software for simulating the Galactic microwave sky

(2016)

Authors:

Ben Thorne, Jo Dunkley, David Alonso, Sigurd Naess

Weak-lensing mass calibration of the Atacama Cosmology Telescope equatorial Sunyaev-Zeldovich cluster sample with the Canada-France-Hawaii telescope stripe 82 survey

Journal of Cosmology and Astroparticle Physics IOP Publishing 2016:08 (2016) 013

Authors:

N Battaglia, A Leauthaud, H Miyatake, M Hasselfield, MB Gralla, R Allison, JR Bond, E Calabrese, D Crichton, MJ Devlin, J Dunkley, R Dünner, T Erben, S Ferrara, M Halpern, M Hilton, JC Hill, AD Hincks, R Hložek, KM Huffenberger, JP Hughes, JP Kneib, A Kosowsky, M Makler, TA Marriage, F Menanteau, Lance Miller, K Moodley, B Moraes, MD Niemack, L Page, H Shan, N Sehgal, BD Sherwin, JL Sievers, C Sifón, DN Spergel, ST Staggs, JE Taylor, R Thornton, LV Waerbeke, EJ Wollack

Abstract:

Mass calibration uncertainty is the largest systematic effect for using clusters of galaxies to constrain cosmological parameters. We present weak lensing mass measurements from the Canada-France-Hawaii Telescope Stripe 82 Survey for galaxy clusters selected through their high signal-to-noise thermal Sunyaev-Zeldovich (tSZ) signal measured with the Atacama Cosmology Telescope (ACT). For a sample of 9 ACT clusters with a tSZ signal-to-noise greater than five the average weak lensing mass is (4.8±0.8) ×1014 Mo, consistent with the tSZ mass estimate of (4.70±1.0) ×1014 Mo which assumes a universal pressure profile for the cluster gas. Our results are consistent with previous weak-lensing measurements of tSZ-detected clusters from the Planck satellite. When comparing our results, we estimate the Eddington bias correction for the sample intersection of Planck and weak-lensing clusters which was previously excluded.

A general theory of linear cosmological perturbations: scalar-tensor and vector-tensor theories

Journal of Cosmology and Astroparticle Physics IOP Publishing 2016:8 (2016) 007

Authors:

Macarena Lagos, Tessa Baker, Pedro Ferreira, Johannes Noller

Abstract:

We present a method for parametrizing linear cosmological perturbations of theories of gravity, around homogeneous and isotropic backgrounds. The method is sufficiently general and systematic that it can be applied to theories with any degrees of freedom (DoFs) and arbitrary gauge symmetries. In this paper, we focus on scalar-tensor and vector-tensor theories, invariant under linear coordinate transformations. In the case of scalar-tensor theories, we use our framework to recover the simple parametrizations of linearized Horndeski and ''Beyond Horndeski'' theories, and also find higher-derivative corrections. In the case of vector-tensor theories, we first construct the most general quadratic action for perturbations that leads to second-order equations of motion, which propagates two scalar DoFs. Then we specialize to the case in which the vector field is time-like (à la Einstein-Aether gravity), where the theory only propagates one scalar DoF. As a result, we identify the complete forms of the quadratic actions for perturbations, and the number of free parameters that need to be defined, to cosmologically characterize these two broad classes of theories.

Reconstructing cosmic growth with kinetic Sunyaev-Zel’dovich observations in the era of stage IV experiments

Physical Review D American Physical Society 94:4 (2016) 043522

Authors:

David Alonso, Thibaut Louis, Philip Bull, Pedro Ferreira

Abstract:

Future ground-based cosmic microwave background (CMB) experiments will generate competitive large-scale structure data sets by precisely characterizing CMB secondary anisotropies over a large fraction of the sky. We describe a method for constraining the growth rate of structure to sub-1% precision out to z≈1, using a combination of galaxy cluster peculiar velocities measured using the kinetic Sunyaev-Zel'dovich (kSZ) effect, and the velocity field reconstructed from galaxy redshift surveys. We consider only thermal SZ-selected cluster samples, which will consist of O(104-105) sources for Stage 3 and 4 CMB experiments respectively. Three different methods for separating the kSZ effect from the primary CMB are compared, including a novel blind "constrained realization" method that improves signal-to-noise by a factor of ∼2 over a commonly-used aperture photometry technique. Assuming a correlation between the integrated tSZ y-parameter and the cluster optical depth, it should then be possible to break the kSZ velocity-optical depth degeneracy. The effects of including CMB polarization and SZ profile uncertainties are also considered. In the absence of systematics, a combination of future Stage 4 experiments should be able to measure the product of the growth and expansion rates, α≡fH, to better than 1% in bins of Δz=0.1 out to z≈1 - competitive with contemporary redshift-space distortion constraints from galaxy surveys. We conclude with a discussion of the likely impact of various systematics.