Prof. David Alonso

Joint constraints on cosmology and the impact of baryon feedback: combining KiDS-1000 lensing with the thermal Sunyaev-Zeldovich effect from Planck and ACT

(2021)

Authors:

Tilman Tröster, Alexander J Mead, Catherine Heymans, Ziang Yan, David Alonso, Marika Asgari, Maciej Bilicki, Andrej Dvornik, Hendrik Hildebrandt, Benjamin Joachimi, Arun Kannawadi, Konrad Kuijken, Peter Schneider, HuanYuan Shan, Ludovic van Waerbeke, Angus H Wright

The LSST-DESC 3x2pt Tomography Optimization Challenge

(2021)

Authors:

Joe Zuntz, François Lanusse, Alex I Malz, Angus H Wright, Anže Slosar, Bela Abolfathi, David Alonso, Abby Bault, Clécio R Bom, Massimo Brescia, Adam Broussard, Jean-Eric Campagne, Stefano Cavuoti, Eduardo S Cypriano, Bernardo MO Fraga, Eric Gawiser, Elizabeth J Gonzalez, Dylan Green, Peter Hatfield, Kartheik Iyer, David Kirkby, Andrina Nicola, Erfan Nourbakhsh, Andy Park, Gabriel Teixeira, Katrin Heitmann, Eve Kovacs, Yao-Yuan Mao

Detecting ultra-high-energy cosmic ray anisotropies through harmonic cross-correlations

Astronomy & Astrophysics EDP Sciences 652 (2021) a41-a41

Authors:

Federico R Urban, Stefano Camera, David Alonso

Abstract:

We propose an observable for ultra-high-energy cosmic ray (UHECR) physics: the harmonic-space cross-correlation power spectrum between the arrival directions of UHECRs and the large-scale cosmic structure mapped by galaxies. This cross-correlation has not yet been considered in the literature, and it permits a direct theoretical modelling of the main astrophysical components. We describe the expected form of the cross-correlation and show how, if the distribution of UHECR sources traces the large-scale cosmic structure, it could be easier to detect with current data than the UHECR auto-correlation. Moreover, the cross-correlation is more sensitive to UHECR anisotropies on smaller angular scales, it is more robust to systematic uncertainties, and it could be used to determine the redshift distribution of UHECR sources, making it a valuable tool for determining their origins and properties.

Microwave spectro-polarimetry of matter and radiation across space and time

Experimental Astronomy Springer Nature 51:3 (2021) 1471-1514

Authors:

Jacques Delabrouille, Maximilian H Abitbol, Nabila Aghanim, Yacine Ali-Haïmoud, David Alonso, Marcelo Alvarez, Anthony J Banday, James G Bartlett, Jochem Baselmans, Kaustuv Basu, Nicholas Battaglia, José Ramón Bermejo Climent, José L Bernal, Matthieu Béthermin, Boris Bolliet, Matteo Bonato, François R Bouchet, Patrick C Breysse, Carlo Burigana, Zhen-Yi Cai, Jens Chluba, Eugene Churazov, Helmut Dannerbauer, Paolo De Bernardis, Gianfranco De Zotti, Eleonora Di Valentino, Emanuela Dimastrogiovanni, Akira Endo, Jens Erler, Simone Ferraro, Fabio Finelli, Dale Fixsen, Shaul Hanany, Luke Hart, Carlos Hernández-Monteagudo, J Colin Hill, Selim C Hotinli, Kenichi Karatsu, Kirit Karkare, Garrett K Keating, Ildar Khabibullin, Alan Kogut, Kazunori Kohri, Ely D Kovetz, Guilaine Lagache, Julien Lesgourgues, Mathew Madhavacheril, Bruno Maffei, Nazzareno Mandolesi, Carlos Martins

Abstract:

This paper discusses the science case for a sensitive spectro-polarimetric survey of the microwave sky. Such a survey would provide a tomographic and dynamic census of the three-dimensional distribution of hot gas, velocity flows, early metals, dust, and mass distribution in the entire Hubble volume, exploit CMB temperature and polarisation anisotropies down to fundamental limits, and track energy injection and absorption into the radiation background across cosmic times by measuring spectral distortions of the CMB blackbody emission. In addition to its exceptional capability for cosmology and fundamental physics, such a survey would provide an unprecedented view of microwave emissions at sub-arcminute to few-arcminute angular resolution in hundreds of frequency channels, a data set that would be of immense legacy value for many branches of astrophysics. We propose that this survey be carried out with a large space mission featuring a broad-band polarised imager and a moderate resolution spectro-imager at the focus of a 3.5 m aperture telescope actively cooled to about 8K, complemented with absolutely-calibrated Fourier Transform Spectrometer modules observing at degree-scale angular resolution in the 10–2000 GHz frequency range. We propose two observing modes: a survey mode to map the entire sky as well as a few selected wide fields, and an observatory mode for deeper observations of regions of specific interest.

Linear anisotropies in dispersion-measure-based cosmological observables

Physical Review D - Particles, Fields, Gravitation and Cosmology American Physical Society 103 (2021) 123544

Abstract:

We derive all contributions to the dispersion measure (DM) of electromagnetic pulses to linear order in cosmological perturbations, including both density fluctuations and relativistic effects. We then use this result to calculate the power spectrum of DM-based cosmological observables to linear order in perturbations. In particular we study two cases: maps of the dispersion measure from a set of localized sources (including the effects of source clustering), and fluctuations in the density of DM-selected sources. The impact of most relativistic effects is limited to large angular scales, and is negligible for all practical applications in the context of ongoing and envisaged observational programmes targetting fast radio bursts. We compare the leading contributions to DM-space clustering, including the effects of gravitational lensing, and find that the signal is dominated by the fluctuations in the free electron column density, rather than the local source clustering or lensing contributions. To compensate for the disappointing irrelevance of relativistic effects, we re-derive them in terms of the geodesic equation for massive particles in a perturbed Friedmann-Robertson-Walker metric.