Professor Pedro Ferreira

Constraints on quantum gravity and the photon mass from gamma ray bursts

Physical Review D American Physical Society 104:10 (2021) 103516

Authors:

Dj Bartlett, H Desmond, Pg Ferreira, J Jasche

Abstract:

Lorentz invariance violation in quantum gravity (QG) models or a nonzero photon mass, mγ, would lead to an energy-dependent propagation speed for photons, such that photons of different energies from a distant source would arrive at different times, even if they were emitted simultaneously. By developing source-by-source, Monte Carlo-based forward models for such time delays from gamma ray bursts, and marginalizing over empirical noise models describing other contributions to the time delay, we derive constraints on mγ and the QG length scale, ℓQG, using spectral lag data from the BATSE satellite. We find mγ<4.0×10-5 h eV/c2 and ℓQG<5.3×10-18 h GeV-1 at 95% confidence, and demonstrate that these constraints are robust to the choice of noise model. The QG constraint is among the tightest from studies which consider multiple gamma ray bursts and the constraint on mγ, although weaker than from using radio data, provides an independent constraint which is less sensitive to the effects of dispersion by electrons.

Dynamical friction from scalar dark matter in the relativistic regime

Physical Review D American Physical Society 104:10 (2021) 103014

Authors:

Dina Traykova, Katherine Clough, Thomas Helfer, Emanuele Berti, Pedro G Ferreira, Lam Hui

Abstract:

Light bosonic scalars (e.g., axions) may form clouds around black holes via superradiant instabilities or via accretion if they form some component of the dark matter. It has been suggested that their presence may lead to a distinctive dephasing of the gravitational wave signal when a small compact object spirals into a larger black hole. Motivated by this, we study numerically the dynamical friction force on a black hole moving at relativistic velocities in a background scalar field with an asymptotically homogeneous energy density. We show that the relativistic scaling is analogous to that found for supersonic collisional fluids, assuming an approximate expression for the pressure correction which depends on the velocity and scalar mass. While we focus on a complex scalar field, our results confirm the expectation that real scalars would exert a force which oscillates between positive and negative values in time with a frequency set by the scalar mass. The complex field describes the time averaged value of this force, but in a real scalar, the rapid force oscillations could, in principle, leave an imprint on the trajectory. The approximation we obtain can be used to inform estimates of dephasing in the final stages of an extreme mass ratio inspiral.

Euclid preparation

Astronomy & Astrophysics EDP Sciences 655 (2021) a44

Authors:

A Pocino, I Tutusaus, FJ Castander, P Fosalba, M Crocce, A Porredon, S Camera, V Cardone, S Casas, T Kitching, F Lacasa, M Martinelli, A Pourtsidou, Z Sakr, S Andreon, N Auricchio, C Baccigalupi, A Balaguera-Antolínez, M Baldi, A Balestra, S Bardelli, R Bender, A Biviano, C Bodendorf, D Bonino, A Boucaud, E Bozzo, E Branchini, M Brescia, J Brinchmann, C Burigana, R Cabanac, V Capobianco, A Cappi, CS Carvalho, M Castellano, G Castignani, S Cavuoti, A Cimatti, R Cledassou, C Colodro-Conde, G Congedo, CJ Conselice, L Conversi, Y Copin, L Corcione, A Costille, J Coupon, HM Courtois, M Cropper, J-G Cuby, A Da Silva, S de la Torre, D Di Ferdinando, F Dubath, C Duncan, X Dupac, S Dusini, S Farrens, PG Ferreira, I Ferrero, F Finelli, S Fotopoulou, M Frailis, E Franceschi, S Galeotta, B Garilli, W Gillard, B Gillis, C Giocoli, G Gozaliasl, J Graciá-Carpio, F Grupp, L Guzzo, W Holmes, F Hormuth, K Jahnke, E Keihanen, S Kermiche, A Kiessling, CC Kirkpatrick, M Kunz, H Kurki-Suonio, S Ligori, PB Lilje, I Lloro, D Maino, E Maiorano, O Mansutti, O Marggraf, N Martinet, F Marulli, R Massey, S Maurogordato, E Medinaceli, S Mei, M Meneghetti, R Benton Metcalf, G Meylan, M Moresco, B Morin, L Moscardini, E Munari, R Nakajima, C Neissner, RC Nichol, S Niemi, J Nightingale, C Padilla, S Paltani, F Pasian, L Patrizii, K Pedersen, WJ Percival, V Pettorino, S Pires, G Polenta, M Poncet, L Popa, D Potter, L Pozzetti, F Raison, A Renzi, J Rhodes, G Riccio, E Romelli, M Roncarelli, E Rossetti, R Saglia, AG Sánchez, D Sapone, R Scaramella, P Schneider, V Scottez, A Secroun, G Seidel, S Serrano, C Sirignano, G Sirri, L Stanco, F Sureau, AN Taylor, M Tenti, I Tereno, R Teyssier, R Toledo-Moreo, A Tramacere, EA Valentijn, L Valenziano, J Valiviita, T Vassallo, M Viel, Y Wang, N Welikala, L Whittaker, A Zacchei, G Zamorani, J Zoubian, E Zucca

The growth of density perturbations in the last ∼10 billion years from tomographic large-scale structure data

Journal of Cosmology and Astroparticle Physics IOP Publishing 10:2021 (2021) 030

Authors:

Carlos Garcia-Garcia, Jaime Ruiz Zapatero, David Alonso, Emilio Bellini, Pedro Ferreira, Eva Mueller, Andrina Nicola, Pilar Ruiz-Lapuente

Abstract:

In order to investigate the origin of the ongoing tension between the amplitude of matter fluctuations measured by weak lensing experiments at low redshifts and the value inferred from the cosmic microwave background anisotropies, we reconstruct the evolution of this amplitude from z ∼ 2 using existing large-scale structure data. To do so, we decouple the linear growth of density inhomogeneities from the background expansion, and constrain its redshift dependence making use of a combination of 6 different data sets, including cosmic shear, galaxy clustering and CMB lensing. We analyze these data under a consistent harmonic-space angular power spectrum-based pipeline. We show that current data constrain the amplitude of fluctuations mostly in the range 0.2 < z < 0.7, where it is lower than predicted by Planck. This difference is mostly driven by current cosmic shear data, although the growth histories reconstructed from different data combinations are consistent with each other, and we find no evidence of systematic deviations in any particular experiment. In spite of the tension with Planck, the data are well-described by the ΛCDM model, albeit with a lower value of S8 ≡ σ8(Ωm/0.3)0.5 . As part of our analysis, we find constraints on this parameter of S8 = 0.7781 ± 0.0094 (68% confidence level), reaching almost percent-level errors comparable with CMB measurements, and 3.4σ away from the value found by Planck.

Theoretical priors in scalar-tensor cosmologies: shift-symmetric Horndeski models

Physical Review D American Physical Society 104:8 (2021) 83502

Authors:

Dina Traykova, Emilio Bellini, Pedro G Ferreira, Carlos García-García, Johannes Noller, Miguel Zumalacárregui

Abstract:

Attempts at constraining theories of late time accelerated expansion often assume broad priors for the parameters in their phenomenological description. Focusing on shift-symmetric scalar-tensor theories with standard gravitational wave speed, we show how a more careful analysis of their dynamical evolution leads to much narrower priors. In doing so, we propose a simple and accurate parametrization of these theories, capturing the redshift dependence of the equation of state, w (z), and the kinetic braiding parameter, αB(z) , with only two parameters each, and derive their statistical distribution (also known as theoretical priors) that fit the cosmology of the underlying model. We have considered two versions of the shift-symmetric model, one where the energy density of dark energy is given solely by the scalar field and another where it also has a contribution from the cosmological constant. By including current data, we show how theoretical priors can be used to improve constraints by up to an order of magnitude. Moreover, we show that shift-symmetric theories without a cosmological constant are observationally viable. We work up to quartic order in first derivatives of the scalar in the action, and our results suggest this truncation is a good approximation to more general shift-symmetric theories. This work establishes an actionable link between phenomenological parametrizations and Lagrangian-based theories, the two main approaches to test cosmological gravity and cosmic acceleration.