Probing hydrogen intensity and fast radio bursts with CHIME and CHORD

En 2017, l'expérience canadienne de cartographie de l’intensité de l’hydrogène (Canadian Hydrogen Intensity Mapping Experiment, CHIME) a été mise en service pour la première fois. Son objectif : cartographier l’abondance de l’hydrogène dans l’univers et exploiter ces données afin de mesurer de façon indépendante le taux d’expansion cosmique. Mais CHIME s'est également révélé être un outil puissant pour détecter des événements transitoires dans le ciel nocturne, comme les mystérieux « sursauts radio rapides » (FRB), des signaux puissants et courts découverts pour la première fois en 2007. CHIME a désormais détecté plus de 4 000 FRB, alors que tous les autres télescopes combinés en ont détecté environ 300.

Le succès de CHIME tient en partie à sa philosophie de conception, qui transfère la complexité de l'instrument du matériel vers le logiciel. Les algorithmes utilisés par CHIME pour analyser les masses de données qu'il recueille sont sans égal, et les scientifiques de l’Institut Périmètre ont participé activement à la conception et au codage de ce logiciel.

Kendrick Smith, titulaire de la chaire Daniel Family James Peebles en physique théorique, ainsi que le professeur associé Ue-Li Pen, le scientifique en informatique Dustin Lang, le chercheur Seth Siegel et le chercheur postdoctoral Simon Foreman ont tous contribué à ce projet.

L’équipe a également contribué à la production de résultats scientifiques clés issus du projet CHIME, notamment l’identification de nouveaux sursauts radio rapides répétitifs offrant des pistes sur l’origine de ces signaux, ainsi que la découverte du premier FRB au sein de notre propre galaxie, dont la source a pu être localisée avec précision. Ces découvertes suggèrent que les magnétars – des étoiles à neutrons hautement magnétisées – sont probablement à l'origine de la plupart des FRB, bien que la physique exacte de ce processus ne soit pas encore comprise et que d'autres sources puissent exister.

L’Institut Périmètre et ses scientifiques sont également des partenaires clés du successeur de CHIME, L'Observatoire canadien de l'hydrogène et détecteur de transitoires radio (Canadian Hydrogen Observatory and Radio-transient Detector) (CHORD), un réseau de 512 antennes qui aura une sensibilité 10 fois supérieure à celle de CHIME. Actuellement en construction, CHORD devrait permettre de mieux cerner l'énergie noire et surpasser CHIME dans sa capacité à localiser

Articles connexes :

Collaboration CHIME/FRB, « A bright millisecond-duration radio burst from a Galactic magnetar ». Nature, volume 587, pages 54-58 (2020). 

Collaboration CHIME/FRB, « Sub-second periodicity in a fast radio burst ». Nature volume 607, pages 256-259 (2022) ; 

K. Vanderlinde et al. « LRP 2020 Whitepaper: The Canadian Hydrogen Observatory and Radio-transient Detector (CHORD) ». arXiv:1911.01777.

Devising new ways to test primordial non-Gaussianity

The early universe, as far as we can tell, was a strikingly simple place. The cosmos emerged from the hot big bang in an almost perfectly flat, homogeneous state. The primordial density variations appear to have had a uniform composition, and near-perfect Gaussianity – that is to say, the fluctuations, when plotted on a graph, match a perfectly normal distribution: a bell curve.

The universe’s simplicity presents a challenge to fundamental physics, because there is no straightforward explanation for how that homogenous early universe evolved into what we see today. We must either find a compelling explanation for this simplicity, or discover new observational clues going beyond the simplicity. Measuring the extent of non-Gaussianity (if there is any) would help refine possible models of the universe and improve our understanding of the period of cosmic inflation.

Perimeter researchers have been primary drivers of this research, approaching it from several angles. Neal Dalal (at the time a senior research associate at the Canadian Institute for Theoretical Astrophysics, and later a Perimeter faculty member) proposed a new test for non-Gaussianity in 2008, by measuring the clustering of galaxies in the universe. This idea was further developed by Perimeter visiting fellow Sarah Shandera. Their approach overcame a challenge known as scale-dependant galaxy bias, in which different sizes of galaxies clump together differently, making it complicated to track the evolution of the cosmic web in a simplistic way.

Meanwhile, Kendrick Smith, Daniel Family James Peebles Chair in Theoretical Physics, along with Perimeter Distinguished Visiting Research Chair Matias Zaldarriaga and their colleague Leonardo Senatore, advanced the development of new statistical methods required to test for non-Gaussianity using observations of the Cosmic Microwave Background (CMB) radiation taken by the WMAP and Planck experiments. The CMB is the remains of the first light to travel freely through the universe, about 380,000 years after the big bang. Their analyses show, with unprecedented precision, that our cosmological initial conditions seem to have been perfectly Gaussian, with no hint of primordial non-Gaussianity so far. These results represent a huge step forward in the precision measurement of the early universe, and provide a fundamental new constraint in theoretical cosmology.

More recently, Perimeter researchers have developed a completely novel way to test for non-Gaussianity, using what is known as the kinetic Sunyaev-Zeldovich (kSZ) effect: the Doppler shifting of CMB photons produced by scattering off ionized electrons in the late universe. Existing statistical methods were not powerful enough to disentangle different physical effects in the kSZ, but the Perimeter team, including Smith, research associate faculty Matthew Johnson, and postdoctoral researchers Matthew Madhavacheril, Moritz Münchmeyer, and Zheng Pan, developed new methods, enabling them to extract cosmological signals from kSZ. The first applications of these methods to real data were carried out by Johnson, Smith, and collaborators. These new kSZ statistical methods will be instrumental in probing data from the next major observation of the CMB, expected to come from the Simons Observatory, which began taking data in 2024, and are increasingly being adopted in cosmological data analysis. There has been a significant uptake in these methods across the scientific community.

Related Papers:

Neal Dalal, Olivier Doré, Dragan Huterer, and Alexander Shirokov, “Imprints of primordial non-Gaussianities on large-scale structure: Scale-dependent bias and abundance of virialized objects.” Phys. Rev. D 77, 123514 (2008).; 

Marilena LoVerde, Amber Miller, Sarah Shandera and Licia Verde, “Effects of scale-dependent non-Gaussianity on cosmological structures.” JCAP 014 (2008).; 

K. Smith, L. Senatore and M. Zaldarriaga, “Optimal Analysis of the CMB trispectrum,” arXiv: 1502.00635.; 

K. Smith et al., “Planck 2015 Results. XVII. Constraints on primordial non-Gaussianity,” arXiv: 1502.01592.; 

K. Smith, S. Ferraro, “Detecting patchy reionization in the CMB,” Phys. Rev. Lett. 119 (2017) 021301, [arXiv:1607.01769].; 

M. Münchmeyer, M. Madhavacheril, S. Ferraro, M. Johnson, K. Smith, “Constraining local non-Gaussianities with kSZ tomography,” Phys. Rev. D 100 (2019) 083508, [arXiv:1810.13424].; 

Z. Pan, M. Johnson, “Forecasted constraints on modified gravity from Sunyaev-Zeldovich tomography,” Phys. Rev. D 100 (2019) 0803522, [arXiv:1906.04208]. A. Deutsch, E. Dimastrogiovanni, M. Johnson, M. Münchmeyer and A. Terrana, “Reconstruction of the remote dipole and quadrupole fields from the kinetic Sunyaev Zel’dovich and polarized Sunyaev Zel’dovich effects,” Phys. Rev. D 98 (2018) 123501, [1707.08129 [astro-ph.CO]].; 

Cayuso, M. Johnson and J. Mertens, “Simulated reconstruction of the remote dipole field using the kinetic Sunyaev Zel’dovich effect,” Phys. Rev. D 98 (2018) 063502, [1806.01290 [astro-ph.CO]].; 

K. Smith, M. Madhavacheril, M. Münchmeyer, S. Ferraro, U. Giri and M. Johnson, “KSZ tomography and the bispectrum,” [1810.13423 [astro-ph.CO]].; 

Utkarsh Giri and Kendrick M. Smith, “Exploring KSZ velocity reconstruction with N-body simulations and the halo model,” J. Cosmol. Astropart. Phys. 2022 (2022) 028, [2010.07193 [astro-ph.CO]].; 

Selim C. Hotinli, Simone Ferraro, Gilbert P. Holder, Matthew C. Johnson, Marc Kamionkowski and Paul La Plante, “Probing helium reionization with kinetic Sunyaev Zel’dovich tomography.” [2207.07660 [astro-ph.CO]].; 

Selim C. Hotinli, Joel Meyers, Neal Dalal and Andrew H. Jaffe et al., “Transverse velocities with the moving lens effect,”  Phys. Rev. Lett. 123 (2019) 061301, [1812.03167 [astro-ph.CO]].;

 Selim C. Hotinli, Kendrick M. Smith, Mathew S. Madhavacheril and Marc Kamionkowski, “Cosmology with the moving lens effect,” Phys. Rev. D 104 (2021) 083529, [2108.02207 [astro-ph.CO]].; 

Selim C. Hotinli, Gilbert P. Holder, Matthew C. Johnson and Marc Kamionkowski, “Cosmology from the kinetic polarized Sunyaev Zel’dovich effect,” J. Cosmol. Astropart. Phys. 2022 (2022) 026, [2204.12503 [astro-ph.CO]].; 

Oliver H.E. Philcox and Matthew C. Johnson, “Novel cosmological tests from combining galaxy lensing and the polarized Sunyaev Zel’dovich effect.” Phys. Rev. D 106 (2022) 083501, [2206.07054 [astro-ph.CO]].; 

Richard Bloch, Matthew C. Johnson, “Kinetic Sunyaev Zel'dovich velocity reconstruction from Planck and unwise,” 2024, arxiv.org/abs/2405.00809.; 

Fiona McCarthy et al., “The Atacama Cosmology Telescope: Large-scale velocity reconstruction with the kinematic Sunyaev Zel'dovich effect and DESI LRGs.” JCAP 057 (2025).; 

Alex Laguë, Mathew S. Madhavacheril, Kendrick M. Smith, Simone Ferraro, Emmanuel Schaan, “Constraints on Local Primordial Non-Gaussianity with 3D Velocity Reconstruction from the Kinetic Sunyaev-Zeldovich Effect,” Phys.Rev.Lett. 134 (2025) 15, 151003.

Probing gravity and dark energy

Einstein’s general relativity (GR) has been a very successful theory of gravity, as tested within the Solar System and in measurements using pulsar signals. However, when astronomers try to reconcile it with cosmological observations, they are forced to invoke two mysterious energy components – dark matter and dark energy. These have only been detected gravitationally, yet they make up most of the energy and matter in the cosmos. In a related problem, quantum mechanics suggests the existence of vacuum energy – the result of ‘virtual particles’ that constantly emerge and annihilate, popping in and out of existence as particle-antiparticle pairs. This vacuum energy is one possible explanation for dark energy, but the predictions of its strength made by quantum mechanics, and the observed strength in the cosmos, are wildly different. It’s a conundrum called the cosmological constant problem.

This situation might be a clue that GR is not quite correct on large scales and must be modified in some way to resolve these conundrums. Modifications of GR that are theoretically and observationally consistent, however, are surprisingly hard to find. 

One promising modification of GR suggests that the graviton (a theoretical particle that mediates the gravitational force) has mass. The idea of ‘massive gravity’ goes all the way back to 1939, when it was theorized by Markus Fierz and Wolfgang Pauli, but their version was incomplete.

Some important work in developing a full theory of massive gravity came from Perimeter faculty member Justin Khoury. A major breakthrough followed in 2011, when Claudia de Rham and Andrew Tolley (together with Gregory Gabadadze) built off their postdoctoral research at Perimeter to develop a non-linear completion of Fierz and Pauli’s 1939 linearized theory. This was the first truly complete theory of massive gravity.

Massive gravity implies that gravitational waves must travel below the speed of light, offering the potential for future observational tests of the theory. Current gravitational wave detectors would need improved sensitivity to either confirm or rule out this possibility.

Massive gravity’s predictions match the observations of GR in the near universe, but modify it at large distances, and it could explain the accelerated expansion of the universe without the need for dark energy. This was a landmark result, and research building on this theory has continued to progress.

More recently, observational evidence is growing that dark energy may be dynamical and evolving over time. Perimeter research associate faculty Will Percival and computational scientist Dustin Lang are core members of the Dark Energy Spectroscopic Instrument (DESI) collaboration, which released the first hints of the dynamical nature of dark energy in 2024, and followed up in 2025 with more data. DESI’s science run is ongoing. Its outcomes will drive new work on both theoretical and observational efforts to find a complete explanation for dark energy, the cosmological constant problem, and gravity.
 

Related Papers:

Gia Dvali, Stefan Hofmann, and Justin Khoury, “Degravitation of the cosmological constant and graviton width,” Phys. Rev. D 76, 084006.; 

Claudia de Rham, Gregory Gabadadze, Andrew J. Tolley, “Resummation of Massive Gravity,” Phys.Rev.Lett.106:231101,2011, DESI Collaboration, “DESI 2024 III: Baryon Acoustic Oscillations from Galaxies and Quasars.” arXiv:2404.03000.; 

DESI Collaboration, DESI Collaboration, “DESI 2024 VI: Cosmological Constraints from the Measurements of Baryon Acoustic Oscillations” https://arxiv.org/abs/2404.03001; 

DESI Collaboration, “DESI 2024 VI: Cosmological Constraints from the Measurements of Baryon Acoustic Oscillations.”  https://arxiv.org/abs/2404.03002.; 

DESI Collaboration, “DESI DR2 Results II: Measurements of Baryon Acoustic Oscillations and Cosmological Constraints.” https://arxiv.org/abs/2503.14738.

More Turning Points:

 

More Turning Points

Cosmology

Perimeter researchers are reshaping our understanding of the cosmos, from the origins of fast radio bursts to new ways of probing dark energy and the early universe.

Mathematical Physics

From redefining holography to revealing hidden structures in gauge theory, Perimeter researchers are advancing the mathematical foundations that underpin modern physics.

Particle Physics

Perimeter scientists are pushing the boundaries of the Standard Model, from pioneering dark matter models to designing novel experiments probing hidden particles.

Quantum Foundations

What is quantum theory really telling us? Perimeter researchers are redefining its core principles and exploring what lies beyond, from axioms to causality.

Quantum Fields and Strings

From entanglement and holography to the revival of the S-matrix bootstrap, Perimeter researchers are charting new territory in the quantum fabric of reality.

Quantum Gravity

Uniting general relativity with quantum mechanics is one of physics’ great quests. Perimeter researchers are advancing bold ideas, from spin foams to holography, moving us closer.

Quantum Information

At the intersection of computation, cryptography, and black holes, Perimeter researchers are uncovering how information shapes the quantum world — and how we can harness it.

Quantum Matter

From machine learning in quantum systems to phases that defy thermalization, Perimeter researchers are uncovering new states of matter — and new ways to understand them.

Strong Gravity

Perimeter researchers are exploring gravity at its most extreme, from imaging black holes to simulating the cosmic origins of gold and other heavy elements.