Atacama Cosmology Telescope: Constraints on prerecombination early dark energy

Creators: Hill, J. Colin; Calabrese, Erminia; Aiola, Simone; Battaglia, Nicholas; Bolliet, Boris; Choi, Steve K.; Devlin, Mark J.; Duivenvoorden, Adriaan J.; Dunkley, Jo; Ferraro, Simone; Gallardo, Patricio A.; Gluscevic, Vera; Hasselfield, Matthew; Hilton, Matt; Hincks, Adam D.; Hlozek, Renee; Koopman, Brian J.; Kosowsky, Arthur; La Posta, Adrien; Louis, Thibaut; Madhavacheril, Mathew S.; McMahon, Jeff; Moodley, Kavilan; Naess, Sigurd; Natale, Umberto; Nati, Federico; Newburgh, Laura; Niemack, Michael D.; Page, Lyman A.; Partridge, Bruce; Qu, Frank J.; Salatino, Maria; Schillaci, Alessandro; Sehgal, Neelima; Sherwin, Blake D.; Sifón, Cristóbal; Spergel, David N.; Staggs, Suzanne T.; Storer, Emilie R.; van Engelen, Alexander; Vavagiakis, Eve M.; Wollack, Edward J.; Xu, Zhilei

Abstract

The early dark energy (EDE) scenario aims to increase the value of the Hubble constant (H₀) inferred from cosmic microwave background (CMB) data over that found in the standard cosmological model (Λ CDM), via the introduction of a new form of energy density in the early Universe. The EDE component briefly accelerates cosmic expansion just prior to recombination, which reduces the physical size of the sound horizon imprinted in the CMB. Previous work has found that nonzero EDE is not preferred by Planck CMB power spectrum data alone, which yield a 95% confidence level (C.L.) upper limit f_(EDE) < 0.087 on the maximal fractional contribution of the EDE field to the cosmic energy budget. In this paper, we fit the EDE model to CMB data from the Atacama Cosmology Telescope (ACT) data release 4. We find that a combination of ACT, large-scale Planck TT (similar to WMAP), Planck CMB lensing, and BAO data prefers the existence of EDE at > 99.7% C.L.: f_(EDE) = 0.091^(+0.020)_(−0.036), with H₀ = 70.9^(+1.0)_(−2.0) km/s/Mpc (both 68% C.L.). From a model-selection standpoint, we find that EDE is favored over Λ CDM by these data at roughly 3σ significance. In contrast, a joint analysis of the full Planck and ACT data yields no evidence for EDE, as previously found for Planck alone. We show that the preference for EDE in ACT alone is driven by its TE and EE power spectrum data. The tight constraint on EDE from Planck alone is driven by its high-ℓ TT power spectrum data. Understanding whether these differing constraints are physical in nature, due to systematics, or simply a rare statistical fluctuation is of high priority. The best-fit EDE models to ACT and Planck exhibit coherent differences across a wide range of multipoles in TE and EE, indicating that a powerful test of this scenario is anticipated with near-future data from ACT and other ground-based experiments.

Additional Information

© 2022 American Physical Society. (Received 14 September 2021; accepted 14 June 2022; published 30 June 2022) We are grateful to Evan McDonough and Michael Toomey for their contributions to the development of class_ede and for useful conversations, and we thank the Scientific Computing Core staff at the Flatiron Institute for computational support. The Flatiron Institute is supported by the Simons Foundation. E. C. acknowledges support from the STFC Ernest Rutherford Fellowship No. ST/M004856/2 and STFC Consolidated Grant No. ST/S00033X/1. EC and U. N. acknowledge support from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant Agreement No. 849169). J. D. and E. S. acknowledge support from NSF Grant No. AST-1814971. N. S. acknowledges support from NSF Grant No. AST-1907657. M. Hi. and K. M. acknowledge support from the National Research Foundation of South Africa. V. G. is supported by the National Science Foundation under Grant No. PHY-2013951. Z. X. is supported by the Gordon and Betty Moore Foundation. Research at Perimeter Institute is supported in part by the Government of Canada through the Department of Innovation, Science, and Industry Canada and by the Province of Ontario through the Ministry of Colleges and Universities. A. D. H. acknowledges support from the Sutton Family Chair in Science, Christianity, and Cultures and from the Faculty of Arts and Science, University of Toronto. S. K. C. acknowledges support from NSF Grant No. AST-2001866. E. V. acknowledges support from the NSF GRFP via Grant No. DGE-1650441. C. S. acknowledges support from the Agencia Nacional de Investigación y Desarrollo (ANID) under FONDECYT Grant No. 11191125. This work was completed at the Aspen Center for Physics, which is supported by National Science Foundation Grant No. PHY-1607611. Support for ACT was through the U.S. National Science Foundation through Grants No. AST-0408698, No. AST-0965625, and No. AST-1440226 for the Atacama Cosmology Telescope (ACT) project, as well as Grants No. PHY-0355328, No. PHY-0855887, and No. PHY-1214379. Funding was also provided by Princeton University, the University of Pennsylvania, and a Canada Foundation for Innovation (CFI) award to UBC. ACT operates in the Parque Astronómico Atacama in northern Chile under the auspices of the Agencia Nacional de Investigación y Desarrollo (ANID). The development of multichroic detectors and lenses was supported by NASA Grants No. NNX13AE56G and No. NNX14AB58G. Detector research at NIST was supported by the NIST Innovations in Measurement Science program. We acknowledge use of the matplotlib [97], numpy [98], getdist [82], cobaya [74], and cosmomc [75] packages and use of the Boltzmann codes camb [85] and class [84].

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