Your search keyword '"RIESS, ADAM G."' showing total 8 results

1. Cosmic Confusion.

Author

KAMIONKOWSKI, MARC and RIESS, ADAM G.

Subjects

*PARTICLE physics, *PHYSICAL cosmology, *SOLAR system, *STARS, *TYPE II supernovae, *COSMIC background radiation, *DARK energy, *HUBBLE constant

Abstract

The article discusses the discrepancy between measurements of the universe's expansion rate, known as the Hubble constant, and the predictions of the standard model of cosmology. Astronomers have observed that the expansion rate measured through supernovae observations in the nearby universe does not agree with the rate predicted by the standard model. This inconsistency, known as the "Hubble tension," has become more pronounced over time and poses a challenge to the standard model. One possible explanation for this tension is the concept of early dark energy, which suggests that the universe expanded faster in its early stages due to an additional repulsive force. Experiments are currently being conducted to test this idea. The article also explains the methods used to measure the Hubble constant through supernovae observations and the cosmic microwave background (CMB). The CMB-inferred value of the Hubble constant is smaller than the local value obtained through supernovae observations, which presents a problem for the standard model. The article concludes by highlighting the need for further research and data to determine if the expansion of the cosmos is deviating from predictions and to understand the reasons behind it. The Hubble tension refers to the discrepancy between two methods of calculating the expansion rate of the universe, known as the Hubble constant. One method involves using a distance ladder to measure the distances and velocities of galaxies, while the other method involves studying the cosmic microwave background (CMB) and using the standard model of cosmology to extrapolate the expansion rate. These two [Extracted from the article]

Published

2024

2. The Hubble Tension and Early Dark Energy.

Author

Kamionkowski, Marc and Riess, Adam G.

Abstract

Over the past decade, the disparity between the value of the cosmic expansion rate determined directly from measurements of distance and redshift and that determined instead from the standard Lambda cold dark matter (ΛCDM) cosmological model, calibrated by measurements from the early Universe, has grown to a level of significance requiring a solution. Proposed systematic errors are not supported by the breadth of available data (and unknown errors are untestable by lack of definition). Simple theoretical explanations for this Hubble tension that are consistent with the majority of the data have been surprisingly hard to come by, but in recent years, attention has focused increasingly on models that alter the early or pre-recombination physics of ΛCDM as the most feasible. Here, we describe the nature of this tension and emphasize recent developments on the observational side. We then explain why early-Universe solutions are currently favored and the constraints that any such model must satisfy. We discuss one workable example, early dark energy, and describe how it can be tested with future measurements. Given an assortment of more extended recent reviews on specific aspects of the problem, the discussion is intended to be fairly general and understandable to a broad audience. [ABSTRACT FROM AUTHOR]

Published

2023

3. The Local Value of H0.

Author

Riess, Adam G. and Breuval, Louise

Subjects

*LARGE magellanic cloud, *TYPE I supernovae, *CEPHEIDS, *HUBBLE constant, *ECLIPSING binaries, *SPACE telescopes, *DARK matter, *COSMIC background radiation

Abstract

We review the local determination of the Hubble constant, H0, focusing on recent measurements of a distance ladder constructed from geometry, Cepheid variables and Type Ia supernovae (SNe Ia). We explain in some detail the components of the ladder: (1) geometry from Milky Way parallaxes, masers in NGC 4258 and detached eclipsing binaries in the Large Magellanic Cloud; (2) measurements of Cepheids with the Hubble Space Telescope (HST) in these anchors and in the hosts of 42 SNe Ia; and (3) SNe Ia in the Hubble flow. Great attention to negating systematic uncertainties through the use of differential measurements is reviewed. A wide array of tests are discussed. The measurements provide a strong indication of a discrepancy between the local measure of H0 and its value predicted by Λ Cold Dark Matter theory, calibrated by the cosmic microwave background (Planck), a decade-long challenge known as the 'Hubble Tension'. We present new measurements with the James Webb Space Telescope of >320 Cepheids on both rungs of the distance ladder, in a SN Ia host and the geometric calibrator NGC 4258, showing good agreement with the same as measured with HST. This provides strong evidence that systematic errors in HST Cepheid photometry do not play a significant role in the present Hubble Tension. Future measurements are expected to refine the local determination of the Hubble constant. [ABSTRACT FROM AUTHOR]

Published

2022

4. Measurements of the Hubble Constant with a Two-rung Distance Ladder: Two Out of Three Ain’t Bad.

Author

Kenworthy, W. D’Arcy, Riess, Adam G., Scolnic, Daniel, Yuan, Wenlong, Luis Bernal, José, Brout, Dillon, Casertano, Stefano, Jones, David O., Macri, Lucas, and Peterson, Erik R.

Subjects

*HUBBLE constant, *LARGE magellanic cloud, *TYPE I supernovae, *LARGE scale structure (Astronomy), *MILKY Way

Abstract

The three-rung distance ladder, which calibrates Type Ia supernovae (SNe Ia) through stellar distances linked to geometric measurements, provides the highest precision direct measurement of the Hubble constant. In light of the Hubble tension, it is important to test the individual components of the distance ladder. For this purpose, we report a measurement of the Hubble constant from 35 extragalactic Cepheid hosts measured by the SH0ES team, using their distances and redshifts at cz ≤ 3300 km sâˆ'1, instead of any more distant SNe Ia, to measure the Hubble flow. The Cepheid distances are calibrated geometrically in the Milky Way, NGC 4258, and the Large Magellanic Cloud. Peculiar velocities are a significant source of systematic uncertainty at z ∼ 0.01, and we present a formalism for both mitigating and quantifying their effects, making use of external reconstructions of the density and velocity fields in the nearby universe. We identify a significant source of uncertainty originating from different assumptions about the selection criteria of this sample, whether distance or redshift limited, as it was assembled over three decades. Modeling these assumptions yields central values ranging from H 0 = 71.7 to 76.4 km sâˆ'1 Mpcâˆ'1. Combining the four best-fitting selection models yields H 0 = 72.9 âˆ' 2.2 + 2.4 as a fiducial result, at 2.4 σ tension with Planck. While SNe Ia are essential for a precise measurement of H 0, unknown systematics in these supernovae are unlikely to be the source of the Hubble tension. [ABSTRACT FROM AUTHOR]

Published

2022

5. The Mira Distance to M101 and a 4% Measurement of H 0.

Author

Huang, Caroline D., Yuan, Wenlong, Riess, Adam G., Hack, Warren, Whitelock, Patricia A., Zakamska, Nadia L., Casertano, Stefano, Macri, Lucas M., Marengo, Massimo, Menzies, John W., and Smith, Randall K.

Subjects

*LARGE magellanic cloud, *TYPE I supernovae, *ASYMPTOTIC giant branch stars, *STELLAR luminosity function, *DISTANCES, *RED giants, *LIGHT curves, *SPIRAL galaxies

Abstract

The giant spiral galaxy M101 is host to the nearest recent Type Ia supernova (SN 2011fe) and thus has been extensively monitored in the near-infrared to study the late-time light curve of the SN. Leveraging this existing baseline of observations, we derive the first Mira-based distance to M101 by discovering and classifying a sample of 211 Miras with periods ranging from 240–400 days in the SN field. Combined with new Hubble Space Telescope (HST) WFC3/IR channel observations, our data set totals 11 epochs of F110W (HST YJ) and 13 epochs of F160W (HST H) data spanning ∼2900 days. We adopt absolute calibrations of the Mira period–luminosity relation based on geometric distances to the Large Magellanic Cloud and the water megamaser host galaxy NGC 4258, and find μ M101 = 29.10 ± 0.06 mag. This distance is in 1 σ agreement with most other recent Cepheid and tip of the red giant branch distance measurements to M101. Including the previous Mira SN Ia host, NGC 1559, and SN 2005df, we determine the fiducial SN Ia peak luminosity, M B 0 = − 19.27 ± 0.09 mag. With the Hubble diagram of supernovae Ia, we derive H 0 = 72.37 ± 2.97 km s−1 Mpc−1, a 4.1% measurement of H 0 using Miras. We find excellent agreement with recent Cepheid distance ladder measurements of H 0 and confirm previous indications that the local universe value of H 0 is higher than the early universe value at ∼95% confidence. Currently, the Mira-based H 0 measurement is still dominated by the statistical uncertainty in the SN Ia peak magnitude. [ABSTRACT FROM AUTHOR]

Published

2024

6. A Gaia Data Release 3 View on the Tip of the Red Giant Branch Luminosity.

Author

Li, Siyang, Casertano, Stefano, and Riess, Adam G.

Subjects

*RED giants, *DATA release, *LUMINOSITY, *PARALLAX, *HUBBLE constant, *PHOTOMETRY, *MILKY Way

Abstract

The tip of the red giant branch (TRGB) is a standard candle that can be used to help refine the determination of the Hubble constant. Gaia Data Release 3 (DR3) provides synthetic photometry constructed from low-resolution BP/RP spectra for Milky Way field stars that can be used to directly calibrate the luminosity of the TRGB in the Johnson–Cousins I band, where the TRGB is least sensitive to metallicity. We calibrate the TRGB luminosity using a two-dimensional maximum likelihood algorithm with field stars and Gaia synthetic photometry and parallaxes. For a high-contrast and low-contrast break (characterized by the values of the contrast parameter R or the magnitude of the break β), we find M TRGB I = −4.02 and −3.92 mag respectively, or a midpoint of −3.970 − 0.024 + 0.042 (sys) ± 0.062 (stat) mag. This measurement improves upon the TRGB measurement from Li et al., as the higher precision photometry based on Gaia DR3 allows us to constrain two additional free parameters of the luminosity function. We also investigate the possibility of using Gaia DR3 synthetic photometry to calibrate the TRGB luminosity with ω Centauri, but find evidence of blending within the inner region for cluster member photometry that precludes accurate calibration with Gaia DR3 photometry. We instead provide an updated TRGB measurement of m TRGB I = 9.82 ± 0.04 mag in ω Centauri using ground-based photometry from the most recent version of the database described in Stetson et al., which gives M TRGB I = −3.97 ± 0.04 (stat) ± 0.10 (sys) mag when tied to the Gaia EDR3 parallax distance from the consensus of Vasiliev & Baumgardt, Soltis et al., and Maíz Apellániz. [ABSTRACT FROM AUTHOR]

Published

2023

7. A synthetic Roman Space Telescope High-Latitude Time-Domain Survey: supernovae in the deep field.

Author

Wang, Kevin X, Scolnic, Dan, Troxel, M A, Rodney, Steven A, Popovic, Brodie, Duff, Caleb, Filippenko, Alexei V, Foley, Ryan J, Hounsell, Rebekah, Jha, Saurabh W, Jones, David O, Joshi, Bhavin A, Long, Heyang, Macias, Phillip, Riess, Adam G, Rose, Benjamin M, and Yamamoto, Masaya

Subjects

*SPACE telescopes, *TYPE I supernovae, *SUPERNOVAE, *GRAVITATIONAL lenses, *IMAGE analysis

Abstract

NASA will launch the Nancy Grace Roman Space Telescope (hereafter Roman) in the second half of this decade, which will allow for a generation-defining measurement of dark energy through multiple probes, including Type Ia supernovae (SNe Ia). To improve decisions on survey strategy, we have created the first simulations of realistic Roman images that include artificial SNe Ia injected as point sources in the images. Our analysis combines work done on Roman simulations for weak gravitational lensing studies as well as catalogue-level simulations of SN Ia samples. We have created a time series of images over 2 yr containing ∼1050 SNe Ia, covering a 1 deg2 subarea of a planned 5 deg2 deep survey. We have released these images publicly for community use along with input catalogues of all injected sources. We create secondary products from these images by generating coadded images and demonstrating recovery of transient sources using image subtraction. We perform first-use analyses on these images in order to measure galaxy detection efficiency, point source detection efficiency, and host-galaxy association biases. The simulated images can be found here at https://roman.ipac.caltech.edu/sims/SN_Survey_Image_sim.html. [ABSTRACT FROM AUTHOR]

Published

2023

8. The DEHVILS survey overview and initial data release: high-quality near-infrared Type Ia supernova light curves at low redshift.

Author

Peterson, Erik R, Jones, David O, Scolnic, Daniel, Sánchez, Bruno O, Do, Aaron, Riess, Adam G, Ward, Sam M, Dwomoh, Arianna, de Jaeger, Thomas, Jha, Saurabh W, Mandel, Kaisey S, Pierel, Justin D R, Popovic, Brodie, Rose, Benjamin M, Rubin, David, Shappee, Benjamin J, Thorp, Stephen, Tonry, John L, Tully, R Brent, and Vincenzi, Maria

Subjects

*TYPE I supernovae, *LIGHT curves, *DATA release, *DARK energy, *SCATTER diagrams

Abstract

While the sample of optical Type Ia supernova (SN Ia) light curves (LCs) usable for cosmological parameter measurements surpasses 2000, the sample of published, cosmologically viable near-infrared (NIR) SN Ia LCs, which have been shown to be good 'standard candles,' is still ≲ 200. Here, we present high-quality NIR LCs for 83 SNe Ia ranging from 0.002 < z < 0.09 as a part of the Dark Energy, H0, and peculiar Velocities using Infrared Light from Supernovae (DEHVILS) survey. Observations are taken using UKIRT's WFCAM, where the median depth of the images is 20.7, 20.1, and 19.3 mag (Vega) for Y, J , and H -bands, respectively. The median number of epochs per SN Ia is 18 for all three bands (Y,J , and H) combined and 6 for each band individually. We fit 47 SN Ia LCs that pass strict quality cuts using three LC models, SALT3, snoopy , and B  aye SN and find scatter on the Hubble diagram to be comparable to or better than scatter from optical-only fits in the literature. Fitting NIR-only LCs, we obtain standard deviations ranging from 0.128 to 0.135 mag. Additionally, we present a refined calibration method for transforming 2MASS magnitudes to WFCAM magnitudes using HST CALSPEC stars that results in a 0.03 mag shift in the WFCAM Y -band magnitudes. [ABSTRACT FROM AUTHOR]

Published

2023