Shedding Light On An Undiscovered Aspect That Perfectly Mimics Cosmic Acceleration

Mapping Intimacies ◽

10.21203/rs.3.rs-812452/v2 ◽

2022 ◽

Author(s):

Karan R. Takkhi

Keyword(s):

Gamma Ray ◽

Hubble Space Telescope ◽

High Redshift ◽

Cosmic Acceleration ◽

Expansion Rate ◽

Type Ia Supernovae ◽

Time Relationship ◽

Type Ia ◽

Ia Supernovae ◽

Distance Relationship

Abstract The comparison of redshift-distance relationship for high and low-redshift supernovae revealed the surprising transition of the Universe’s expansion from deceleration to acceleration. As compared to local supernovae, remote supernovae appear 10% to 25% dimmer as they are further away than expected. The expansion rate obtained for local supernovae is higher with low redshifts as compared to the expansion rate obtained for remote supernovae with high redshifts. Since observed redshifts in an expanding Universe provide an estimate of recession velocities, therefore, it is very disturbing to find that low recession velocities (just 1% of speed of light) indicate a faster rate of expansion (acceleration), whereas high recession velocities (60% of speed of light) indicate a slower rate of expansion (deceleration). In this paper, I unravel an undiscovered aspect that perfectly mimics cosmic acceleration. Rather than “cosmic deceleration that preceded the current epoch of cosmic acceleration”, I show in this paper, that “consecutive expansion epochs of the Universe that preceded the current epoch of cosmic expansion” were responsible for placing remote supernovae further away than expected. As a consequence of consecutive expansion, expansion began for remote structures in preceding expansion epochs before it did for local structures in the current (or more recent) expansion epoch; remote supernovae, quasars, and gamma-ray bursts are therefore not only further away than expected, but they also happen to yield a slower rate of expansion, thereby suggesting their deceleration even with “superluminal expansion”. As a result of consecutive expansion, preceding expansion epochs appear to be decelerating as compared to the expansion epoch that succeeds them. The analysis is based on the redshift-distance relationship plotted for 580 type Ia supernovae from the Supernova Cosmology Project, 7 additional high-redshift type Ia supernovae discovered through the Advanced Camera for Surveys on the Hubble Space Telescope from the Great Observatories Origins Deep Survey Treasury program, and 1 additional very high-redshift type Ia supernova discovered with Wide Field and Planetary Camera 2 on the Hubble Space Telescope. The results obtained by the High-Z Supernova Search Team through observations of type Ia supernovae have also been analysed. Studies incorporating quasars and gamma-ray bursts to determine how the expansion of the Universe has changed over time have been taken into consideration as well. The results obtained in this paper have been confirmed by plotting velocity-distance relationship, expansion rate vs. time relationship, expansion factor vs. time relationship, scale factor vs. time relationship, scale factor vs. distance relationship, distance-redshift relationship, and distance modulus vs. redshift relationship, moreover, the deceleration parameter (q0) is also found to be negative (q0 < 0).

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Model-independent cosmic acceleration and redshift-dependent intrinsic luminosity in type-Ia supernovae

Astronomy and Astrophysics ◽

10.1051/0004-6361/201833032 ◽

2019 ◽

Vol 625 ◽

pp. A15 ◽

Cited By ~ 8

Author(s):

I. Tutusaus ◽

B. Lamine ◽

A. Blanchard

Keyword(s):

Spline Interpolation ◽

High Redshift ◽

Cosmic Acceleration ◽

Expansion Rate ◽

Type Ia Supernovae ◽

Type Ia ◽

Model Independent ◽

Ia Supernovae ◽

The Universe ◽

Intrinsic Luminosity

Context. The cosmological concordance model (ΛCDM) is the current standard model in cosmology thanks to its ability to reproduce the observations. The first observational evidence for this model appeared roughly 20 years ago from the type-Ia supernovae (SNIa) Hubble diagram from two different groups. However, there has been some debate in the literature concerning the statistical treatment of SNIa, and their stature as proof of cosmic acceleration. Aims. In this paper we relax the standard assumption that SNIa intrinsic luminosity is independent of redshift, and examine whether it may have an impact on our cosmological knowledge and more precisely on the accelerated nature of the expansion of the universe. Methods. To maximise the scope of this study, we do not specify a given cosmological model, but we reconstruct the expansion rate of the universe through a cubic spline interpolation fitting the observations of the different cosmological probes: SNIa, baryon acoustic oscillations (BAO), and the high-redshift information from the cosmic microwave background (CMB). Results. We show that when SNIa intrinsic luminosity is not allowed to vary as a function of redshift, cosmic acceleration is definitely proven in a model-independent approach. However, allowing for redshift dependence, a nonaccelerated reconstruction of the expansion rate is able to fit, at the same level of ΛCDM, the combination of SNIa and BAO data, both treating the BAO standard ruler rd as a free parameter (not entering on the physics governing the BAO), and adding the recently published prior from CMB observations. We further extend the analysis by including the CMB data. In this case we also consider a third way to combine the different probes by explicitly computing rd from the physics of the early universe, and we show that a nonaccelerated reconstruction is able to nicely fit this combination of low- and high-redshift data. We also check that this reconstruction is compatible with the latest measurements of the growth rate of matter perturbations. We finally show that the value of the Hubble constant (H0) predicted by this reconstruction is in tension with model-independent measurements. Conclusions. We present a model-independent reconstruction of a nonaccelerated expansion rate of the universe that is able to fit all the main background cosmological probes nicely. However, the predicted value of H0 is in tension with recent direct measurements. Our analysis points out that a final reliable and consensual value for H0 is critical to definitively prove cosmic acceleration in a model-independent way.

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Exploring the potentiality of standard sirens to probe cosmic opacity at high redshifts

The European Physical Journal C ◽

10.1140/epjc/s10052-020-08479-6 ◽

2020 ◽

Vol 80 (9) ◽

Author(s):

Xiangyun Fu ◽

Jianfei Yang ◽

Zhaoxia Chen ◽

Lu Zhou ◽

Jun Chen

Keyword(s):

Gamma Ray ◽

High Redshift ◽

Gamma Ray Bursts ◽

Type Ia Supernovae ◽

Luminosity Distance ◽

Spatial Homogeneity ◽

Einstein Telescope ◽

The Future ◽

Type Ia ◽

Ia Supernovae

AbstractIn this work, using the Gaussian process, we explore the potentiality of future gravitational wave (GW) measurements to probe cosmic opacity at high redshifts through comparing its opacity-free luminosity distance (LD) with the opacity-dependent one from the combination of Type Ia supernovae (SNIa) and gamma-ray bursts (GRBs). The GW data, SNIa and GRB data are simulated from the measurements of the future Einstein Telescope, the actual Pantheon compilation and the latest observation of GRBs compiled by Amati et al, respectively. A nonparametric method is proposed to probe the spatial homogeneity of cosmic transparency at high redshift by comparing the LD reconstructed from the GW data with that reconstructed from the Pantheon and GRB data. In addition, the cosmic opacity is tested by using the parametrization for the optical depth, and the results show that the constraints on cosmic opacity are more stringent than the previous ones. It shows that the future GW measurements may be used as an important tool to probe the cosmic opacity in the high redshift region.

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ACCELERATING COMPACT OBJECT MERGERS IN TRIPLE SYSTEMS WITH THE KOZAI RESONANCE: A MECHANISM FOR “PROMPT” TYPE Ia SUPERNOVAE, GAMMA-RAY BURSTS, AND OTHER EXOTICA

The Astrophysical Journal ◽

10.1088/0004-637x/741/2/82 ◽

2011 ◽

Vol 741 (2) ◽

pp. 82 ◽

Cited By ~ 177

Author(s):

Todd A. Thompson

Keyword(s):

Gamma Ray ◽

Compact Object ◽

Gamma Ray Bursts ◽

Type Ia Supernovae ◽

Triple Systems ◽

Type Ia ◽

Ia Supernovae ◽

Kozai Resonance

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Spectra of High-Redshift Type Ia Supernovae and a Comparison with Their Low-Redshift Counterparts

The Astronomical Journal ◽

10.1086/497635 ◽

2005 ◽

Vol 130 (6) ◽

pp. 2788-2803 ◽

Cited By ~ 44

Author(s):

I. M. Hook ◽

D. A. Howell ◽

G. Aldering ◽

R. Amanullah ◽

M. S. Burns ◽

...

Keyword(s):

High Redshift ◽

Type Ia Supernovae ◽

Type Ia ◽

Ia Supernovae

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Luminosity–duration relations and luminosity functions of repeating and non-repeating fast radio bursts

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa895 ◽

2020 ◽

Vol 494 (2) ◽

pp. 2886-2904 ◽

Cited By ~ 4

Author(s):

Tetsuya Hashimoto ◽

Tomotsugu Goto ◽

Ting-Wen Wang ◽

Seong Jin Kim ◽

Simon C-C Ho ◽

...

Keyword(s):

Neutron Star ◽

Time Scale ◽

Gamma Ray ◽

Clear Correlation ◽

Type Ia Supernovae ◽

Radio Bursts ◽

Luminosity Functions ◽

Type Ia ◽

Ia Supernovae ◽

Two Populations

ABSTRACT Fast radio bursts (FRBs) are mysterious radio bursts with a time-scale of approximately milliseconds. Two populations of FRB, namely repeating and non-repeating FRBs, are observationally identified. However, the differences between these two and their origins are still cloaked in mystery. Here we show the time-integrated luminosity–duration (Lν–wint, rest) relations and luminosity functions (LFs) of repeating and non-repeating FRBs in the FRB Catalogue project. These two populations are obviously separated in the Lν-wint, rest plane with distinct LFs, i.e. repeating FRBs have relatively fainter Lν and longer wint, rest with a much lower LF. In contrast with non-repeating FRBs, repeating FRBs do not show any clear correlation between Lν and wint, rest. These results suggest essentially different physical origins of the two. The faint ends of the LFs of repeating and non-repeating FRBs are higher than volumetric occurrence rates of neutron star (NS) mergers and accretion-induced collapse (AIC) of white dwarfs (WDs), and are consistent with those of soft gamma-ray repeaters (SGRs), Type Ia supernovae (SNe Ia), magnetars, and WD mergers. This indicates two possibilities: either (i) faint non-repeating FRBs originate in NS mergers or AIC and are actually repeating during the lifetime of the progenitor, or (ii) faint non-repeating FRBs originate in any of SGRs, SNe Ia, magnetars, and WD mergers. The bright ends of LFs of repeating and non-repeating FRBs are lower than any candidates of progenitors, suggesting that bright FRBs are produced from a very small fraction of the progenitors regardless of the repetition. Otherwise, they might originate in unknown progenitors.

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