One hundred years of the cosmological constant: from “superfluous stunt” to dark energy

O'Raifeartaigh, Cormac; O’Keeffe, Michael; Nahm, W.; Mitton, Simon

doi:10.1140/epjh/e2017-80061-7

Cited by 53 publications

(71 citation statements)

References 218 publications

(282 reference statements)

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“…The Hubble-Lemaître law originally was established for a sample of nearby galaxies, which are members of the Local Group. For them the empirical Hubble-Lemaître law seemed to confirm the FLRW equations, however, later it became clear that not only the galaxies have their peculiar velocities but the Local Group itself is gravitationally bounded to a larger configuration; see [14]. In other words, that law was observed at scales for which it should not be observed.…”

Section: Local and Global Hubble Flows With λmentioning

confidence: 96%

$$H_0$$ tension: clue to common nature of dark sector?

Gurzadyan

Степанян

2019

Eur. Phys. J. C

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The recently sharpened H 0 tension is argued not to be a result of data calibration or any other systematic feature, but an indication for the common nature of dark matter and dark energy. This conclusion is drawn within modified weak-field General Relativity where the accelerated expansion of the Universe and the dynamics of galaxy groups and clusters are described by the same parameter, the cosmological constant. The common nature of the dark sector hence will result in an intrinsic discrepancy/tension between the local and global determinations of the values of the Hubble constant.

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Section: Local and Global Hubble Flows With λmentioning

confidence: 96%

$$H_0$$ tension: clue to common nature of dark sector?

Gurzadyan

Степанян

2019

Eur. Phys. J. C

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“…5 Λ: vacuum, inflation, clusters of galaxies and quasars Despite Einstein's scepticism about the possibility of realisation of cosmological constant in the nature, it continued to live its own life in the minds of physicists and cosmologists. Georges Lemaître, Richard Tolman, Willem de Sitter, Arthur Eddington and other remained its supporters (for more details see [O'Raifeartaigh 2018]). In 1934 G. Lemaître has suggested that since the energy associated with it is Lorentz invariant, then the cosmological constant is the vacuum energy density [Lemaître 1934].…”

Section: Einstein's Denial Of λmentioning

confidence: 99%

“…In this paper, devoted to the century of cosmological constant, we briefly review the motivation of its including in general relativity, using it for interpretation of the cosmological observations and the unsuccessful attempts to give it some fundamental meaning. The comprehensive historical review of the story of the cosmological constant one can find in the recent papers [O'Raifeartaigh 2017, O'Raifeartaigh 2018 as well as the complete list of publications devoted to it. a e-mail: bnovos@gmail.com 2 "Cosmological Considerations on the General Theory of Relativity"…”

Section: Introductionmentioning

confidence: 99%

Century of Λ

Novosyadlyj¹

2018

EPJ H

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The cosmological constant was proposed 100 years ago in order to make the model of static Universe, imagined then by most scientists, possible. Today it is the main candidate for the physical essence causing the observed accelerated expansion of our Universe. But, as well as a hundred years ago, its nature is unknown. This paper is devoted to the story of invention of Λ by Albert Einstein in 1917, rejection of it by him in 1931 and returning of it into the great science by other scientists during the century. The aim is to once again emphasize prominent role of cosmological constant in the development of ideas of modern physics and cosmology, focusing on the main points and publications, the choice of which may have a certain part of subjectivity.

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“…The well-known Weinberg review of 1989 [12] referenced about one hundred papers dealing with the problem of the cosmological constant. After the discovery of the acceleration of the expansion of the Universe, many thousands of articles were published [14]. However the vacuum fluctuations may not contribute to the cosmological constant [15].…”

Section: Bouncing Cosmology and The Cosmological Constant Problemmentioning

confidence: 99%

A Possible Solution for the Cosmological Constant Problem

Gorkavyi¹,

Vasilkov²,

Mather³

2018

Proceedings of 2nd World Summit: Exploring the Dark Side of the Universe — PoS(EDSU2018)

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The mysterious acceleration of the expansion of the Universe, discovered in 1998, can be described by the cosmological constant introduced by Einstein in 1917. In the quantum cosmology, the existence of a repulsive force is associated with "dark energy"-a hypothetical substance with a negative pressure. But numerous attempts to obtain from the quantum theory the observed value of the cosmological constant lead to values of 120 orders of magnitude larger than the observed value. In the bouncing cosmology, a collapse of the Universe of the previous cycle is supposed, and then its new divergence. We consider the bouncing cosmology in the light of the latest discovery of gravitational waves and a large number of massive black holes, which are a probable candidate for the role of dark matter. When the Universe collapses, a significant part of the gravitational mass of the merging black holes turns into gravitational waves. During mergers, the size of black holes increases. We call the largest of them the Big Black Hole (BBH). In the stage of expansion, the frequency of mergers of black holes will decrease sharply and the reverse process will begin due to the absorption of gravitational waves: the slow growth of the mass of black holes, first of all the BBH, which has the maximum surface. If we assume that gravitational radiation themselves do not generate a gravitational field, then it can be shown that a sharp decrease in the gravitational mass of the Universe causes strong antigravity, which can be responsible for the Big Bang. The gravitational mass of BBH at the stage of expansion of the Universe will grow and the gravitational influence of BBH will stretch a field of galaxies. This stretching effect is described by the appearance of a cosmological constant in the Friedmann equations. An estimated value of the cosmological constant is in good agreement with the observations. A cyclic model of the Universe can be developed on the basis of periodic transformation of the mass of merging black holes into gravitational waves and absorption of the background gravitational radiation by the BBH.

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One hundred years of the cosmological constant: from “superfluous stunt” to dark energy

Cited by 53 publications

References 218 publications

$$H_0$$ tension: clue to common nature of dark sector?

$$H_0$$ tension: clue to common nature of dark sector?

Century of Λ

A Possible Solution for the Cosmological Constant Problem

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