The Star Formation History and Dynamics of the Ultra-diffuse Galaxy Dragonfly 44 in MOND and MOG

2020

A&A

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The galaxy-wide stellar initial mass function (gwIMF) of a galaxy in dependence on its metallicity and star formation rate can be calculated by the integrated galactic IMF (IGIMF) theory. This theory has been applied in a study of the chemical evolution of the ultra-faint dwarf (UFD) satellite galaxies, but failed to reproduce the data. Here, we find that the IGIMF theory is naturally consistent with the data. We applied the time-evolving gwIMF, which was calculated at each time step. The number of type Ia supernova explosions that forms per unit stellar mass was renormalised according to the gwIMF. The chemical evolution of Boötes I, one of the best-observed UFD, was calculated. Our calculation suggests a mildly bottom-light and top-light gwIMF for Boötes I, and that this UFD has the same gas-consumption timescale as other dwarfs, but was quenched about 0.1 Gyr after formation. This is consistent with independent estimations, and it is similar to Dragonfly 44. The recovered best-fitting input parameters in this work are not covered in previous work, creating a discrepancy between our conclusions. In addition, a detailed discussion of the uncertainties is presented to address the dependence of the chemical evolution model results on the applied assumptions. This study demonstrates the power of the IGIMF theory in understanding star formation in extreme environments and shows that UDFs are a promising pathway to constrain the variation of the low-mass stellar IMF.

Section: Star Formation Historymentioning

confidence: 64%

Section: Resultsmentioning

confidence: 94%

Chemical evolution of ultra-faint dwarf galaxies in the self-consistently calculated integrated galactic IMF theory

Yan

Jeřabková

2020

A&A

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“…MOG is a covariant scalar-tensor-vector gravity theory which allows the gravitational constant G, a vector field coupling ω, and the vector field mass µ to vary with space and time. This model was recently ruled out at 5.49σ using the velocity dispersion profile of the ultra-diffuse galaxy Dragonfly 44 (Haghi et al 2019). While perhaps the basic ideas of MOG can still be saved by applying some corrections or modifications, its current formulation seems to be in conflict with observations.…”

Section: A Lower Massmentioning

confidence: 99%

A massive blow for ΛCDM – the high redshift, mass, and collision velocity of the interacting galaxy cluster El Gordo contradicts concordance cosmology

Asencio

Banik

Monthly Notices of the Royal Astronomical Society

2020

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El Gordo (ACT-CL J0102-4915) is an extremely massive galaxy cluster (M200 ≈ 3 × 1015 M⊙) at redshift z = 0.87 composed of two subclusters with mass ratio 3.6 merging at speed Vinfall ≈ 2500 km/s. Such a fast collision between individually rare massive clusters is unexpected in ΛCDM cosmology at such high z. However, this is required for non-cosmological hydrodynamical simulations of the merger to match its observed properties (Zhang et al. 2015). Here, we determine the probability of finding a similar object in a ΛCDM context using the Jubilee simulation box with side length 6 h−1 Gpc. We search for galaxy cluster pairs that have turned around from the cosmic expansion with properties similar to El Gordo in terms of total mass, mass ratio, redshift, and collision velocity relative to virial velocity. We fit the distribution of pair total mass quite accurately, with the fits used in two methods to infer the probability of observing El Gordo in the surveyed region. The more conservative (and detailed) method involves considering the expected distribution of pairwise mass and redshift for analogue pairs with similar dimensionless parameters to El Gordo in the past lightcone of a z = 0 observer. Detecting one pair with its mass and redshift rules out ΛCDM cosmology at 6.16σ. We also use the results of Kraljic & Sarkar (2015) to show that the Bullet Cluster is in 2.78σ tension once the sky coverage of its discovery survey is accounted for. Using a χ2 approach, the combined tension can be estimated as 6.43σ. Both collisions arise naturally in a MOND cosmology with light sterile neutrinos.

“…However, including the Galactic external field did not much improve the agreement with observations (Derakhshani & Haghi 2014). MOND can also explain the velocity dispersion of the ultra-diffuse galaxy Dragonfly 2 (DF2, Kroupa et al 2018b), DF4 (Haghi et al 2019a), and DF44 (Bílek et al 2019), with the latter galaxy having a measured dispersion profile that is consistent with MOND at 2.40σ (Haghi et al 2019b). The calculations for DF2 and DF4 are significantly affected by the EFE.…”

Section: Introductionmentioning

confidence: 69%

Scale-invariant dynamics in the Solar system

Banik

Monthly Notices of the Royal Astronomical Society: Letters

2020

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ABSTRACT The covariant scale-invariant dynamics (SID) theory has recently been proposed as a possible explanation for the observed dynamical discrepancies in galaxies. SID implies that these discrepancies – commonly attributed to dark matter – arise instead from a non-standard velocity-dependent force that causes two-body near-Keplerian orbits to expand. We show that the predicted expansion of the Earth–Moon orbit is incompatible with lunar laser ranging data at >200σ. Moreover, SID predicts that the gravitating mass of any object was much smaller in the past. If true, a low-mass red giant star must be significantly older than in standard theory. This would make it much older than the conventional age of the Universe, which, however, is expected to be similarly old in SID. Moreover, it is not completely clear whether SID truly contains new physics beyond general relativity, with several previous works arguing that the extra degree of freedom is purely mathematical. We conclude that the SID model is falsified at high significance by observations across a range of scales, even if it is theoretically well formulated.