A closer look at the spur, blob, wiggle, and gaps in GD-1

Boer, T. J. L. de; Erkal, Denis; Gieles, M.

doi:10.1093/mnras/staa917

Cited by 47 publications

(42 citation statements)

References 83 publications

(113 reference statements)

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“…Gaps of scales of approximately 10 • were found in this stream using SDSS and these were associated with the encounter with sub-halos by Carlberg (2016). This was confirmed by Banik et al (2021) analyzing the stellar density perturbations from accurate measurements of the morphology (de Boer et al 2020) of this streams using Gaia data combined with photometry from Pan-STARRS (Chambers et al 2016). They found that the data indicates that these perturbations should come from sub-halos, and that their abundance and masses are compatible with the expected from CDM from simulations.…”

Section: Stellar Streamsmentioning

confidence: 64%

Ultra-light dark matter

Ferreira

2021

Astron Astrophys Rev

238

126

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Ultra-light dark matter is a class of dark matter models (DM), where DM is composed by bosons with masses ranging from $$10^{-24}\, \mathrm {eV}< m < \mathrm {eV}$$ 10 - 24 eV < m < eV . These models have been receiving a lot of attention in the past few years given their interesting property of forming a Bose–Einstein condensate (BEC) or a superfluid on galactic scales. BEC and superfluidity are some of the most striking quantum mechanical phenomena that manifest on macroscopic scales, and upon condensation, the particles behave as a single coherent state, described by the wavefunction of the condensate. The idea is that condensation takes place inside galaxies while outside, on large scales, it recovers the successes of $$\varLambda $$ Λ CDM. This wave nature of DM on galactic scales that arise upon condensation can address some of the curiosities of the behaviour of DM on small-scales. There are many models in the literature that describe a DM component that condenses in galaxies. In this review, we are going to describe those models, and classify them into three classes, according to the different non-linear evolution and structures they form in galaxies: the fuzzy dark matter (FDM), the self-interacting fuzzy dark matter (SIFDM), and the DM superfluid. Each of these classes comprises many models, each presenting a similar phenomenology in galaxies. They also include some microscopic models like the axions and axion-like particles. To understand and describe this phenomenology in galaxies, we are going to review the phenomena of BEC and superfluidity that arise in condensed matter physics, and apply this knowledge to DM. We describe how ULDM can potentially reconcile the cold DM picture with the small-scale behaviour. These models present a rich phenomenology that is manifest in different astrophysical consequences. We review here the astrophysical and cosmological tests used to constrain those models, together with new and future observations that promise to test these models in different regimes. For the case of the FDM class, the mass where this model has an interesting phenomenology on small-scales $$ \sim 10^{-22}\, \mathrm {eV}$$ ∼ 10 - 22 eV , is strongly challenged by current observations. The parameter space for the other two classes remains weakly constrained. We finalize by showing some predictions that are a consequence of the wave nature of this component, like the creation of vortices and interference patterns, that could represent a smoking gun in the search of these rich and interesting alternative class of DM models.

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Section: Stellar Streamsmentioning

confidence: 64%

Ultra-light dark matter

Ferreira

2021

Astron Astrophys Rev

238

126

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“…The morphology of the gap and the spur observed in the GD-1 stream can be reproduced by numerical models of the stream interacting with a massive object in the Milky Way halo (Bonaca et al 2019;de Boer et al 2020), and the interaction might have elevated the stream's velocity dispersion. However, similarly high values of velocity dispersion were measured in the Palomar 5 tidal tails (σ = 2.1 ± 0.4 km s −1 , Kuzma et al 2015) and the ATLAS-Aliqa Uma complex (σ = 4.8 ± 0.4 km s −1 , Li et al 2020).…”

Section: Summary and Discussionmentioning

confidence: 91%

Velocity Dispersion of the GD-1 Stellar Stream

Gialluca,

Naidu,

Bonaca

2020

Preprint

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Tidally dissolved globular clusters form thin stellar streams that preserve a historical record of their past evolution. We report a radial velocity dispersion of 2.3 ± 0.3 km s −1 in the GD-1 stellar stream using a sample of 43 spectroscopically confirmed members. The GD-1 velocity dispersion is constant over the surveyed ≈ 15 • span of the stream. We also measured velocity dispersion in the spur adjacent to the main GD-1 stream, and found a similar value at the tip of the spur. Surprisingly, the region of the spur closer to the stream appears dynamically colder than the main stream. An unperturbed model of the GD-1 stream has a velocity dispersion of ≈ 0.6 km s −1 , indicating that GD-1 has undergone dynamical heating. Stellar streams arising from globular clusters, which prior to their arrival in the Milky Way, orbited a dwarf galaxy with a cored density profile are expected to have experienced the amount of heating required to match the velocity dispersion observed in GD-1. This suggests that GD-1 has been accreted and that imprints of its original host galaxy, including the inner slope of its dark-matter halo, remain observable in the stream today.

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“…To date, there is about a dozen of known cold streams in the inner regions of the Galaxy (Malhan et al 2018;Ibata et al 2019). Among those, the best studied correspond to the stream associated with the globular cluster Palomar 5 (Odenkirchen et al 2003), and GD-1 (Grillmair & Dionatos 2006), whose progenitor remains undetected to date, likely because it was completely disrupted (Malhan & Ibata 2019;de Boer et al 2020). Bearing in mind the limitations discussed in §4.1, it interesting to estimate the number of ultra-wide binaries that can potentially form in those systems.…”

Section: Ultra-wide Binaries In Cold Tidal Streamsmentioning

confidence: 99%

Creation/destruction of ultra-wide binaries in tidal streams

Peñarrubia

2020

Monthly Notices of the Royal Astronomical Society

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This paper uses statistical and N-body methods to explore a new mechanism to form binary stars with extremely large separations (≳ 0.1 pc), whose origin is poorly understood. Here, ultra-wide binaries arise via chance entrapment of unrelated stars in tidal streams of disrupting clusters. It is shown that (i) the formation of ultra-wide binaries is not limited to the lifetime of a cluster, but continues after the progenitor is fully disrupted, (ii) the formation rate is proportional to the local phase-space density of the tidal tails, (iii) the semimajor axis distribution scales as p(a)da ∼ a1/2da at a ≪ D, where D is the mean interstellar distance, and (vi) the eccentricity distribution is close to thermal, p(e)de = 2ede. Owing to their low binding energies, ultra-wide binaries can be disrupted by both the smooth tidal field and passing substructures. The time-scale on which tidal fluctuations dominate over the mean field is inversely proportional to the local density of compact substructures. Monte-Carlo experiments show that binaries subject to tidal evaporation follow p(a)da ∼ a−1da at a ≳ apeak, known as Öpik’s law, with a peak semi-major axis that contracts with time as apeak ∼ t−3/4. In contrast, a smooth Galactic potential introduces a sharp truncation at the tidal radius, p(a) ∼ 0 at a ≳ rt. The scaling relations of young clusters suggest that most ultra-wide binaries arise from the disruption of low-mass systems. Streams of globular clusters may be the birthplace of hundreds of ultra-wide binaries, making them ideal laboratories to probe clumpiness in the Galactic halo.

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A closer look at the spur, blob, wiggle, and gaps in GD-1

Cited by 47 publications

References 83 publications

Ultra-light dark matter

Ultra-light dark matter

Velocity Dispersion of the GD-1 Stellar Stream

Creation/destruction of ultra-wide binaries in tidal streams

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