Galaxy formation with BECDM – II. Cosmic filaments and first galaxies

Mocz, Philip; Fialkov, Anastasia; Vogelsberger, Mark; Becerra, Fernando; Shen, Xuejian; Robles, Victor H.; Amin, Mustafa A.; Zavala, Jesús; Boylan-Kolchin, Michael; Bose, Sownak; Marinacci, Federico; Chavanis, Pierre‐Henri; Lancaster, Lachlan; Hernquist, Lars

doi:10.1093/mnras/staa738

Cited by 79 publications

(97 citation statements)

References 108 publications

(136 reference statements)

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“…The leading-order result in our EFT is consistent with the Schrödinger-Poisson (SP) system in an expanding universe, which is widely used in the literature [8]. For example, the SP system has enabled long-time-scale simulations of nonlinear structure formation of axion-like fields [14,31,32]. It has also been used to understand the cosmological formation, gravitational clustering, and scattering of solitons with strong self-interactions in the early and contemporary universe [16].…”

Section: Jhep09(2021)050supporting

confidence: 68%

Beyond Schrödinger-Poisson: nonrelativistic effective field theory for scalar dark matter

Salehian

Zhang

Amin

et al. 2021

J. High Energ. Phys.

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Massive scalar fields provide excellent dark matter candidates, whose dynamics are often explored analytically and numerically using nonrelativistic Schrödinger-Poisson (SP) equations in a cosmological context. In this paper, starting from the nonlinear and fully relativistic Klein-Gordon-Einstein (KGE) equations in an expanding universe, we provide a systematic framework for deriving the SP equations, as well as relativistic corrections to them, by integrating out ‘fast modes’ and including nonlinear metric and matter contributions. We provide explicit equations for the leading-order relativistic corrections, which provide insight into deviations from the SP equations as the system approaches the relativistic regime. Upon including the leading-order corrections, our equations are applicable beyond the domain of validity of the SP system, and are simpler to use than the full KGE case in some contexts. As a concrete application, we calculate the mass-radius relationship of solitons in scalar dark matter and accurately capture the deviations of this relationship from the SP system towards the KGE one.

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Section: Jhep09(2021)050supporting

confidence: 68%

Beyond Schrödinger-Poisson: nonrelativistic effective field theory for scalar dark matter

Salehian

Zhang

Amin

et al. 2021

J. High Energ. Phys.

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show abstract

“…(3) has only recently been investigated by direct numerical simulation in the cosmological setting [28] and appears to contain features of both the focusing and the defocusing nonlinear Schrödinger equation. As mentioned above, at large scales the Schrödinger-Newton model exhibits gravitationally driven accretion into filaments which then become unstable and collapse into spherical haloes [29,30] (cf. collapses in the focusing nonlinear Schrödinger model driven by the self-focusing local contact potential).…”

Section: Turbulence In the Nonlinear Schrödinger And Schrödinger-newton Equationsmentioning

confidence: 97%

“…At large scales the two models become indistinguishable [18]. Thus, until the precise nature of dark matter particles is identified, fuzzy dark matter must be considered alongside cold dark matter when investigating the formation of large-scale structure in the early universe [18,[28][29][30].…”

Section: Small-scale Limit: the Schrödinger-newton Equationsmentioning

confidence: 99%

Wave turbulence in self-gravitating Bose gases and nonlocal nonlinear optics

2020

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We develop the theory of weak wave turbulence in systems described by the Schrödinger-Helmholtz equations in two and three dimensions. This model contains as limits both the familiar cubic nonlinear Schrödinger equation, and the Schrödinger-Newton equations. The latter, in three dimensions, are a nonrelativistic model of fuzzy dark matter which has a nonlocal gravitational self-potential, and in two dimensions they describe nonlocal nonlinear optics in the paraxial approximation. We show that in the weakly nonlinear limit the Schrödinger-Helmholtz equations have a simultaneous inverse cascade of particles and a forward cascade of energy. The inverse cascade we interpret as a nonequilibrium condensation process, which is a precursor to structure formation at large scales (for example the formation of galactic dark matter haloes or optical solitons). We show that for the Schrödinger-Newton equations in two and three dimensions, and in the two-dimensional nonlinear Schrödinger equation, the particle and energy fluxes are carried by small deviations from thermodynamic distributions, rather than the Kolmogorov-Zakharov cascades that are familiar in wave turbulence. We develop a differential approximation model to characterize such "warm cascade" states.

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“…Apart from the core-envelope structure of halos, some FDM simulations find large-scale coherence effects around and between halos (Schive et al, 2014a), (Mocz et al, 2017), extending all the way to cosmic filaments (Mocz et al, 2020), as well as finding signs of quantum turbulence within halo envelopes (Mocz et al, 2017). Unfortunately, current simulations cannot resolve the DM substructure expected in FDM and BEC-DM, in general.…”

Section: Dynamics Characteristic Scales and Halos At Largementioning

confidence: 81%

To Observe, or Not to Observe, Quantum-Coherent Dark Matter in the Milky Way, That is a Question

Rindler-Daller

2021

Front. Astron. Space Sci.

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In recent years, Bose-Einstein-condensed dark matter (BEC-DM) has become a popular alternative to standard, collisionless cold dark matter (CDM). This BEC-DM -also called scalar field dark matter (SFDM)- can suppress structure formation and thereby resolve the small-scale crisis of CDM for a range of boson masses. However, these same boson masses also entail implications for BEC-DM substructure within galaxies, especially within our own Milky Way. Observational signature effects of BEC-DM substructure depend upon its unique quantum-mechanical features and have the potential to reveal its presence. Ongoing efforts to determine the dark matter substructure in our Milky Way will continue and expand considerably over the next years. In this contribution, we will discuss some of the existing constraints and potentially new ones with respect to the impact of BEC-DM onto baryonic tracers. Studying dark matter substructure in our Milky Way will soon resolve the question, whether dark matter behaves classical or quantum on scales of ≲ 1 kpc.

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Galaxy formation with BECDM – II. Cosmic filaments and first galaxies

Cited by 79 publications

References 108 publications

Beyond Schrödinger-Poisson: nonrelativistic effective field theory for scalar dark matter

Beyond Schrödinger-Poisson: nonrelativistic effective field theory for scalar dark matter

Wave turbulence in self-gravitating Bose gases and nonlocal nonlinear optics

To Observe, or Not to Observe, Quantum-Coherent Dark Matter in the Milky Way, That is a Question

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