Astronomy:Fuzzy cold dark matter
Fuzzy cold dark matter is a hypothetical form of cold dark matter proposed to solve the cuspy halo problem. It would consist of extremely light scalar particles with masses on the order of eV; so a Compton wavelength on the order of 1 light year. Fuzzy cold dark matter halos in dwarf galaxies would manifest wave behavior on astrophysical scales, and the cusps would be avoided through the Heisenberg uncertainty principle.[1] The wave behavior leads to interference patterns, spherical soliton cores in dark matter halo centers,[2] and cylindrical soliton-like cores in dark matter cosmic web filaments.[3]
Fuzzy cold dark matter is a limit of scalar field dark matter without self-interaction.[4][5] Fuzzy cold dark matter is sometimes called wave DM, or simply fuzzy dark matter (FDM).[6] It is governed by the Schrödinger–Poisson equation.
Fuzzy dark matter models are the simplest class of the ultralight dark matter models; the only free parameter is the particle mass. (In "ultralight dark matter models", the dark matter of a galaxy condenses into a superfluid. This requirement greatly constrains the particle mass; for example, the QCD (Peccei–Quinn) axion is considered too heavy to condense.) A second approach, where FDM is modified to have simple self-interaction, has been suggested with theories such as self-interacting fuzzy dark matter (SIFDM), repulsive DM, scalar field DM, and fluid dark matter. A third approach, called the "DM superfluid model", focuses on the empirical data for a large-scale MOND relation, and then works backwards to determine what types of complicated self-interactions would best produce such a distribution.[6]
New research (2023) has uncovered evidence that fuzzy dark matter, specifically ultralight axions, may better fit gravitational lens data than WIMP dark matter.[7]
Notes
- ↑ Hu, Wayne; Barkana, Rennan; Gruzinov, Andrei (2000). "Cold and Fuzzy Dark Matter". Physical Review Letters 85 (6): 1158–61. doi:10.1103/PhysRevLett.85.1158. PMID 10991501. Bibcode: 2000PhRvL..85.1158H.
- ↑ Schive, Hsi-Yu; Chiueh, Tzihong; Broadhurst, Tom (2014). "Cosmic structure as the quantum interference of a coherent dark wave". Nature Physics 10 (7): 496–499. doi:10.1038/nphys2996. Bibcode: 2014NatPh..10..496S.
- ↑ Mocz, Philip; Fialkov, Anastasia; Vogelsberger, Mark; Becerra, Fernando; Amin, Mustafa A.; Bose, Sownak; Boylan-Kolchin, Michael; Chavanis, Pierre-Henri et al. (2019). "First Star-Forming Structures in Fuzzy Cosmic Filaments". Physical Review Letters 123 (14). doi:10.1103/PhysRevLett.123.141301. ISSN 0031-9007. PMID 31702225. Bibcode: 2019PhRvL.123n1301M.
- ↑ Bohua Li; Tanja Rindler-Daller; Paul R. Shapiro (2014). "Cosmological Constraints on Bose-Einstein-Condensed Scalar Field Dark Matter". Phys. Rev. D 89 (8). doi:10.1103/PhysRevD.89.083536. Bibcode: 2014PhRvD..89h3536L.
- ↑ Lee, Jae-Weon (2018). "Brief History of Ultra-light Scalar Dark Matter Models". EPJ Web of Conferences 168: 06005. doi:10.1051/epjconf/201816806005. Bibcode: 2018EPJWC.16806005L.
- ↑ 6.0 6.1 Ferreira, Elisa G. M. (December 2021). "Ultra-light dark matter". The Astronomy and Astrophysics Review 29 (1): 7. doi:10.1007/s00159-021-00135-6. Bibcode: 2021A&ARv..29....7F.
- ↑ Timmer, John (2023-04-21). "No WIMPS! Heavy particles don't explain gravitational lensing oddities". https://arstechnica.com/science/2023/04/gravitational-lensing-may-point-to-lighter-dark-matter-candidate/.
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