The distribution of dark matter in galaxies (original) (raw)
Adams JJ, Simon JD, Fabricius MH et al (2014) Dwarf galaxy dark matter density profiles inferred from stellar and gas kinematics. ApJ 789:63 ADS Google Scholar
Adhikari R, Agostini M, Ky NA et al (2017) A white paper on keV sterile neutrino dark matter. JCAP 1:025 ADS Google Scholar
Alabi AB, Forbes DA, Romanowsky AJ et al (2016) The SLUGGS survey: the mass distribution in early-type galaxies within five effective radii and beyond. MNRAS 460:3838 ADS Google Scholar
Alabi A, Ferré-Mateu A, Romanowsky AJ, Brodie J, Forbes DA, Wasserman A, Bellstedt S, Martín-Navarro I, Pandya V, Stone M, Okabe N (2018) Origins of ultradiffuse galaxies in the Coma cluster—I. Constraints from velocity phase space. Mon Not R Astron Soc 479(3):3308–3318. https://doi.org/10.1093/mnras/sty1616 ArticleADS Google Scholar
An JH, Evans NW (2011) Modified virial formulae and the theory of mass estimators. MNRAS 413:1744 ADS Google Scholar
Aprile E, Aalbers J, Agostini F (2018) Dark matter search results from a one ton-year exposure of XENON1T (XENON Collaboration). PRL 121:111302 ADS Google Scholar
Arcadi G, Dutra M, Ghosh P (2018) The waning of the WIMP? A review of models, searches, and constraints. EPJC 78:203 ADS Google Scholar
Auger MW et al (2010) The Sloan Lens ACS Survey. X. Stellar, dynamical, and total mass correlations of massive early-type galaxies. ApJ 724:511 ADS Google Scholar
Bacon R, Copin Y, Monnet G (2001) The SAURON project—I. The panoramic integral-field spectrograph. MNRAS 326:23 ADS Google Scholar
Bahcall JN (1984) K giants and the total amount of matter near the sun. ApJ 276:169 ADS Google Scholar
Bartelmann M, Maturi M (2016) Weak gravitational lensing. ArXiv e-print. arXiv:1612.06535
Battaglia G, Helmi A, Breddels M (2013) Internal kinematics and dynamical models of dwarf spheroidal galaxies around the Milky Way. New Astron Rev 57:52 ADS Google Scholar
Beasley MA, Romanowsky AJ, Pota V et al (2016) An overmassive dark halo around an ultra-diffuse galaxy in the Virgo cluster. ApJL 819:L20 ADS Google Scholar
Bell E, de Jong RS (2001) Stellar mass-to-light ratios and the Tully–Fisher relation. ApJ 550:212 ADS Google Scholar
Bell EF, McIntosh DH, Katz N, Weinberg MD (2003) The optical and near-infrared properties of galaxies. I. Luminosity and stellar mass functions. ApJS 149:289 ADS Google Scholar
Bellazzini B, Cliche M, Tanedo P (2013) Effective theory of self-interacting dark matter. PRD 88:083506 ADS Google Scholar
Bernal N, Heikinheimo Tenkanen NT (2017) The dawn of FIMP dark matter: a review of models and constraints. IJMPA 32:27 Google Scholar
Bernardi M, Sheth RK, Annis J (2003) Early-type galaxies in the Sloan Digital Sky Survey. II. Correlations between observables. AJ 125:1866 ADS Google Scholar
Bershady MA, Verheijen MAW, Westfall KB (2010a) The DiskMass Survey. I. Overview. ApJ 716:234 ADS Google Scholar
Bershady MA, Verheijen MAW, Swaters RA (2010b) The DiskMass Survey. II. Error budget. ApJ 716:198 ADS Google Scholar
Bertone G (ed) (2010) Particle dark matter: observations, models and searches. Cambridge University Press, Cambridge MATH Google Scholar
Binney J, Tremaine S (2008) Galactic dynamics. Princeton University Press, Princeton MATH Google Scholar
Bloom JV (2017) The SAMI Galaxy Survey: the low-redshift stellar mass Tully–Fisher relation. MNRAS 472:1809 ADS Google Scholar
Boddy KK, Feng JL, Manoj Kaplinghat M et al (2014) Strongly interacting dark matter: self-interactions and keV lines. PRD 89:115017 ADS Google Scholar
Bode P, Ostriker JP, Turok N (2001) Halo formation in warm dark matter models. ApJ 556:93 ADS Google Scholar
Bolton AS, Burles S, Koopmans LVE et al (2006) The Sloan Lens ACS Survey. I. A large spectroscopically selected sample of massive early-type lens galaxies. ApJ 638:703 ADS Google Scholar
Bolton AS, Burles S, Treu T (2007) A more fundamental plane. ApJ 665:105 ADS Google Scholar
Bolton AS et al (2008) The Sloan Lens ACS Survey. VII. Elliptical galaxy scaling laws from direct observational mass measurements. ApJ 684:248 ADS Google Scholar
Bonnivard V et al (2015) Dark matter annihilation and decay in dwarf spheroidal galaxies: the classical and ultrafaint dSphs. MNRAS 453:849 ADS Google Scholar
Bosma A (1981a) 21-cm line studies of spiral galaxies. II. The distribution and kinematics of neutral hydrogen in spiral galaxies of various morphological types. AJ 86:1791 ADS Google Scholar
Bosma A (1981b) 21-cm line studies of spiral galaxies. I—observations of the galaxies NGC 5033, 3198, 5055, 2841, and 7331. AJ 86:1825 ADS Google Scholar
Bothun GD, Impey CD, Malin DF (1991) Extremely low surface brightness galaxies in the Fornax Cluster—properties, stability, and luminosity fluctuations. ApJ 376:404 ADS Google Scholar
Bottema R, Pestaña JLG (2015) The distribution of dark and luminous matter inferred from extended rotation curves. MNRAS 448:2566 ADS Google Scholar
Boyarsky A, Nevalainen J, Ruchayskiy O (2007) Constraints on the parameters of radiatively decaying dark matter from the dark matter halos of the Milky Way and Ursa Minor. A&A 471:51 ADS Google Scholar
Breddels MA, Helmi A, van den Bosch RCE et al (2013) Orbit-based dynamical models of the Sculptor dSph galaxy. MNRAS 433:3173 ADS Google Scholar
Bringmann T et al (2016) Suppressing structure formation at dwarf galaxy scales and below: late kinetic decoupling as a compelling alternative to warm dark matter. PRD 94:103529 ADS Google Scholar
Brook CB, Santos-Santos I, Stinson G (2016) The different baryonic Tully–Fisher relations at low masses. MNRAS 459:638 ADS Google Scholar
Brown WR, Geller MJ, Kenyon SJ, Diaferio A (2009) The anisotropic spatial distribution of hypervelocity stars. ApJ 690:1639 ADS Google Scholar
Bruzual G, Charlot S (2003) Stellar population synthesis at the resolution of 2003. MNRAS 344:1000 ADS Google Scholar
Bullock JS, Boylan-Kolchin M (2017) Small-scale challenges to the \(\varLambda \)CDM paradigm. ARAA 55:343 ADS Google Scholar
Burkert A (1995) The structure of dark matter halos in dwarf galaxies. ApJL 447:L25 ADS Google Scholar
Burkert A (2015) The structure and dark halo core properties of dwarf spheroidal galaxies. ApJ 808:158 ADS Google Scholar
Butler J (2018) Dark matter searches at the LHC. PoS(ALPS2018), 030
Caldwell JAR, Ostriker JP (1981) The mass distribution within our Galaxy—a three component model. ApJ 251:61 ADS Google Scholar
Campbell DJR et al (2017) Knowing the unknowns: uncertainties in simple estimators of galactic dynamical masses. MNRAS 469:2335 ADS Google Scholar
Cappellari M (2016) Structure and kinematics of early-type galaxies from integral field spectroscopy. ARAA 54:597 ADS Google Scholar
Cappellari M, Emsellem E, Krajnović D et al (2011) The ATLAS\(^{3D}\) project—VII. A new look at the morphology of nearby galaxies: the kinematic morphology-density relation. MNRAS 413:813 ADS Google Scholar
Cappellari M et al (2012) Systematic variation of the stellar initial mass function in early-type galaxies. Nature 484:485 ADS Google Scholar
Cappellari M et al (2013) The ATLAS\(^{3D}\) project—XX. Mass-size and mass-\(\sigma \) distributions of early-type galaxies: bulge fraction drives kinematics, mass-to-light ratio, molecular gas fraction and stellar initial mass function. MNRAS 432:1709 ADS Google Scholar
Cappellari M, Romanowsky AJ, Brodie JP et al (2015) Small scatter and nearly isothermal mass profiles to four half-light radii from two-dimensional stellar dynamics of early-type galaxies. ApJL 804:L21 ADS Google Scholar
Cappellari M et al (2006) The SAURON project—IV. The mass-to-light ratio, the virial mass estimator and the Fundamental Plane of elliptical and lenticular galaxies. MNRAS 366:1126 ADS Google Scholar
Carignan C, Freeman KC (1985) Basic parameters of dark halos in late-type spirals. ApJ 294:494 ADS Google Scholar
Catena R, Ullio P (2010) A novel determination of the local dark matter density. JCAP 08(2010):004 ADS Google Scholar
Catena R, Ullio P (2012) The local dark matter phase-space density and impact on WIMP direct detection. JCAP 05(2012):005 ADS Google Scholar
Catinella B, Giovanelli R, Haynes MP (2006) Template rotation curves for disk galaxies. ApJ 640:751 ADS Google Scholar
Chae K-H (2014) A universal power-law profile of pseudo-phase-space density-like quantities in elliptical galaxies. ApJL 788:L15 ADS Google Scholar
Coccato L, Gerhard O, Arnaboldi M et al (2009) Kinematic properties of early-type galaxy haloes using planetary nebulae. MNRAS 394:1249 ADS Google Scholar
Corbelli E, Salucci P (2000) The extended rotation curve and the dark matter halo of M33. MNRAS 311:441 ADS Google Scholar
Corsini EM, Wegner GA, Thomas J et al (2017) The density of dark matter haloes of early-type galaxies in low-density environments. MNRAS 466:974 ADS Google Scholar
Courteau S (1997) Optical rotation curves and linewidths for Tully–Fisher applications. AJ 114:2402 ADS Google Scholar
Cretton N, de Zeeuw PT, van der Marel RP, Rix H-W (1999) Axisymmetric three-integral models for galaxies. ApJS 124:383 ADS Google Scholar
Deason AJ, Belokurov V, Evans NW, An J (2012) Broken degeneracies: the rotation curve and velocity anisotropy of the Milky Way halo. MNRAS 424:L44 ADS Google Scholar
de Blok WJG (2010) The core–cusp problem. Adv Astron 2010:789293 ADS Google Scholar
de Blok WJG, McGaugh SS, Rubin VC (2001) High-resolution rotation curves of low surface brightness galaxies. II. Mass models. AJ 122:2396 ADS Google Scholar
de Blok WJG, Walter F, Brinks E (2008) High-resolution rotation curves and galaxy mass models from THINGS. AJ 136:2648 ADS Google Scholar
De Masi C, Matteucci F, Vincenzo F (2018) The effects of the initial mass function on the chemical evolution of elliptical galaxies. MNRAS 474:5259 ADS Google Scholar
Destri C, de Vega P, Sanchez NG (2013) Warm dark matter primordial spectra and the onset of structure formation at redshift z. PRD 88:3512 Google Scholar
de Swart J, Bertone G, van Dongen J (2017) How dark matter came to matter. Nat Astron 1:005 Google Scholar
de Vega HJ, Sanchez NG (2017) Equation of state, universal profiles, scaling and macroscopic quantum effects in warm dark matter galaxies. EPJC 77:1 Google Scholar
de Zeeuw PT, Bureau M, Emsellem E (2002) The SAURON project—II. Sample and early results. MNRAS 329:513 ADS Google Scholar
Di Cintio A, Brook CB, Dutton AA et al (2014) A mass-dependent density profile for dark matter haloes including the influence of galaxy formation. MNRAS 441:2986 ADS Google Scholar
Di Paolo C, Salucci P (2018) The universal rotation curve of low surface brightness galaxies IV: the interrelation between dark and luminous matter. ArXiv e-print. arXiv:1805.07165
Di Paolo C, Nesti F, Villante FL (2018) Phase-space mass bound for fermionic dark matter from dwarf spheroidal galaxies. MNRAS 475:5385 ADS Google Scholar
Djorgovski S, Davis M (1987) Fundamental properties of elliptical galaxies. ApJ 313:59 ADS Google Scholar
Dodelson S, Widrow LM (1994) Sterile neutrinos as dark matter. PRL 72:17 ADS Google Scholar
Donato F, Gentile G, Salucci P (2004) Cores of dark matter haloes correlate with stellar scalelengths. MNRAS 353:17 ADS Google Scholar
Donato F, Gentile G, Salucci P et al (2009) A constant dark matter halo surface density in galaxies. MNRAS 397:1169 ADS Google Scholar
Dressler A, Lynden-Bell D, Burstein D et al (1987) Spectroscopy and photometry of elliptical galaxies. I—a new distance estimator. ApJ 313:42 ADS Google Scholar
Ellis G et al (2018) The standard cosmological model: achievements and issues. Found Phys 48:1226 ADSMathSciNetMATH Google Scholar
Ettori S, Fabian AC (2006) Effects of sedimented helium on the X-ray properties of galaxy clusters. MNRAS 369:L42 ADS Google Scholar
Evoli C, Salucci P, Lapi A, Danese L (2011) The HI content of local late-type galaxies. ApJ 743:45 ADS Google Scholar
Faber SM, Gallagher JS (1979) Masses and mass-to-light ratios of galaxies. ARAA 17:135 ADS Google Scholar
Fabricant D, Rybicki G, Gorenstein P (1984) Further evidence for M87’s massive, dark halo. ApJ 286:186 ADS Google Scholar
Freeman KC (1970) On the disks of spiral and so galaxies. ApJ 160:811 ADS Google Scholar
Freese K (2017) Status of dark matter in the universe. IJMPD 26:1730012 ADS Google Scholar
Gammaldi V (2015) Indirect searchers of TeV dark matter. PhD thesis, UCM Madrid
Gammaldi V (2016) Highlights on gamma rays, neutrinos and antiprotons from TeV dark matter. EPJ Web Conf 121:06003 Google Scholar
García-Bellido J (2017) Massive primordial black holes as dark matter and their detection with gravitational waves. J Phys Conf Ser 840:012032 Google Scholar
Gentile G, Salucci P, Klein U, Vergani D, Kalberla P (2004) The cored distribution of dark matter in spiral galaxies. MNRAS 351:903 ADS Google Scholar
Gentile G, Burkert A, Salucci P et al (2005) The dwarf galaxy DDO 47 as a dark matter laboratory: testing cusps hiding in triaxial halos. ApJ 634:145 ADS Google Scholar
Genzel R, Schreiber NMF, Übler H et al (2017) Strongly baryon-dominated disk galaxies at the peak of galaxy formation ten billion years ago. Nature 543:397 ADS Google Scholar
Gondolo P (2002) Recoil momentum spectrum in directional dark matter detectors. PRD 66:103513 ADS Google Scholar
Gratier P, Braine J, Rodriguez-Fernandez NJ et al (2010) Molecular and atomic gas in the Local Group galaxy M 33. A&A 522:A3 ADS Google Scholar
Graves GJ, Faber SM (2010) Dissecting the red sequence. III. Mass-to-light variations in three-dimensional fundamental plane space. ApJ 717:803 ADS Google Scholar
Green AM (2016) Microlensing and dynamical constraints on primordial black hole dark matter with an extended mass function. PRD 94:063530 ADS Google Scholar
Grillo C, Gobat R, Lombardi M, Rosati P (2009) Photometric mass and mass decomposition in early-type lens galaxies. A&A 501:461 ADS Google Scholar
Gurovich S, McGaugh SS, Freeman KC (2004) The baryonic Tully–Fisher relation. PASA 21:412 ADS Google Scholar
Hessman FV (2017) Estimating the baryonic masses of face-on spiral galaxies from stellar kinematics. MNRAS 469:1147 ADS Google Scholar
Hoekstra H, Jain B (2008) Weak gravitational lensing and its cosmological applications. Annu Rev Nucl Part Sci 58:99 ADS Google Scholar
Honma M, Nagayama T, Ando K et al (2012) Fundamental parameters of the Milky Way galaxy based on VLBI astrometry. PASJ 64:136 ADS Google Scholar
Hudson MJ, Gillis BR, Coupon J et al (2015) CFHTLenS: co-evolution of galaxies and their dark matter haloes. MNRAS 447:298 ADS Google Scholar
Hui L, Ostriker JP, Tremaine S, Witten E (2017) Ultralight scalars as cosmological dark matter. PRD 95:043541 ADS Google Scholar
Hyde JB, Bernardi M (2009) The luminosity and stellar mass Fundamental Plane of early-type galaxies. MNRAS 396:1171 ADS Google Scholar
Impey C, Bothun G, Malin D (1988) Virgo dwarfs—new light on faint galaxies. ApJ 330:634 ADS Google Scholar
Jorgensen I, Franx M, Kjaergaard P (1996) The fundamental plane for cluster E and S0 galaxies. MNRAS 280:167 ADS Google Scholar
Jungman G, Kamionkowski M, Griest K (1996) Supersymmetric dark matter. Phys Rep 267:195 ADS Google Scholar
Jurić M, Ivezić Ž, Brooks A (2008) The Milky Way tomography with SDSS. I. Stellar number density distribution. ApJ 673:864 ADS Google Scholar
Kang S, Scopel S, Tomar G, Yoon J-H (2018) Present and projected sensitivities of Dark Matter direct detection experiments to effective WIMP-nucleus couplings. ArXiv e-print. arXiv:1805.06113
Kaplinghat M, Linden T, Yu H-B (2015) Galactic center excess in \(\gamma \) rays from annihilation of self-interacting dark matter. PRL 114:211303 ADS Google Scholar
Karukes EV, Salucci P (2017) The universal rotation curve of dwarf disc galaxies. MNRAS 465:4703 ADS Google Scholar
Karukes EV, Salucci P, Gentile G (2015) The dark matter distribution in the spiral NGC 3198 out to 0.22 R\(_{{\rm vir}}\). A&A 578:A13 ADS Google Scholar
Kennedy R, Frenk C, Cole S, Benson A (2014) Constraining the warm dark matter particle mass with Milky Way satellites. MNRAS 442:2487 ADS Google Scholar
Klypin A, Trujillo-Gomez S, Primack J (2011) Dark matter halos in the standard cosmological model: results from the Bolshoi simulation. ApJ 740:102 ADS Google Scholar
Kolb EW, Turner MS (1990) The early universe. Addison Wesley, New York MATH Google Scholar
Kormendy J, Freeman KC (2004) Scaling laws for dark matter halos in late-type and dwarf spheroidal galaxies. In: Ryder SD et al (eds) Dark matter in galaxies (IAU S220). ASP, San Francisco, p 377 Google Scholar
Korsaga M, Carignan C, Amram P et al (2018) GHASP: an H\(\alpha \) kinematical survey of spiral galaxies—XI. Distribution of luminous and dark matter in spiral and irregular nearby galaxies using WISE photometry. MNRAS 478:50 ADS Google Scholar
Koushiappas SM, Loeb A (2017) Dynamics of dwarf galaxies disfavor stellar-mass black holes as dark matter. PRL 119:041102 ADS Google Scholar
Kregel M, van der Kruit PC, de Grijs R (2002) Flattening and truncation of stellar discs in edge-on spiral galaxies. MNRAS 334:646 ADS Google Scholar
Kusenko A (2009) Sterile neutrinos: the dark side of the light fermions. Phys Rep 481:1 ADS Google Scholar
Kuzio de Naray R, McGaugh SS, de Blok WJG (2008) Mass models for low surface brightness galaxies with high-resolution optical velocity fields. ApJ 676:920 ADS Google Scholar
Lapi A, Salucci P, Danese L (2018) Precision scaling relations for disk galaxies in the local universe. ApJ 859:2 ADS Google Scholar
Lelli F, McGaugh SS, Schombert JM (2016a) The small scatter of the baryonic Tully–Fisher relation. ApJL 816:L14 ADS Google Scholar
Lelli F, McGaugh SS, Schombert JM (2016b) SPARC: mass models for 175 disk galaxies with Spitzer photometry and accurate rotation curves. AJ 152:157 ADS Google Scholar
Li B, Shapiro PR, Rindler-Daller T (2017) Bose–Einstein-condensed scalar field dark matter and the gravitational wave background from inflation: new cosmological constraints and its detectability by LIGO. PRD 96:063505 ADS Google Scholar
Lisanti M (2017) Lectures on dark matter physics. In: Polchinski J, Vieira P, DeWolfe O (eds) New frontiers in fields and strings. World Scientific, Singapore, pp 399–446 Google Scholar
Magoulas C, Springob CM, Colless M et al (2012) The 6dF Galaxy Survey: the near-infrared Fundamental Plane of early-type galaxies. MNRAS 427:245 ADS Google Scholar
Mamon G, Lokas EL (2005) Dark matter in elliptical galaxies—II. Estimating the mass within the virial radius. MNRAS 363:705 ADS Google Scholar
Maraston C (2013) In: Thomas D, Pasquali A, Ferreras I (eds) The intriguing life of massive galaxies (IAU S295). Cambridge University Press, Cambridge, p 272
Martinsson T, Verheijen M, Westfall K et al (2013) The DiskMass Survey. VII. The distribution of luminous and dark matter in spiral galaxies. A&A 557:131 Google Scholar
Matteucci F (2012) Chemical evolution of galaxies. Springer, Berlin Google Scholar
McGaugh SS (2005) The baryonic Tully–Fisher relation of galaxies with extended rotation curves and the stellar mass of rotating galaxies. ApJ 632:859 ADS Google Scholar
McGaugh SS, Schombert JM, Bothun GD, de Blok WJG (2000) The baryonic Tully–Fisher relation. ApJL 533:L99 ADS Google Scholar
McMillan PJ (2011) Mass models of the Milky Way. MNRAS 414:2446 ADS Google Scholar
Moster BP, Somerville RS, Maulbetsch C et al (2010) Constraints on the relationship between stellar mass and halo mass at low and high redshift. ApJ 710:903 ADS Google Scholar
Müller O, Pawlowski MS, Jerjen T et al (2018) A whirling plane of satellite galaxies around Centaurus A challenges cold dark matter cosmology. Science 359:534 ADSMathSciNetMATH Google Scholar
Munshi D, Valageas P, van Waerbeke L, Heavens A (2008) Cosmology with weak lensing surveys. Phys Rep 462:67 ADS Google Scholar
Naab T, Ostriker JP (2017) Theoretical challenges in galaxy formation. ARAA 55:59 ADS Google Scholar
Navarro JF, Frenk CS, White SDM (1997) A universal density profile from hierarchical clustering. ApJ 490:493 ADS Google Scholar
Nesti F, Salucci P (2013) The dark matter halo of the Milky Way, AD 2013. JCAP 7:16 ADS Google Scholar
Noordermeer E, van der Hulst JM, Sancisi R et al (2007) The mass distribution in early-type disc galaxies: declining rotation curves and correlations with optical properties. MNRAS 376:1513 ADS Google Scholar
Oguri M et al (2014) The stellar and dark matter distributions in elliptical galaxies from the ensemble of strong gravitational lenses. MNRAS 439:2494 ADS Google Scholar
Oh S-H (2008) High-resolution mass models of dwarf galaxies from LITTLE THINGS. AJ 136:2761 ADS Google Scholar
Oh S-H, Brook C, Governato F (2011) Dark and luminous matter in THINGS dwarf galaxies. AJ 142:24 ADS Google Scholar
Oh S-H, Hunter DA, Brinks E et al (2015) High-resolution mass models of dwarf galaxies from LITTLE THINGS. AJ 149:180 ADS Google Scholar
Oman KA, Navarro JF, Fattahi A et al (2015) The unexpected diversity of dwarf galaxy rotation curves. MNRAS 452:3650 ADS Google Scholar
Palunas P, Williams TB (2000) Maximum disk mass models for spiral galaxies. AJ 120:2884 ADS Google Scholar
Pascale R, Posti L, Nipoti C, Binney J (2018) Action-based dynamical models of dwarf spheroidal galaxies: application to Fornax. MNRAS 480:927 ADS Google Scholar
Pato M, Iocco F (2017) galkin: a new compilation of Milky Way rotation curve data. SoftwareX 6:54 ADS Google Scholar
Persic M, Salucci P (1990) Mass decomposition of spiral galaxies from disc kinematics. MNRAS 245:577 ADS Google Scholar
Persic M, Salucci P (1991) The universal galaxy rotation curve. ApJ 368:60 ADS Google Scholar
Persic M, Salucci P (1995) Rotation curves of 967 spiral galaxies. ApJS 99:501 ADS Google Scholar
Persic M, Salucci P, Stel F (1996) The universal rotation curve of spiral galaxies—I. The dark matter connection. MNRAS 281:27 ADS Google Scholar
Collaboration Planck, Ade PAR, Aghanim N (2016) Planck 2015 results. XIII. Cosmological parameters. A&A 594:A13 ADS Google Scholar
Plummer HC (1915) The distribution of stars in globular clusters. MNRAS 76:107 ADS Google Scholar
Poci A, Cappellari M, McDermid RM (2017) Systematic trends in total-mass profiles from dynamical models of early-type galaxies. MNRAS 467:1397 ADS Google Scholar
Ponomareva AA, Verheijen MAW, Papastergis E (2018) The multiwavelength Tully–Fisher relation with spatially resolved HI kinematics. MNRAS 474:4366 ADS Google Scholar
Posacki S, Cappellari M, Treu T et al (2015) The stellar initial mass function of early-type galaxies from low to high stellar velocity dispersion: homogeneous analysis of ATLAS\(^{3D}\) and Sloan Lens ACS galaxies. MNRAS 446:493 ADS Google Scholar
Pulsoni C, Gerhard O, Arnaboldi M et al (2017) The extended Planetary Nebula Spectrograph (ePN.S) early-type galaxy survey: the kinematic diversity of stellar halos and the relation between halo transition scale and stellar mass. A&A 618:A94 ADS Google Scholar
Ratnam C, Salucci P (2000) The mass distribution in the innermost regions of spiral galaxies. NewA 5:427 ADS Google Scholar
Richards EE, van Zee L, Barnes KL (2015) Baryonic distributions in galaxy dark matter haloes—II. Final results. MNRAS 449:3981 ADS Google Scholar
Ringwald A (2012) Exploring the role of axions and other WISPs in the dark universe. Phys Dark Univ 1:116 Google Scholar
Roberts MS (1978) The rotation curves of galaxies. AJ 83:1026 ADS Google Scholar
Roszkowski L, Sessolo EM, Trojanowski S (2017) WIMP dark matter candidates and searches—current status and future prospects. Rep Prog Phys 81:066201 ADSMathSciNet Google Scholar
Rubin VC, Ford WK Jr, Thonnard N (1980) Rotational properties of 21 Sc galaxies with a large range of luminosities and radii, from NGC 4605 (\(R = 4\) kpc) to UGC 2885 (\(R = 122\) kpc). ApJ 238:471 ADS Google Scholar
Salucci P (2001) The constant-density region of the dark haloes of spiral galaxies. MNRAS 320:L1 ADS Google Scholar
Salucci P, Burkert A (2000) Dark matter scaling relations. ApJL 537:L9 ADS Google Scholar
Salucci P, Turini N (2017) Evidences for collisional dark matter in galaxies? ArXiv e-print. arXiv:1707.01059
Salucci P, Frenk CS, Persic M (1993) A physical distance indicator for spiral galaxies and the determination of \(H_0\). MNRAS 262:392 ADS Google Scholar
Salucci P, Lapi A, Tonini C, Gentile G, Yegorova I, Klein U (2007) The universal rotation curve of spiral galaxies—II. The dark matter distribution out to the virial radius. MNRAS 378:41 ADS Google Scholar
Salucci P, Yegorova IA, Drory N (2008) The disc mass of spiral galaxies. MNRAS 388:159 ADS Google Scholar
Salucci P, Nesti F, Gentile G, Frigerio Martins C (2010) Dark matter scaling relations. A&A 523:83 ADS Google Scholar
Salucci P, Wilkinson MI, Walker MG et al (2012) Dwarf spheroidal galaxy kinematics and spiral galaxy scaling laws. MNRAS 420:2034 ADS Google Scholar
Schneider P (1996) Detection of (dark) matter concentrations via weak gravitational lensing. MNRAS 283:837 ADS Google Scholar
Serra P, Oosterloo T, Cappellari M, den Heijer M, Jozsa GIG (2016) Linear relation between HI circular velocity and stellar velocity dispersion in early-type galaxies, and slope of the density profiles. MNRAS 460:1382 ADS Google Scholar
Shankar F, Lapi A, Salucci P (2006) New relationships between galaxy properties and host halo mass, and the role of feedbacks in galaxy formation. ApJ 643:14 ADS Google Scholar
Shi X, Fuller GM (1999) New dark matter candidate: nonthermal sterile neutrinos. PRL 82:2832 ADS Google Scholar
Shi D (2017) Deep imaging of the HCG 95 field. I. Ultra-diffuse galaxies. ApJ 846:26 ADS Google Scholar
Simon JD, Bolatto AD, Leroy A, Blitz L, Gates EL (2005) High-resolution measurements of the halos of four dark matter-dominated galaxies: deviations from a universal density profile. Astrophys J 621(2):757–776. https://doi.org/10.1086/427684 ArticleADS Google Scholar
Sofue Y (2013) Rotation curve and mass distribution in the galactic center—from black hole to entire galaxy. PASJ 65:118 ADS Google Scholar
Sofue Y (2017) Rotation and mass in the Milky Way and spiral galaxies. PASJ 69:R1 ADS Google Scholar
Somerville RS, Dave R (2015) Physical models of galaxy formation in a cosmological framework. ARAA 53:51 ADS Google Scholar
Spano M, Marcelin M, Amram P et al (2008) GHASP: an H\(\alpha \) kinematic survey of spiral and irregular galaxies—V. Dark matter distribution in 36 nearby spiral galaxies. MNRAS 383:297 ADS Google Scholar
Spekkens K, Giovanelli R, Haynes MP (2005) The cusp/core problem in galactic halos: long-slit spectra for a large dwarf galaxy sample. AJ 129:2119 ADS Google Scholar
Spergel DN, Steinhardt PJ (2000) Observational evidence for self-interacting cold dark matter. PRL 84:3760 ADS Google Scholar
Steigman S, Turner MS (1985) Cosmological constraints on the properties of weakly interacting massive particles. Nucl Phys B 253:375 ADS Google Scholar
Strauss MJ, Willick JA (1995) The density and peculiar velocity fields of nearby galaxies. Phys Rep 261:271 ADS Google Scholar
Strigari LE, Bullock JS, Kaplinghat M et al (2008) A common mass scale for satellite galaxies of the Milky Way. Nature 454:1096 ADS Google Scholar
Strigari LE, Frenk CS, White SDM (2018) Dynamical constraints on the dark matter distribution of the sculptor dwarf spheroidal from stellar proper motions. ApJ 860:56 ADS Google Scholar
Thomas J, Saglia RP, Bender R et al (2011) Dynamical masses of early-type galaxies: a comparison to lensing results and implications for the stellar initial mass function and the distribution of dark matter. MNRAS 415:545 ADS Google Scholar
Tinsley BM (1981) Correlation of the dark mass in galaxies with Hubble type. MNRAS 194:63 ADS Google Scholar
Tiret O, Salucci P, Bernardi M, Maraston C, Pforr J (2011) The inner structure of very massive elliptical galaxies: implications for the inside-out formation mechanism of \(z \sim 2\) galaxies. MNRAS 411:1435 ADS Google Scholar
Toloba E, Lim S, Peng E et al (2018) Dark matter in ultra-diffuse galaxies in the Virgo cluster from their globular cluster populations. ApJL 856:L31 ADS Google Scholar
Tortora C, La Barbera F, Napolitano NR et al (2014) Systematic variations of central mass density slopes in early-type galaxies. MNRAS 445:115 ADS Google Scholar
Tortora C, Napolitano NR, Roy N et al (2018) The last 6 Gyr of dark matter assembly in massive galaxies from the Kilo Degree Survey. MNRAS 473:969 ADS Google Scholar
Tulin S, Yu H, Zurek KM (2013) Beyond collisionless dark matter: particle physics dynamics for dark matter halo structure. PRD 87:115007 ADS Google Scholar
Tully RB, Fisher JR (1977) A new method of determining distances to galaxies. A&A 54:661 ADS Google Scholar
Turner MS (2018) \(\varLambda \)CDM: much more than we expected, but now less than what we want. Found Phys 48:1261 ADSMATH Google Scholar
van Albada TS, Bahcall JN, Begeman K et al (1985) Distribution of dark matter in the spiral galaxy NGC 3198. ApJ 295:305 ADS Google Scholar
van der Kruit PC (1988) The three-dimensional distribution of light and mass in disks of spiral galaxies. A&A 192:117 ADS Google Scholar
van der Kruit PC, Freeman KC (2011) Galaxy disks. ARAA 49:301–371 ADS Google Scholar
van der Kruit PC, Searle L (1981) Surface photometry of edge-on spiral galaxies. I—a model for the three-dimensional distribution of light in galactic disks. A&A 95:105 ADS Google Scholar
van Dokkum PG, Romanowsky AJ, Abraham R et al (2015) Spectroscopic confirmation of the existence of large, diffuse galaxies in the coma cluster. ApJL 804:L26 ADS Google Scholar
Verheijen MAW (2001) The ursa major cluster of galaxies. V. HI rotation curve shapes and the Tully–Fisher relations. ApJ 563:694 ADS Google Scholar
Viel M, Branchini E, Cen R et al (2005) Tracing the warm-hot intergalactic medium in the local Universe. MNRAS 360:1110 ADS Google Scholar
Vogelsberger M, Genel S, Springel V et al (2014) Properties of galaxies reproduced by a hydrodynamic simulation. Nature 509:177 ADS Google Scholar
Vogt NP, Haynes MP, Herter T, Giovanelli R (2004a) \(M/L\), H\(\alpha \) rotation curves, and HI gas measurements for 329 nearby cluster and field spirals. III. Evolution in fundamental galaxy parameters. AJ 127:3273 ADS Google Scholar
Vogt NP, Haynes MP, Herter T, Giovanelli R (2004b) \(M/L\), H\(\alpha \) rotation curves, and HI measurements for 329 nearby cluster and field spirals. I. Data. AJ 127:3325 ADS Google Scholar
Walker M (2013) Dark matter in the galactic dwarf spheroidal satellites. In: Oswalt TD, Gilmore G (eds) Planets, stars and stellar systems 5. Springer, Dordrecht, pp 1039–1089 Google Scholar
Walker MG, Penarrubia J (2011) A method for measuring (slopes of) the mass profiles of dwarf spheroidal galaxies. ApJ 742:20 ADS Google Scholar
Walker MG, Mateo M, Olszewski EW (2009a) Stellar velocities in the Carina, Fornax, Sculptor, and Sextans dSph galaxies: data from the Magellan/MMFS Survey. AJ 137:3100 ADS Google Scholar
Walker MG, Mateo M, Olszewski EW et al (2009b) A universal mass profile for dwarf spheroidal galaxies? ApJ 704:1274 ADS Google Scholar
Wang J, Fu J, Aumer M et al (2014) An observational and theoretical view of the radial distribution of HI gas in galaxies. MNRAS 441:2159 ADS Google Scholar
Watkins LL, Evans NW, An JH (2010) The masses of the Milky Way and Andromeda galaxies. MNRAS 406:264 ADS Google Scholar
Wechsler RH, Tinker JL (2018) The connection between galaxies and their dark matter halos. ARAA 56:435 ADS Google Scholar
Wechsler RH, Zentner AR, Bullock JS et al (2006) The dependence of halo clustering on halo formation history, concentration, and occupation. ApJ 652:71 ADS Google Scholar
Wolf J, Martinez GD, Bullock JS et al (2010) Accurate masses for dispersion-supported galaxies. MNRAS 406:1220 ADS Google Scholar
Xue XX et al (2008) The Milky Way’s circular velocity curve to 60 kpc and an estimate of the dark matter halo mass from the kinematics of \(\sim \)2400 SDSS blue horizontal-branch stars. ApJ 684:1143 ADS Google Scholar
Yegorova IA, Salucci P (2007) The radial Tully–Fisher relation for spiral galaxies—I. MNRAS 377:507 ADS Google Scholar
Zaritsky D (2012) Implications and applications of kinematic galaxy scaling relations. ISRN Astron Astrophys 2012:189625 Google Scholar
Zavala J, Vogelsberger M, Walker MG (2013) Constraining self-interacting dark matter with the Milky Way’s dwarf spheroidals. MNRAS 431:L20 ADS Google Scholar
Zhao H (1996) Analytical models for galactic nuclei. MNRAS 278:488 ADS Google Scholar
Zu Y, Mandelbaum R (2015) Mapping stellar content to dark matter haloes using galaxy clustering and galaxy-galaxy lensing in the SDSS DR7. MNRAS 454:1161 ADS Google Scholar