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Dark Stars: Dark Matter annihilation can power the first stars Katherine Freese University of Michigan Collaborators Douglas Spolyar Paolo Gondolo Papers Phys. Rev. Lett. 98, 010001 (2008),arxiv:0705.0521 D. Spolyar , K .Freese, and P. Gondolo JCAP,11,014F (2008) arXiv:0802.1724 K. Freese, D. Spolyar, and A. Aguirre Astrophys.J.693:1563-1569,2009, arXiv:0805.3540 K. Freese, P. Gondolo, J.A. Sellwood, and D. Spolyar Astrophys.J.685:L101-L112,2008, arXiv:0806.0617 K. Freese, P. Bodenheimer, D. Spolyar, and P. Gondolo Astrophys.J.705:1031-1042,2009, arXiv:0903.1724 D. Spolyar, P. Bodenheimer, K Freese, and P Gondolo K. Freese, C. Ilie, D. Spolyar, M. Valluri, and P. Bodenheimer, Astrophys.J. 716 (2010) 1397 P. Sandick, J. Diemand, K. Freese, and D. Spolyar, Phys.Rev. D85 (2012) 083519 C.Ilie, K. Freese, M. Valluri, I. Iliev, P. Shapiro, Mon.Not.Roy.Astron.Soc. 422 (2012) 2164 From Science et Vie Dark Stars The first stars to form in the history of the universe may be powered by Dark Matter annihilation rather than by Fusion (even though the dark matter constitutes less than 1% of the mass of the star). THESE REALLY ARE STARS: atomic matter that shines due to dark matter, possibly a billion times as bright as the Sun • This new phase of stellar evolution lasts millions to billions of years (possibly even to today) Outline • The First Stars- standard picture • Dark Matter WIMPs • Life in the Roaring 20’s • Dark Star Born • Stellar structure • Dark Star can grow supermassive and superbright • When a dark star dies it becomes a giant black hole (up to a billion solar masses) First Stars: Standard Picture • Formation Basics: – – – – – First luminous objects ever. When universe was 200 million yrs old Form inside DM haloes of ~106 M¤ Atoms initially only 15% Formation is a gentle process Made only of hydrogen and helium from the Big Bang. Dominant cooling Mechanism is H2 Not a very good coolant (Hollenbach and McKee ‘79) Pioneers of First Stars Research: Abel, Bryan, Norman; Bromm, Greif, and Larson; McKee and Tan; Gao, Hernquist, Omukai, and Yoshida; Klessen; Nishii Abundances of Elements • In the hot early Universe, only free particles • The first elements formed when the Universe was 3 minutes old. From then on there was hydrogen, helium, and a smattering of lithium. • Everything else forms later in the high densities in stars: C, N, O …. Fe • Thus the first stars only had hydrogen and helium. Note: M¤ = mass of the Sun = 2 times 1033 grams Galaxies have Dark Matter Haloes The mass of the Milky Way is a trillion solar masses, i.e. a trillion times that of the Sun. The first stars formed inside Dark Matter haloes that were a million times that of the Sun, i.e. 106 M¤ Atoms constitute 15% of the total mass of these haloes. Hierarchical Structure Formation Smallest objects form first (sub earth mass) Merge to ever larger structures First stars (inside 106 M¤ haloes) first light Merge → galaxies Merge → clusters → → Scale of the Halo • Cooling time is less than Hubble time. • First useful coolant in the early universe is H2 . • H2 cools efficiently at around 1000K • The virial temperature of 106 M¤ ~1000K Note: M¤ = mass of the Sun = 2 times 1033 grams Thermal evolution of a primordial gas adiabatic phase Must be cool to collapse! 104 T [K] H2 formation line cooling 102 3-body reaction opaque to cont. loitering and (~LTE) Heat opaque to dissociation release molecular line (NLTE) 103 adiabatic contraction collision induced emission number density 0.3 Mpc Naoki Yoshida Self-gravitating cloud Eventually exceed Jeans Mass of 1000 Msun 5pc Yoshida 0.01pc Fully-molecular core A new born proto-star with T* ~ 20,000K r ~ 10 Rsun! Scales (Note: M¤ = mass of the Sun = 2 times 1033 grams) • Halo Atomic Mass ~ 105 M¤ (Halo Mass 106 M¤) ↓ • Jeans Mass • Initial Core Mass feedback effects McKee and Tan 2008 ~ 103 M¤ ↓ ~ 10-3 M¤ ↓ Accretion Final stellar Mass?? 100M¤Standard Picture With DM heating Much more massive 103 - 107 M¤ Dark Star Good news: cosmologists don't need to "invent" new particle: • Weakly Interacting Massive Particles (WIMP)s – – • Axions – • e.g. the neutralino (LSP) WIMP Miracle Pecci-Quinn Solution to the strong CP problem Primordial Black Holes – First order phase transitions (GUT models, Electro-Weak Phase transition) • Weakly Interacting Massive Particles • They feel only gravity and weak interactions • They weigh about one to ten thousand times as much as a proton • They are their own antiparticles and annihilate among themselves in the early universe, leaving behind the right numbers to explain the dark matter: • THE WIMP MIRACLE • Weakly Interacting Massive Particles • Billions pass through your body every second • No strong interactions (they would hurt) • No electromagnetic interactions • Yes, they feel gravity • Of the four fundamental forces, the other possibility is weak interactions (e.g. responsible for radioactivity) WIMPs from Supersymmetry – Extension of the Standard model • Every particle we know has a partner: photon photino quark squark electron selectron • The lightest supersymmetric partner is a WIMP dark matter candidate. Weakly interacting DM Mass 1Gev-10TeV (take 100GeV) Annihilation via the weak force Same annihilation that leads to correct WIMP abundance in today’s universe persists in the Universe today wherever there is an overabundance of WIMPs Same annihilation that gives potentially observable signal in FERMI, PAMELA, etc Detecting WIMPs • I. Colliders (Large Hadron Collider at CERN) • II. Direct Detection (Goodman and Witten 1986; Drukier, Freese, and Spergel 1986) • III. Indirect Detection: uses same annihilation responsible for today’s relic density: • Neutrinos from Sun (Silk, Olive, and Srednicki 1985) or Earth (Freese 1986; Krauss and Wilczek 1986) • Anomalous Cosmic rays from Galactic Halo (Ellis, KF et al 1987) • Neutrinos, Gamma-rays, radio waves from galactic center (Gondolo and Silk 1999) • N.B. SUSY neutralinos are their own antiparticles; they annihilate among themselves to 1/3 neutrinos, 1/3 photons, 1/3 electrons and positrons EXCITING TIMES • We made WIMP proposals twenty years ago: • It is coming to fruition! • My personal prediction: one of the anomalous results is right and we will know very soon. LHC: Taking data now 1. Found the Higgs 2. Searching for supersymmetry Supersymmetric Particles in LHC • Signature: missing energy when SUSY particle is created and some energy leaves the detector • Problem with identification: degeneracy of interpretation • SUSY can be found, but, you still don’t know how long the particle lives: fractions of a second to leave detector or the age of the universe if it is dark matter • Proof that the dark matter has been found requires astrophysical particles to be found Direct Detection of WIMP dark matter A WIMP in the Galaxy travels through our detectors. It hits a nucleus, and deposits a tiny amount of energy. The nucleus recoils, and we detect this energy deposit. Expected Rate: less than one count/kg/day! DAMA annual modulation Drukier, Freese, and Spergel (PRD 1986); Freese, Frieman, and Gould (PRD 1988) Bernabei et al 2003 NaI crystals in Gran Sasso Tunnel under the Apennine Mountains near Rome. Data do show modulation! Peak in June, minimum in December (as predicted). WIMP interpretation??? Two Issues with DAMA • 1. The experimenters won’t release their data to the public • 2. Comparison to other experiments: Some seem to agree (CoGeNT and CRESST?) Others disagree: null results from CDMS and XENON. But comparison is difficult because experiments are made of different detector materials! Can the positive signal in DAMA be compatible with null results from other experiments? Savage, Gelmini, Gondolo, and Freese, arxiv:0808:3607 (also Hooper and Zurek; Fairbairn and Schwetz;Chang, Pierce and W Data from Multiple Experiments for SI scattering INTERACTION STRENGTH WIMP MASS Joachim Kopp 10 GeV WIMPs in 2012 • COGENT (made of different element and in different continent) sees annual modulation too… but not quite the same region • CRESST (Germany) sees anomalous results around the same mass: but radioactivity in clamps • CDMS and XENON claim to rule it out, but they are designed to look for higher masses. WAIT AND SEE! • Upcoming: DM-ICE is putting NaI crystals down into the ice at the South Pole to look for modulation. If they see it too, then we’ll know! DEAP/CLEAN Miniclean Eureka MAX, GeoDM Indirect Detection WIMP Annihilation χ χ Many WIMPs are their own antiparticles, annihilate among themselves: • 1) Early Universe gives WIMP miracle • 2) Indirect Detection expts look for annihilation products • 3) Same process can power Stars (dark stars) Wq W+ e+ q ν π0 p γ γ e+ γ Annihilation Products • • • • 1/3 electron/positrons 1/3 gamma rays 1/3 neutrinos Typical particles have energies roughly 1/10 of the initial WIMP mass • All of these are detectable! Indirect Detection History • Indirect Detection (Neutrinos) • Sun (Silk,Olive,Srednicki ‘85) • Earth (Freese ‘86; Krauss, Srednicki, Wilczek ‘86) • Indirect Detection (Gamma Rays, positrons) • Milky Way Halo (Ellis, KF et al ‘87) • Galactic Center (Gondolo and Silk 2000) New Indirect Detection Results! (When it rains it pours) Pamela IceCube FERMI How to understand positron excess? • 0) Pulsars: the best bet? • 1) Astrophysics. Propagation of charged particles in the galaxy poorly understood. See Delahaye and Salati 08. • 2) proton background (misidentified as positrons), is known to rise with energy. PAMELA doesn’t identify each event (HEAT did) • 3) We happen to live in a hot spot of high dark matter density (boosted by at least factor 10) • 4) nonstandard WIMPs: e.g., nonthermal WIMPs; Kaluza Klein particles. MUST HAVE BOOSTED ANNIHILATION CROSS SECTION AND LEPTOPHILIC PRODUCTS • WHO KNOWS? FERMI satellite • Gamma-ray telescope (high energy photons) • Launched June 2008 Excess gamma-rays towards Galactic Center 130 GeV gamma-ray line in FERMI? Christoph Weniger, not yet vetted by the collaboration Lars Bergstrom pioneered idea of line searches in 1980s • From annihilation of 130 GeV WIMPs? 2 WIMPs to 2 gammas • 3.2 sigma, • From nearby the Galactic Center Many claims of WIMP dark matter detection: how can we be sure? • 1) The DAMA annual modulation: compatible with COGENT? CRESST? • 2) The HEAT and PAMELA positron excess • 3) Gamma-rays from Galactic Center: EGRET, HESS, VERITAS, FERMI • HAS DARK MATTER BEEN DISCOVERED? WIMP Annihilation χ χ Many WIMPs are their own antiparticles, annihilate among themselves: • 1) Early Universe gives WIMP miracle • 2) Indirect Detection expts look for annihilation products • 3) Same process can power stars! Wq W+ e+ q ν π0 p γ γ e+ γ Why DM annihilation in the first stars is more potent than in today’s stars: higher DM density • THE RIGHT PLACE: one single star forms at the center of a million solar mass DM halo • THE RIGHT TIME: the first stars formed in the early universe, when it was much more compact than it is now Basic Picture • The first stars form in a DM rich environment • As the gas cools and collapses to form the first stars, the cloud pulls DM in. • DM particles are their own antipartners, and annihilate more and more rapidly as the density increases • DM annihilates to e+/e- and photon endproducts of 100 GeV (or so) which collide with hydrogen, are trapped inside the cloud, and heat it up. • At a high enough DM density, the DM heating overwhelms any cooling mechanisms; the cloud can no longer continue to cool and collapse. A Dark Star is born, powered by DM. Dark Matter Power vs. Fusion • DM annihilation is (roughly) 100% efficient in the sense that all of the particle mass is converted to heat energy for the star • Fusion, on the other hand, is only 1% efficient (only a fraction of the nuclear mass is released as energy) • Fusion only takes place at the center of the star where the temperature is high enough; vs. DM annihilation takes place throughout the star. Three Conditions for Dark Stars (Spolyar, Freese, Gondolo 2007 aka Paper 1) • I) Sufficiently High Dark Matter Density ? • 2) Annihilation Products get stuck in star ? • 3) DM Heating beats H2 Cooling ? New Phase Dark Matter Heating Heating rate: Qann = nχ2 < σv >× mχ Fraction of annihilation energy deposited in the gas: ρχ2 < σv > = mχ ΓDMHeating = fQ Qann € € 4 Previous work noted that at n≤10 annihilation products simply escape (Ripamonti,Mapelli,Ferrara 07) € € cm−3 fQ : 1/3 electrons 1/3 photons 1/3 neutrinos First Condition: Large DM density • DM annihilation rate scales as DM density squared, and happens wherever DM density is high. The first stars are good candidates: good timing since density was higher in early times and good location at the center of DM halo • As star forms in the center of the halo, it gravitationally pulls in more DM. Treat via adiabatic contraction. • If the scattering cross section is large, even more gets captured (treat this possibility later). Dark Matter inside the Collapsing Cloud • At the center of the halo, a cloud of molecular hydrogen begins to collapse • Soon the atoms dominate the mass inside the cloud and control the gravity. They pull more dark matter particles inside. • We treat this via adiabatic contraction: • Angular momentum is conserved. Number of Hydrogen atpms é Time increasing é Density increasing Abel,Bryan, and Norman 2002 Dark matter density vs. radius Final Profile í Gas densities: Black: 1016 cm-3 Red: 1013 cm-3 Green: 1010 cm-3 ì Blue: Original Profile Three Conditions for Dark Stars (Paper 1) • I) OK! Sufficiently High Dark Matter Density • 2) Annihilation Products get stuck in star Annihilation Products get stuck in star? • 3) DM Heating beats H2 Cooling? Leads to New Phase Crucial Transition • At sufficiently high densities, most of the annihilation energy is trapped inside the core and heats it up • When: 9 • 3 n ≈10 /cm mχ ≈1 GeV → mχ ≈100 GeV → n ≈1013 /cm3 15−16 3 n ≈10 /cm mχ ≈10 TeV → € € DM heating dominates over all cooling mechanisms, The impeding the further collapse € of the core € € € Three Conditions for Dark Stars (Paper 1) • 1) OK! Sufficiently High Dark Matter Density • 2) OK! Annihilation Products get stuck in star • 3) DM DM Heating Heating beats beats H2 H2 Cooling? Coolin New Phase DM Heating dominates over cooling when the red lines cross the blue/green lines (standard evolutionary tracks from simulations). Then heating impedes further collapse. ΓDM ∝ < σv > mχ <σv>ann =3×10−26 cm 3 /sec € € (Spolyar, Freese, Gondolo April 2007) New proto-Stellar Phase: fueled by dark matter w/ N. Yoshida ’07 • Yoshida etal. 2007 Dark Matter Intervenes • Dark Matter annihilation grows rapidly as the gas cloud collapses. Depending upon the DM particle properties, it can stop the standard evolution at different stages. • Cooling Loses! • A “Dark Star” is born (a new Stellar phase) At the moment heating wins: • “Dark Star” supported by DM annihilation rather than fusion • They are giant diffuse stars that fill Earth’s orbit € € mχ ≈1 GeV core radius 960 a.u. Mass 11 M¤ mχ ≈100 GeV core radius 17 a.u. Mass 0.6 M¤ • THE POWER OF DARKNESS: DM is less than 1% of € of the star but provides the heat source the mass • Dark stars € are heated by DM but are not dark Dark Star Evolution • DM heating disassociates molecular hydrogen, and then ionizes the gas • Our proto star has now become a star. • We watch the star grow – Initial star is a few solar masses – Accrete more atoms and keep growing • Treat as star in equilibrium: mechanical equilibrium, thermal equilibrium Building up the mass • Start with a few M¤ Dark Star, find equilibrium solution • Accrete mass, one M¤ at a time, always finding equilibrium solutions • N.b. as accrete atoms, pull in more DM, which then annihilates • Continue until you run out of DM fuel • VERY LARGE FIRST STARS! Then, star contracts further, temperature increases, fusion will turn on, eventually make giant black hole Following DS Evolution • Gas Accretes onto molecular hydrogen Core, the system eventually forms a star. • We then solve for stellar Structure by: – Self consistently solve for the DM density and Stellar structure Atoms Low Temperature 104 K Dark Star Luminosity Gravity turns on 779M ¤ DM runs out (716M ¤) High Temperature ~ 105 K HERTZSPRUNG-RUSSELL DIAGRAM FOR DARK STARS DS Basic Picture • We find that DS are:" – Massive: more than 1000 M¤ – Large-a few a.u. (size of Earth’s orbit around Sun)" – Luminous: more than 107 solar – Cool: 10,000 K vs. 100,000 K plus • Will not reionize the universe. – Long lived: more than 106 years. – With Capture or nonCircular orbits, get even more massive, brighter, and longer lived How big do Dark Stars get? • KEY POINT: As long as the star is Dark Matter powered, it can keep growing because its surface is cool: surface temp 10,000K (makes no ionizing photons) • Therefore, atomic matter can keep falling onto it without feedback. • Previously, we considered spherical haloes and thought the dark matter runs out in the core, making a small hole in the middle with no dark matter. We made 1000 solar mass DS. • Wrong: Haloes are triaxial! MUCH MORE DM is available and the DS can end up Supermassive up to ten million solar masses. • Second mechanism to bring in more dark matter: capture SUPERMASSIVE dark stars (SMDS) from extended adiabatic contraction • Previously we thought dark matter runs out in a million years with 800 M¤ stars: end up with a donut, i.e., big spherical halo of dark matter with hole in the middle • But, triaxial haloes have all kinds of orbits (box orbits, chaotic orbits) so that much more dark matter is in there. Dark stars can grow much bigger and make supermassive stars, 105-107 M¤, last much longer, and reach 109-1011 L¤. Some may live to today • Visible in James Webb Space Telescope. • Leads to (as yet unexplained) big black Holes. A particle that comes through the center of the DS can be annihilated. However, that particle was not on an orbit that would pass through the center again anyway. The next particle will come in from a different orbit. Super Massive DS due to extended adiabatic contraction since reservoir has been replenished due to orbital structure Assuming all of the atomic matter can accrete in a 106 M ¤ halo Additional possible source of DM fuel: capture • Some DM particles bound to the halo pass through the star, scatter off of nuclei in the star, and are captured. (This it the origin of the indirect detection effect in the Earth and Sun). • Two uncertainties: (I) ambient DM density (ii) scattering cross section must be high enough. • Whereas the annihilation cross section is fixed by the relic density, the scattering cross section is a free parameter, set only by bounds from direct detection experiments. Freese, Aguirre, Spolyar 08; Iocco 08 WIMP scattering off nuclei leads to capture of more DM fuel Some DM particles bound to the halo pass through the star, scatter off of nuclei in the star, and are captured. This is the same scattering that COGENT, CDMS, XENON, DAMA, CRESST, etc are looking for (Direct Detection) General Capture Case H-R Diagram: get SUPERMASSIVE DARK STARS These are hotter and harder to detect We could have equally varied the DM scattering crosssection vs. the ambient DM density Observing Dark Stars • Supermassive Dark Stars may be detected in upcoming James Webb Space Telescope • One of JWST goals is to find first stars: only if they are dark stars is this goal realizable Cosmin Ilie, Paul Shapiro Pat Scott DS Spectrum from TLUSTY (stellar atmospheres code) n.b. DS are made of hydrogen and helium only Minihalo formation rate Shapiro, Iliev Dark Stars in Hubble Space Telescope Heaviest ones would be visible in HST as Jband dropouts (observable in 1.6 micron band but not in 1.25 micron band due to Ly-alpha absorption in the intervening gas), yet only one object was found at z=10. Thus we can bound the numbers of 10^7 solar mass SMDS. A,B,C: zform=10,12,15 SMDS in James Webb Space Telescope Brightness Wavelength DS in JWST Horizontal lines: 10^4 and 10^6 sec exposures Million solar mass SMDS as H-band dropout (see in 2.0 micron but not 1.5 micron filter, implying it’s a z=12 object) Numbers of SMDS detectable with JWST as H-band dropouts (see in 2.0 micron but not 1.5 micron filter, implying it’s z=12 object) Comparison of SMDS vs. early galaxies SMDS are brighter, have slightly different slope • If followup spectroscopy is done on an object found as as dropout with JWST, the detection of a HeII1640 emission line or an H emission line would most likely indicate that the object is a Pop III galaxy with nebular emission rather than a SMDS (Pawlik etal 2011; Zackrisson etal 2011) Lifetime of Dark Star • The DS lives as long as DM orbits continue through the DS or it captures more Dark Matter fuel: millions to billions of years. • The refueling can only persist as long as the DS resides in a DM rich environment, I.e. near the center of the DM halo. But the halo merges with other objects. • You never know! They might exist today. • Once the DM runs out, switches to fusion. What happens next? BIG BLACK HOLES Once the dark matter runs out, the star has no power source to sustain it, and it starts to collapse and heat up. When the interior reaches T=107K, fusion sets in. • A. Heger finds that fusion powered stars heavier than 153,000 solar masses are unstable and collapse to BH • Less massive stars live a million years, then becomes Black Holes • Helps explain observed black holes: • (I) in centers of galaxies • (ii) billion solar mass BH at z=6 (Fan, Jiang) • (iii) intermediate mass BH Black Hole remnants of dark stars • These live till today, have DM spikes around them, that DM annihilates to observable signals in gamma rays and positrons (explains PAMELA?) • FERMI satellite has 368 unidentified point sources: can they be seeing these effects? • Numbers of BH in Milky Way can be huge: millions between us and the GC! FERMI bounds on the fraction of minihaloes hosting dark stars Sandick, KF, etal 2010; 2011 Maximum fDS 1 ⇧ ⌅ ⇤ ⇥ ⇧ ⌅ ⇤ ⇥ ⇧ ⇤ ⇥ ⌅ 0.01 10 ⇧ ⇤ ⇥ ⌅ 0.1 0.001 ⇧ ⇤ mX 100 GeV XX⇥b b 4 1 2 3 4 Log10 MBH ⇤M ⇥ ⇥ ⌅ 5 Solid: FERMI point sources; open: gamma ray diffuse flux Final Thoughts: IMF • The Initial Mass Function of the first fusion powered stars (numbers of stars of different masses) may be determined by the Dark Matter encountered by their Dark Star progenitors: as long as there is DM, the DS keeps growing • Depends on cosmological merger details of early haloes, million to hundred million solar mass haloes Dark Stars (conclusion) • The dark matter can play a crucial role in the first stars • The first stars in the Universe may be powered by DM heating rather than fusion • These stars may be very large (1000-100,000 solar masses) and bright (million to ten billion solar luminosities) and can be detected by JWST