Mon.Not.R.Astron.Soc.000,000–000 (0000) Printed5February2008 (MNLATEXstylefilev2.2) Hypervelocity Collisions of Binary Stars at the Galactic Centre ⋆ Idan Ginsburg & Abraham Loeb† Harvard-Smithsonian Centerfor Astrophysics, 60 Garden St., MS51, Cambridge, MA 02138, USA 7 0 0 2 5February2008 n a J ABSTRACT 1 1 Recent surveys have identified seven hypervelocity stars (HVSs) in the halo of the Milky Way. Most of these stars may have originated from the breakup of binary 2 star systems by the nuclear black hole SgrA*. In some instances, the breakup of the v binary may lead to a collision between its member stars. We examine the dynamical 0 propertiesofthesecollisionsbysimulatingthousandsofdifferentbinaryorbitsaround 4 4 SgrA* with a direct N-body integration code. For some orbital parameters, the two 9 starscollidewithanimpactvelocitylowerthantheirescapevelocityandmaytherefore 0 coalesce. It is possible for a coalescing binary to have sufficient velocity to escape the 6 galaxy. Furthermore, some of the massive S-stars near Sgr A* might be the merger 0 remnantsofbinarysystems,howeverthisproductionmethodcannotaccountformost / of the S-stars. h p Key words: black hole physics-Galaxy:center-Galaxy:kinematics and dynamics- - stellar dynamics o r t s a : v 1 INTRODUCTION tence is robustly supported by data (e.g. Ghez et al. 2005; i Reid & Brunthaler 2004; Sch¨odelet al. 2003). X First theorized by Hills (1988), a hypervelocity star (HVS) r hassufficientvelocitytoescapethegravitationalpullofthe a MilkyWaygalaxy.ThefirstHVS,SDSSJ090745.0+024507, was recently discovered in the Galactic halo (Brown et al. SimulationsshowthattightbinariescanproduceHVSs 2005; Fuenteset al. 2005). This HVS is located at a helio- with velocities comparable to the observed HVSs (e.g. centric distance of ∼ 110 kpc and has radial velocity 853 Ginsburg & Loeb 2006 (hereafter Paper I); Bromley et al. ± 12 kms−1, over twice that needed to escape the gravita- 2006). In Paper I, we show that the companion to the hy- tional pull of the Milky Way. Since that initial discovery, pervelocitystarwillbeleftinahighlyeccentricorbit,which six other HVSshavebeen identified (Edelmann et al. 2005; agrees with the known orbits of a number of S-stars orbit- Hirsch et al.2005;Brown et al.2006a;Brown et al.2006b). ing Sgr A* (e.g. Eckart & Genzel 1997, Sch¨odel et al. 2003, Hills(1988)suggestedthataHVSmightresultfromaclose andGhez et al.2005).Therefore,wesuggestedthatsomeof encounter between a tightly bound binary star system and thesestars areformercompanions ofHVSs.Furthermore,a theblackholeattheGalacticcenter,SgrA*.Yu& Tremaine small fraction (∼10%) ofthebinarysystems werefound to (2003) refined Hills’ argument and noted that HVSs might collide. Hereweexamine in detail thedynamical properties also beproduced bythree-bodyinteractions between a star ofsuchcollisions,andcheckwhethersomeofthesecollisions and a binary black hole system. Because the existence of a may end in coalescence. second(intermediate-mass)blackholeintheGalacticcenter (Hansen & Milosavljevi´c 2003) is only ahypotheticalpossi- bility (Sch¨odel et al. 2003), we focus here on the disruption In §2 we describe the N-body code and the simulation of a tightly bound binary by a single supermassive black parameters that were used. In §3 we discuss our numerical hole (SMBH) with a mass of ∼ 4 × 106M⊙ whose exis- results for the collisions, and in §4 we discuss the outcome ofbinarymergersattheGalacticCentre.Ourgoalisnotto cover the entire range of binaries that could produce HVSs or end in collisions, but rather to determine whether some ⋆ E-mail:[email protected] tightbinarieswithmassessimilartotheHVSsobservedthus † E-mail:[email protected] far could coalesce. 2 Idan Ginsburg & Abraham Loeb 2 COMPUTATIONAL METHOD radial velocity but a tangential velocity with an amplitude in the range between 5 and 25 km s−1 at the distance of In our study we have used the N-body code written by 2000AU. In total, we ran 2000 simulations. Aarseth(Aarseth1999)whosedetailsweredescribedinPa- per I. We treat the stars as point particles and ignore tidal andgeneralrelativisticeffectsontheirorbits,sincetheseef- 3 PROPERTIES OF HYPERVELOCITY fects are small at the distance (∼ 10AU) where the binary COLLISIONS is tidally disrupted by the SMBH. We have set the mass of the SMBH to M = 4×106M⊙. The masses of the binary Givenabinarysystemwithstarsofequalmassmseparated members are set to either 3M⊙ & 3M⊙ [since 3M⊙ is the byadistanceaandaSMBHofmassM ≫matadistanceb estimated mass of SDSS J090745.0+024507 (Fuenteset al. fromthebinary,tidaldisruptionwouldoccurifb.bt where 2005)],orto3M⊙&10M⊙[as10M⊙iscomparabletothees- m M timated mass of HE0437-5439 (Edelmann et al. 2005)].All ∼ (1) a3 b3 runsstartwiththecenterofthecircularbinarylocated2000 t AU (=10−2pc) away from theSMBH along the positive y- Thedistanceof closest approach intheinitial plungeof the axis.Thisdistanceiscomparabletotheinnerscaleoftheob- binary towards the SMBH can be obtained by angular mo- serveddistributionofstarsaroundSgrA*(Eckart & Genzel mentumconservationfromitsinitialtransversespeedv⊥ at 1997;Sch¨odel et al.2003;Ghezet al.2005),allowingthere- its initial distance from the SMBH,d, mainingstartopopulatethisregion aftertheejection ofits companion. This radiusis also muchlarger than thebinary GM 1/2 v⊥d= b. (2) size or the distance of closest approach necessary to obtain b „ « therelevantejectionvelocityofHVSs,makingthesimulated The binary will be tidally disrupted if its initial transverse orbits nearly parabolic. speed is lower than some critical value, Werantwosetsofdata.Thefirsthadthebinarysystem rzotpalatinneg. aWloengustehdetxh–eysapmlaeneinaitnidaltdhiestsaenccoendfoarloanllgruthnesyto– v⊥ .v⊥,crit ≡ (GMda)1/2 „Mm«1/6 =102m10a/.1−56/d123.3 km s−1, make thecomparison among them easier to interpret as we (3) varied thedistance ofclosest approach totheSMBHor the where a−1 ≡ (a/0.1 AU), d3.3 = (d/2000 AU), m0.5 ≡ relative positions of the two stars within the binary. We (m/3M⊙).Ifv⊥ .v⊥,crit,oneofthestarsreceivessufficient choseinitialbinaryseparationsbetweena=0.05and0.2AU kineticenergy to become unbound,while thesecond star is becausesucharangeislikelytoproduceHVSsfortheabove kicked into a tighter orbit around the SMBH. The ejection parameters(seePaperI).Significantlywiderbinarieswould speedvejoftheunboundstarcanbeobtainedbyconsidering givelowerejectionvelocities(Gualandris et al.2005).Much the change in its kinetic energy ∼ vδv as it acquires a ve- tighter binaries would not be easily disrupted by the black locity shift of order the binary orbital speed δv ∼ Gm/a hole,ormaycoalescetomakeasinglestarbeforeinteracting during the disruption process of the binary at a distance p withtheSMBH.Theradiusofamainsequencestarofafew ∼b from theSMBH when thebinary center-of-mass speed t solarmassesis∼0.01AU,andthatofa10solarmassstaris isv∼ GM/b (Hills1988;Yu& Tremaine2003).Atlater t ∼0.03AU(see,e.g.Fig.4inFreitag&Benz2005).Binaries times, the binary stars separate and move independently p tighter than ∼0.02AU are precluded because the two stars relativetotheSMBH,eachwithitsown orbitalenergy.For will develop a common envelopeand eventually coalesce. v.v⊥,crit, we therefore expect IntheGalactic disk,aboutone-thirdtohalfofallstars form in binaries or small multiple systems (see e.g. Lada Gm 1/2 GM 1/2 1/2 vej ∼ 2006;Duquennoy& Mayor1991),with roughlyequalprob- "„ a « „ bt « # ability perlogarithmic intervalofseparations, dP/dln(a)= =1.7×103m1/3a−1/2 km s−1. (4) const (e.g. Abt 1983; Heacox 1998; Larson 2003). In the 0.5 −1 Galactic center environment, the maximum binary separa- Under some circumstances, the binary is disrupted in tion is limited by the tidal force of SgrA* at the distance d such a way that the two stars collide. Assuming that the where the binary is formed (for conditions that enable star impulsive kick is given by theSMBH towards a random di- formation near the SMBH, see Milosavljevi´c & Loeb 2004). rection within the orbital plane and ignoring gravitational Since the mass of the black hole is ∼106 times larger than focusing(whichisimportantatlowspeeds),theprobability that of a star, this implies a maximum binary separation foracollision inacasethatotherwisewould haveproduced less than (10−6)1/3 = 10−2 of the initial distance d. For a HVS is four time the radius of a star divided by the cir- d = 2×103AU, the upper limit on the binary separation cumference of a circle with a radius equal to the binary would be 20AU (or smaller if the tidal restriction applies separation. The likelihood for a collision is expected to be during the formation process of the binary). If we assume smaller in the more general case where the binary lies in a a constant probability per ln(a) for 0.02<a<20AU, then differentplanethanitsorbitaroundtheSMBH,unlessgrav- theprobabilityoffindingabinaryintherangeofa=0.05– itationalfocusingdominates.Table1summarizestheactual 0.2AU is substantial, ∼20%. statistical results from our runs. AsshowninPaperI,theinitialphaseofthebinaryorbit The two stars would merge as a result of the collision plays a crucial role in the outcome. Therefore, we sampled if their relative speed is lower than the escape speed from caseswithinitialphasevaluesof0-360degreesinincrements their surface (∼ 500 km s−1). In our runs 22% of all col- of 15◦. As initial conditions, we gave the binary system no lisions have impact velocities low enough to allow the two Hypervelocity Collisions of Binary Stars at the Galactic Centre 3 60 60 a = 0.05 AU a = 0.1 AU a = 0.15 AU a = 0.2 AU Sum a = 0.10 AU a = 0.15 AU a = 0.20 AU Sum 40 40 20 20 600 600 40 40 20 20 0 0 0 1000 2000 0 1000 2000 Relative Velocity upon Impact (km/s) Relative Velocity upon Impact (km/s) Figure 1. Fraction of all collisions (in percent per 100 kms−1 bin) versus relative velocity upon impact (in kms−1). The left section is for amin = 0.02 AU and the right section is for amin = 0.04 AU. The label of the lower left panel corresponds to all panels. The dashed vertical line shows the impact velocity that would have resulted from free fall starting at the binary separation (see equation 6). The solid line is the median velocity of all runs. (We choose to use the median rather than the average value because outliers bias thedataotherwise.)Theminimumimpactparameter foracollisionisexpected tobeamin=(R1+R2)=0.02AUfora3M⊙ &3M⊙ binary, but amin = 0.04 AU for a 10M⊙ & 3M⊙ binary. We show results inother cases for pedagogical purposes, namely to illustrate thedependence oftheresultsonthebinarymassesandamin separately.Ifthe10M⊙ companionisablackholethen amin∼0.01AU. orbital separation. Conservation of energy a(AU) P(3M⊙) P(10M⊙) 0.05 0.11±0.02 0.21±0.05 E = 1 m1m2 r˙2− Gm1m2 =const, (5) 0.10 0.11±0.02 0.13±0.04 2m1+m2 r 0.15 0.06±0.01 0.12±0.03 yields therelative velocity upon impact, 0.20 0.03±0.01 0.04±0.02 1 1 1/2 0.05 0.09 0.27 vf = 2G(m1+m2)(a − a) . (6) 0.10 0.06 0.13 » min – 0.15 0.03 0.09 The actual impact speed would vary around this value due 0.20 0.02 0.07 to the additional velocity induced by the SMBH tidal force along the axis connecting the stars. Nevertheless, Equation Table1.Collisionprobabilitywithdifferentvaluesofaforbina- 6 agrees well with the median of the distribution of impact riesof3M⊙&3M⊙(secondcolumn)and10M⊙&3M⊙(thirdcol- speeds in our runs (see Figure 1). Collisions always occur umn).Thetopfourrowsshowthevaluesobtainedfromoursim- shortlyaftertidaldisruption,asseenfromtheseparationof ulationswiththeircorrespondingPoissonerrors.Forcomparison, theblack and filled circles in Figure 2. the bottom rows show the expected probability from a simplis- tic“billiardball”model(withoutgravitationalfocusing)inwhich the probability of acollisionis 2(R1+R2)/2πa. Here {Ri}i=1,2 4 FATE OF THE COALESCING BINARY aretheradiiofthetwostarsand athebinaryseparation. Stellar collisions are likely the main assembly line of blue stragglers (see e.g. Leonard 1989; Bailyn & Pinsonneault 1995; Lombardi et al. 2002), and ultracompact X-ray bina- ries(e.g.Ivanovaet al.2005;Lombardi et al. 2006)in glob- stars to coalesce (see Table 2). Also of note is the fact that ular clusters. The Galactic Centre of the Milky Way is an- many collisions involve hypervelocities of v > 1000 kms−1 otherplacewherecollisionsarelikelytooccur.Tidaldisrup- upon impact. The typical impact velocity of the two stars tionsofabinarybytheSMBHwillproduce∼0.1collisions canbecrudelyestimated from amodelinwhich theSMBH per HVS (see Paper I). The ultimate fate of the binary de- removestheangularmomentumfromthebinaryandcauses pends on the velocity of its member stars upon impact. As the two stars to fall toward each other from their initial evident from Figure 1, the impact velocity vimp can vary 4 Idan Ginsburg & Abraham Loeb 100 100 00..0044 0.1 50 50 00..0022 0 (a) 00 0 (d) 0 --00..0022 -50 -50 -0.1 --00..0044 -100 -100 -4 -2 0 2 4 --00..0055 00 00..0055 -4 -2 0 2 4 -0.1 0 0.1 100 0.1 100 0.1 50 0.05 50 0 (b) 0 0 (e) 0 -50 -0.05 -50 -0.1 -100 -0.1 -100 -4 -2 0 2 4 -0.1 0 0.1 -4 -2 0 2 4 -0.1 0 0.1 100 600 00..11 0.1 50 400 0 (c) 00 (f) 0 200 -50 --00..11 -0.1 0 -100 -4 -2 0 2 4 --00..11 00 00..11 -20-10 0 10 20 -0.1 0 0.1 Figure2.Orbitsofstars(inunitsofAU)priortocollisionforbinariesof3M⊙ &3M⊙ inpanels(a)−(c)andbinariesof10M⊙ &3M⊙ inpanels (d)−(f). For all panels, the graphs on the left arethe orbits of the stars as they pass near the SMBH located at the origin. For panels (a)−(c), the graphs on the right areplotted at the center of mass frame. For panels (d)−(f), the graphs on the rightare plottedattherestframeofthe10M⊙ star.Theredfilledcircledenotes thecollisioninstantandtheblackfilledcircledenotes thetime when the stars started to move towards each other as a result of the SMBH tidal force. Note that before the binary is disrupted, the 3M⊙ star makes many revolutions as denoted by the blue circles. After the binary is disrupted, the approaching stars are denoted by blacktrianglesforclarity.Panelsaanddbothhaveaninitialseparationofa=0.05AU.Panelsbandehavea=0.10AU,andpanels candf havea=0.15AU. coremerger,whereasahead-oncollisionmightresultincore a(AU) P(3M⊙) P(10M⊙) merger, and thus form a more massive star (Dale & Davies 0.05 0.46 0.13 2006).Theresultsofsmoothedparticlehydrodynamicssim- 0.10 0.19 0.05 ulations of blue stragglers (Sills et al. 2005) show that off- 0.15 0.08 0.00 axis collisions initially have large angular momentum but 0.20 0.00 0.00 eventually lose it to allow the merger to contract down to 0.05 N/A N/A themainsequence.Off-axiscollisions,whicharemoreproba- 0.10 0.81 0.33 blethanhead-oncollisions,couldneverthelessleadtoHVSs 0.15 0.93 0.05 which are rapidly spinning (Alexander& Kumar 2001). Fi- 0.20 0.25 0.03 nally,amergerbetweenalowermassstarwithahighermass star may extend the massive star’s main-sequence phase Table 2. Probability of coalescence upon collision for different (Dale & Davies 2006). values of a for binaries of 3M⊙ & 3M⊙ (second column) and Edelmann et al. (2005) notes that HVS HE 0437-5439 10M⊙ & 3M⊙ (third column). The top four rows show the val- ues obtained fromour simulations for amin = 0.02 AU,and the might be the merger of two 4M⊙ stars, and that such a bottom rowsfor amin = 0.04AU. Herewe assumethat the two mergeris consistent with theage of theHVS.Furthermore, starswillmergeifvimp.500kms−1. Hirsch et al. (2005) suggests that HVS US 708, a sublumi- nous O star, might be the merger of two helium-core white dwarfs. After losing mass, some of the coalescing binaries in our runs might end up with sufficient velocity to escape over a wide range of values. A star with v > v ≡ imp esc [2G(m1 +m2)/(R1 +R2)]1/2 will likely pass through the thegalaxy.Unfortunately,oursimulationscannottreatmass lossaswellasthelargeamountofthermalenergydeposited other star, even during a head-on collision (Freitag & Benz in each collision (see Leonard & Livio 1995). Coalescing bi- 2005). However, in any collision there certainly will be in- narysystemsthatremainboundtotheSMBHcouldendup teractions where the smaller star may gain mass and the as massive S-stars. larger star will likely lose mass (Freitag & Benz2005).Fur- thermore, a collision where the impact velocity is less than Aside from stellar collisions of main-sequence stars, it theescapevelocityv willnotnecessarilyendasamerger. ispossible forcollisions toinvolvecompact objects. Aslong esc A grazing collision might result in envelope-ejection but no as the colliding objects are gravitationally bound, thecom- Hypervelocity Collisions of Binary Stars at the Galactic Centre 5 pactobjectwilleventuallysettletothecenterofthemerger Brown W.R.and Geller M., Kenyon S., Kurtz M., 2006b, remnant due to angular momentum transport by dynami- ApJ,647, 303 cal friction (gravitationally-induced spiral arms) or viscos- Brown W., Geller M., Kenyon S., Kurtz M., 2005, ApJL, ityinthestellar envelope(seee.g.thesimulation ofablack 622, L33 hole-helium star merger in Zhang & Fryer 2001) as well as Dale J., Davies M., 2006, MNRAS,366, 1424 gravitationalradiation.Thesituationofastellarmassblack DuquennoyA.,Mayor M., 1991, A&A,248, 485 hole surrounded by a star also appears in the collapsar Eckart A.,Genzel R.,1997, MNRAS,284, 576 progenitors of long-duration Gamma-Ray Bursts (GRBs) Edelmann H., Napiwotzki R., Heber U., Christlieb N., (MacFadyen & Woosley1999).However,theseeventsresult Reimers D., 2005, ApJL, 634, L181 fromthecollapseofthestellarcoreandsotheaccretionrate Freitag M., Benz W., 2005, MNRAS,358, 1133 into the black hole is larger than the Eddington limit by FuentesC.,StanekK.,GaudiB.,McLeodB.,BogdanovS., morethan10ordersofmagnitude(Narayan et al.2001).In HartmanJ.,HickoxR.,HolmanM.,2005, ApJL,submit- ourcase,theaccretionmightbelimitedbytheEddingtonlu- ted (astro-ph/0507520) minosityandsotheresultingsourceswouldbemuchfainter Ghez A., Salim S., Hornstein S., Tanner A., Lu J., Morris thanGRBs.Itisunclearwhetherthisaccretionwouldresult M., Becklin E., DuchˆeneG., 2005, ApJ, 620, 744 inanimplosionoranexplosion.Inthecaseofaneutronstar Ginsburg I., Loeb A., 2006, MNRAS,368, 221 (Paper I) companion,onegetsaThorne-Z˙ytkowobject,withasimilar Gualandris A., Portegies Zwart S., Sipior M., 2005, MN- accretion rate (Podsiadlowski 1996). 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