Sources of Gravitational Waves

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1 Sources of Gravitational Waves Joan Centrella Laboratory for High Energy Astrophysics NASA/GSFC Gravitational Interaction of Compact Objects KITP May 12-14, 2003 A Different Type of Astronomical Messenger Gravitational Waves... Characteristic amplitudes G Q h ~ c r 4 ~ R r Sch v c 2 2 2 r = distance to source R Sch = 2GM/c 2 Q = (trace-free) quadrupole moment of source v = characteristic nonspherical velocity in source generated by matter distributions with time-changing quadrupole moments carry info about bulk motion of sources interact weakly with matter carry information about deep, hidden regions in the universe Hulse-Taylor binary pulsar PSR 1913+16 Orbital period decay agrees with GR to within the observational errors of < 1% Nobel Prize 1993 Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 1

LISA / LIGO Relationship Complementary observations, different frequency bands Different astrophysical sources 3 The rich variety of sources implies GWs will tell us much about the universe. 4 Collapses * stellar * compact collapse stellar Type II SNe * accretion-induced remnants (WD, collapse NS, BH) *Stellar binaries: (AIC) Oscillations and --* short stochastic falling into * formation * neutron period backgrounds SMBH in of the 1 star (P stars modes 10 4 sec) centers deformations galactic of Pop III * BH confusion-limited of galaxies possible ringdowns binaries (NS, WD, BH ) intermediate * sources wobble mass radiation BH from --* chirping cosmological Binaries * collapse of a mountain binaries GW supermassive on (NS, stars a BH) backgrounds. * to form spinning unexpected supermassive NS sources BHs. *Intermediate * cosmic * dark string matter? mass/seed kinks and BH binaries cusps * dark (M ~ energy? 10 Gravitational captures 2 10 4 M Sun ) *?? *Supermassive BH binaries Backgrounds and bursts (M 10 5 M Sun ) Serendipity Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 2

Focus here on 3 sources involving black holes 5 Final coalescence of BH/BH binaries. Collapse of a supermassive star to a SMBH Capture of stellar remnants by SMBH at centers of galaxies and what we can learn about astrophysics and the cosmos by observing the gravitational waves they emit. Coalescing supermassive BH binaries. 6 Supermassive BHs lurk at the centers of most, if not all, galaxies Masses M 10 5 M Sun Chandra X-ray observatory found the first known system of 2 SMBH starting to merge in the galaxy NGC 6240 distance ~ 120 Mpc close! BHs will merge in ~ few x 10 8 years Most galaxies are formed from the merger of 2 progenitor galaxies merger of SMBHs LISA could observe roughly several per year, out to redshifts z > 10 Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 3

Coalescing intermediate mass or seed BH binaries 7 Black holes having masses M ~ few x 10 2 M Sun 10 4 M Sun Predicted in hierarchical structure formation theories: galaxies form from successive mergers of protogalactic fragments SMBHs at the centers of galaxies form from successive mergers of smaller seed BHs at the centers of these fragments IMBH also can form from the collapse of massive Pop III stars that form BHs in stellar clusters from successive mergers of lower mass BHs LISA will be able to detect these systems out to redshifts z ~ 7 30 will give an unprecedented view of the merger history of galaxies Ground-based detectors will see the final coalescence of systems with masses ~ few x 10 2 M Sun Coalescing stellar black hole binaries 8 Black holes having masses M ~ few x 10-10 2 M Sun Stellar BHs are formed as the end product of the core collapse of massive stars if mass of remnant core ~ 2 M Sun or larger BH will form BH may also form from fallback of gas onto NS, causing collapse Excellent source for ground-based interferometers. Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 4

Final Coalescence of BH binary.. Dominant energy loss mechanism is GW emission Coalescence time for binary of total mass M and separation a (point masses, circular orbits): 5 5 c a t GR = 3 3 64 G M For binary of total mass M = 2 x 10 6 M Sun to coalesce within t H ~ 10 10 years separation a < a max ~ 2.53 x 10 4 M ~ 2.4 x 10-3 pc GW detectors will observe the end stages of this coalescence, typically ~ 10 3 orbits LISA: will observe massive BH binaries for ~ 1 year Ground-based detectors: will observe stellar BH binaries for ~ 1 minute 9 Final coalescence proceeds in 3 stages... GW produced in all three phases of this evolution... Waveforms and dynamics scale with BH masses and spins source modeling applicable to strong-field spacetime stellar BHs, IMBHs & SMBHs. dynamics, spin flips and couplings 10 measure masses and spins of binary BHs detect normal modes of ringdown to identify final Kerr BH (graphic courtesy of Kip Thorne) Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 5

Inspiral stage Slow, quasi-adiabatic inspiral driven by GW emission chirp waveform: sinusoid increasing in amplitude & frequency as the BHs get closer together f binary 1/ 2 2 forbital 1 1 GM = = 3 (1+ z) (1 + z) a 11 Eccentricity can alter waveform shape significantly (Pierro, et al.) e = 0.274 (PSR 1534+12) e = 0.617 (PSR 1913+16) Also, precession effects due to BH spin (Vecchio, Kalogera.) Inspiral stage: MBH observable by LISA for ~ months to years Use waveforms as templates for data analysis by matched filtering If observe a sufficient number of cycles of inspiral waveform (for LISA, ~ few months or longer) within the detector s frequency band, can measure redshifted masses (1+z)M: Chirp mass c = (M 1 M 2 )3/5 /[M 1 + M 2 ] 1/5 Reduced mass (less accurately) = M 1 M 2 /[M 1 + M 2 ] Also some information on spins If know cosmology to ~ 10%, invert luminosity distance relation D L (z) to get redshift z M tot (Hughes 2002) Typically, get (1+z) c to ~ 0.1% or better c to ~ 15 30% 12 Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 6

Merger stage Inspiral lasts until separation a ~ 3R Schw = 6M 13 f inspiral 6-3 10 M Sun 4 x 10 Hz (1+ z) M BHs leave quasi-static orbits and plunge together Expect ~ several cycles of gravitational radiation burst waveform, observable by LISA for ~ minutes hours knowledge of merger waveform important to enhance detectability in ground-based GW observatories. Strong, highly nonlinear, dynamical gravitational fields Requires numerical solution of the full 3D Einstein equations Merger can be phenomenologically rich test of General Relativity in the dynamical, nonlinear regime possible ejection of final BH for M 1 M 2 effects of spin: spin-spin and spin-orbit couplings, spin flips SMBH mergers and radio lobe morphology... 14 Jets emanating from centers of active galaxies believed to result from accretion onto central SMBH jet directed along spin axis Mergers of spinning BHs can change orientation of BH spin axis sudden flip in direction of associated jet Can identify the winged or X-type radio sources with galaxies in which a merger has occurred (Merritt & Ekers, Science, 2002) Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 7

Ringdown 15 Merger rotating, highly distorted BH Rings down to a quiescent Kerr BH by emitting GW Ringdown waveforms are exponentially damped sinusoids, dominated by the strongest l = m = 2 quasinormal mode 6-3 = fqnr 3/10 10 M SUN 3.2x10 Hz fring 1-0.63(1- â), 0 ˆ (1 + z) M (1 + z) a (Echeverria; Leaver) Quality factor Ringdowns are burst waveforms For M = 2 x 10 6 M Sun, if aˆ = 0.5, [ ] 1 Q 2(1 aˆ) = f f 9 / 20 ring τ damp QNR 3 7.8x10 Hz, τ (1+ z) damp 6M 1hr For aˆ = 0.98, τ damp 29M 4.8hr Note: we observe redshifted damping timescale identify mass and spin of final Kerr BH ( 1+ z) τ damp Collapse of supermassive stars to form supermassive BHs. (Shapiro, Shibata, Baumgarte, New..) 16 Collapse of uniformly rotating supermassive star of mass M simulated in axisymmetry using full general relativity N=3 polytrope; initial SMS rotates at mass-shedding limit and is marginally unstable to radial collapse forms a BH with mass ~ 0.9M and spin parameter J/M 2 ~ 0.75, which is surrounded by a rotating disk of mass ~ 0.1 M In some cases, a nonaxisymmetric instability such as a bar mode can develop additional GW emission possible Still to come: calculate gravitational waveforms of supermassive star collapse may enable detection by LISA and shed light on mechanism by which supermassive BHs form. Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 8

Gravitational capture from nuclear star clusters 17 Compact stellar remnants orbit the massive object in the center of a galaxy GW emitted as remnant spirals in Expect LISA can detect ~ 10 5 orbits of remnant around central SMBH in last year of inspiral high precision map These inspiral waves carry the signatures of the multipole moments of the central object map its spacetime geometry determine if central object is indeed a BH by measuring 3 multipole moments Expect LISA can detect ~ several events per year, perhaps many more, out to distances of ~ few Gpc for ~10 M Sun BH remnants 18 Inspiral of stellar compact objects into massive BHs. (Hughes, Creighton, Glampedakis, Thorne, Finn, Ryan..) Challenging! Waveforms are influenced by many harmonics of orbital frequencies Signals will be relatively week (they set the noise floor for LISA) Relatively large numbers of parameters Non-equatorial circular orbit at r = 7M i=62.43 o, about BH with a = 0.95M, observed in equatorial plane of BH (Hughes 2000) Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 9

19 Gravitational Waves... a new kind of cosmic messenger Every time you build new tools to see the universe, new universes are discovered. Through the ages, we see the power of penetrating into space. -- David H. DeVorkin (paraphrasing Sir William Herschel) 20 Joan Centrella, NASA Goddard (KITP Gravitation Conf 5/12/03) 10

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