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Edo Berger (Harvard CfA) Eliot Quataert, Siva Darbha, Dan Kasen, & Daniel Perley (UC Berkeley)

EM Counterparts of Neutron Star Binary Mergers and their Detection in the Era of Advanced LIGO. Brian Metzger. Princeton University NASA Einstein Fellow. In Collaboration with:. Edo Berger (Harvard CfA) Eliot Quataert, Siva Darbha, Dan Kasen, & Daniel Perley (UC Berkeley)

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Edo Berger (Harvard CfA) Eliot Quataert, Siva Darbha, Dan Kasen, & Daniel Perley (UC Berkeley)

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  1. EM Counterparts of Neutron Star Binary Mergers and their Detection in the Era of Advanced LIGO Brian Metzger Princeton University NASA Einstein Fellow In Collaboration with: Edo Berger (Harvard CfA) Eliot Quataert, Siva Darbha, Dan Kasen, & Daniel Perley (UC Berkeley) Almudena Arcones (U Basel) & Gabriel Martinez-Pinedo (GSI, Darmstadt) LIGO Open Data Workshop, Livingston, LA, October 27, 2011

  2. Electromagnetic Counterparts of NS-NS/NS-BH Mergers Importance of EM Detection:  Astrophysical Context(e.g. Identify Host Galaxy & Environment)  Improve Effective Sensitivity of G-Wave Detectors(e.g. Kochanek & Piran 93)  Cosmology: Redshift  Measurement of H0(e.g. Krolak & Schutz 87; Nissanke+ 10)

  3. Electromagnetic Counterparts of NS-NS/NS-BH Mergers Importance of EM Detection:  Astrophysical Context(e.g. Identify Host Galaxy & Environment)  Improve Effective Sensitivity of G-Wave Detectors(e.g. Kochanek & Piran 93)  Cosmology: Redshift  Measurement of H0(e.g. Krolak & Schutz 87; Nissanke+ 10) Four “Cardinal Virtues” of a Promising Counterpart(Metzger & Berger 2011) “Kilonova” Detectable with present or upcoming facilities (given a reasonable allocation of resources). Accompany a high fraction of GW events. Be unambiguously identifiable (a “smoking gun”). Allow for determination of an accurate ~arcsecond sky localization. (see talk by S. Nissanke) Short GRB

  4. Electromagnetic Counterparts of NS-NS/NS-BH Mergers Importance of EM Detection:  Astrophysical Context(e.g. Identify Host Galaxy & Environment)  Improve Effective Sensitivity of G-Wave Detectors(e.g. Kochanek & Piran 93)  Cosmology: Redshift  Measurement of H0(e.g. Krolak & Schutz 87; Nissanke+ 10) Four “Cardinal Virtues” of a Promising Counterpart(Metzger & Berger 2011) “Kilonova” Detectable with present or upcoming facilities (given a reasonable allocation of resources). Accompany a high fraction of GW events. Be unambiguously identifiable (a “smoking gun”). Allow for determination of an accurate ~arcsecond sky localization. (see talk by S. Nissanke) Short GRB

  5. Credit: M. Shibata (U Tokyo)

  6. Short Gamma-Ray Burst (obs < j) (e.g. Eichler et al. 1989; Narayan et al. 1992; Aloy et al. 2005; Rezzolla et al. 2011) j Swift SGRBs Detection Rate >z (yr -1) Metzger & Berger 2011 Redshift z !!! Detection fraction by all sky -ray telescope Accretion Rate

  7. On Axis Optical Afterglow (obs < j) • - Detections  - Upper Limits • - Detections  - Upper Limits obs j see Berger (2010) Metzger & Berger 2011 Afterglow models for different jet energy Ej and ISM density n (from van Eerten & MacFadyen 2011) On axis detections constrain jet energy and circumburst density:

  8. Off Axis Afterglow (obs = 2j) peak timescale ~ day-weeks j obs Afterglow models for different jet energy Ej and ISM density n (from van Eerten & MacFadyen 2011) Detection fraction: need “LSST” for multiple detections 

  9. Far Off Axis Afterglow (obs = 4j) obs j Afterglow models for different jet energy Ej and ISM density n (from van Eerten & MacFadyen 2011)

  10. No observed afterglows detectable!!! Off Axis Radio Emission? (Nakar & Piran 2011; see talk by Kaplan) obs j Metzger & Berger 2011 Metzger & Berger 2011 Detection requires Sky error region ~ tens degrees2 Fdetect ~ 0.5 mJy at 1 GHz 100 pointings + 30 hrs EVLA   

  11. Electromagnetic Counterparts of NS-NS/NS-BH Mergers Importance of EM Detection:  Astrophysical Context(e.g. Identify Host Galaxy & Environment)  Improve Effective Sensitivity of G-Wave Detectors(Kochanek & Piran 93)  Cosmology: Redshift  Measurement of H0(e.g. Krolak & Schutz 87) Four “Cardinal Virtues” of a Promising Counterpart(Metzger & Berger 2011) “Kilonova” Detectable with present or upcoming facilities (given a reasonable allocation of resources). Accompany a high fraction of GW events. Be unambiguously identifiable (a “smoking gun”). Allow for determination of an accurate ~arcsecond sky localization. Short GRB

  12. Sources of Neutron-Rich Ejecta Tidal Tails (Dynamical Ejecta) Rosswog 2005 (e.g. Janka et al. 1999; Lee & Kluzniak 1999; Ruffert & Janka 2001; Rosswog et al. 2004; Rosswog 2005; Shibata & Taniguchi 2006; Giacomazzo et al. 2009; Rezzolla et al. 2010) Accretion Disk Outflows Neutrino-Driven Winds (Early)(McLaughlin & Surman 05; BDM+08; Dessart et al. 2009) Thermonuclear-Driven Winds (Late) (Metzger, Piro & Quataert 2008; Lee et al. 2009) Mej ~ 10-3 - 10-1 M

  13. Sources of Neutron-Rich Ejecta Tidal Tails (Dynamical Ejecta) Rosswog 2005 (e.g. Janka et al. 1999; Lee & Kluzniak 1999; Ruffert & Janka 2001; Rosswog et al. 2004; Rosswog 2005; Shibata & Taniguchi 2006; Giacomazzo et al. 2009; Rezzolla et al. 2010) Accretion Disk Outflows Neutrino-Driven Winds (Early)(McLaughlin & Surman 05; BDM+08; Dessart et al. 2009) Thermonuclear-Driven Winds (Late) (Metzger, Piro & Quataert 2008; Lee et al. 2009) Mej ~ 10-3 - 10-1 M } “mini-supernova”

  14. Radioactive Heating of NS Merger Ejecta R-Process Network (Martinez-Pinedo 2008) • neutron captures (Rauscher & Thielemann 2000) • photo-dissociations • - and -decays • fission reactions (Panov et al. 2009). 3rd BDM et al. 2010 2nd Nucleosynthesis Calculations by G. Martinez-Pinedo & A. Arcones Ye = 0.1 @ t ~ 1 day : Ye = 0.1 • R-process & Ni heating similar • ~1/2 Fission, ~1/2 -Decays • Dominant -Decays:132,134,135 I, 128,129Sb,129Te,135Xe  t-1.2 fLP = 3 x 10-6

  15. Light Curves Color Evolution Bolometric Luminosity “kilo-nova” Blackbody Model Metzger et al. 2010 Monte Carlo Radiative Transfer (SEDONA; Kasen et al. 2006) Peak Brightness MV= -15 @ t ~ 1 day for Mej = 10-2 M CAVEAT: Fe composition assumed for opacity What does a pure r-process photosphere look like?

  16. Far Off Axis (obs = 4j) - The Kilonova is Isotropic obs j Range of kilonova models w different ejecta mass Mej ~10-3 - 0.1Mand velocity v ~ 0.1-0.3 c  Detection requires depth r ~ 22-24 and cadence <~ 1 day (standard LSST 4-day survey not sufficient)

  17. GRB 080503: Candidate Kilonova(Perley, BDM et al. 2009) Optical Rebrightening @ t ~ 1 day Where’s the Host Galaxy? z = 0.561 Best-Fit Kilonova Parameters: v ~ 0.1 c, Mej ~ few 10-2 M , z ~ 0.1

  18. Conclusions • Direct detection of gravitational waves is expected within the next >~5 years, but maximizing the science return requires identifying and localizing an EM counterpart. • Short GRBs are detectable & identifiable, but are limited to <~ 1 detection yr-1 and may not provide localization. These rare detections are nevertheless crucial, so an operational -ray satellite similar to Fermi GBM is important. • No optical or radio facilities can provide all-sky coverage at a cadence and depth matched to the expected counterpart light curves  targeted follow-up is required. • Optical afterglow emission is easily detectable for on-axis events with rapid follow-up. However, off-axis optical afterglows are only detectable for obs < 2 j (even with LSST) and hence are limited to <~ 10% of all mergers. • Radio afterglow emission is isotropic, but existing and planned are not sufficiently sensitive, given the low Ejet/n from existing SGRB afterglows. • Isotropic kilonovae are in principle detectable for most events, but require a follow-up telescope with sensitivity similar to Pan-STARRs/LSST and a short cadence. This is going to be hard, so we need to start planning now!

  19. Gamma-Ray Burst “Afterglows” - Synchrotron Emission from Shock Interaction with the Circumburst Medium Zhang & MacFadyen 2009

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