How Did I End Up in the Galactic Center?
Frederick Baganoff
MIT Kavli Institute for Astrophysics and Space Research
Nedfest 2017 --- UCLA
Ned @ 40
• My first research advisor – Quasar reddening – IRC +10 216 • I learned a lot about programming • Ned’s & Mark’s 40th birthday party – Ned: “brevity is the soul of wit” ‒ Hamlet – Francoise hiding Ned’s rock ‘n roll albums • Playing tennis with Ned – Ned: “You don’t have to hit the ball when you toss it.”
Good Advice! Ned @ 40
• Thesis project? – COBE launch 2+ years away – Ned: “All I have are programming projects. You don’t want to do that.” • Off to work with Matt on AGN variability • Which lead to Sgr A* and the Galactic Center
Ned @ 70
Chandra, Hubble & Spitzer Views of the Galactic Center Chandra Image of the Galactic Center
N E
Red: 2-3.7 keV Green: 3.7-4.5 keV Blue: 4.5-8 keV
5 pc Central Parsec
G359.945-0.044
2-3.5, 3.5-5, 5-8 keV GC Magnetar Outburst
SGR J1745-2900 GC Magnetar SGR J1745-2900
• Swift/BAT discovered outburst 2013 Apr 24 (Kennea et al. 2013) • NuSTAR follow-up revealed 3.76 s period (Mori et al. 2013) • Chandra imaging places it 2.4” SE of Sgr A* (Baganoff et al. 2013) • One of a handful of radio magnetars • Eatough et al. (2013) infer super- equipartition B ~ 8 mG near Bondi radius GC Magnetar SGR J1745-2900
• VLBA proper motion yields transverse velocity 236 +/- 11 km/s wrt Sgr A* (Bower et al. 2015) • Radial velocity unknown but chance alignment unlikely • Velocity & position consistent with bound orbit originating within CW disk of massive stars orbiting Sgr A* • Orbital period 700+ yr Chandra monitoring of initial 3.5 yr of outburst decay analyzed by Coti Zelati et al. (2015, 2017)
Temporal Evolution of Spin Frequency
0
−50 Hz) µ −100
−150 0.2657 Hz ( −
ν
−200 05 − 10 1.9147E −
Hz) 5 µ 0 (t) ( B
ν −5
−
ν −10 5.68×104 5.7×104 5.72×104 5.74×104 5.76×104 5.1434E+04, LI= 1.992 , QU= Time (MJD) − Approximately linear spin down CO= Pulsed Fraction Slightly Rising
1.4 ~55% 1.2
1 60
0.8 2013 May 12 ~37% 1.5 (%) 40
1 8 keV pulsed fraction 8 keV normalized intensity − − 20 0.3 0.3 10 100 1000 0.5 2016 Oct 8 −14 Time (days since outburst onset) 0.3-8 keV normalized intensity normalized 0.3-8 keV 0 0.5 1 1.5 2 PhasePhase (cycle) Time Evolution of Blackbody T & R
1 0.9
BB 0.8 kT (keV) 0.7 3
2 BB R (km) τR~356 d 1 ) 1 − 10 s 2 −
1 erg cm 12 − Absorbed flux (10
) 600 1 −
100 500 erg s 400 33 (10
Luminosity 300 10 10 20 30 40 50 20 50100 200 500 1000 Time (days since outburst onset)
L has double exponential decay: τ1 ~ 96 d, τ2 ~ 326 d Correcting for Dust Scattering Halo
—- without correction for the halo - - - with correction for the halo 30
20
+ BB Norm ID: 14702 10 +
+ ID: 16963 ID: 18058 + + + 0.6 0.8
kTBB (keV) Spectral Fits & Beloborodov Model
2013 May 12 0.1 2016 Oct 14 1
keV 0.01 1 100
3 ) 10 1
10 4 erg s 33 (1o Normalized counts s 10 keV luminosity 4 ) 0.3 σ 2 10 0 2
Residuals ( 4 12 5 0.51 2 5 Energy (keV) 11 2 ABB (10 cm ) Summary
• Crustal cooling model predicts hotspot should remain fairly constant in size while it cools as internal heat conducted up to outer crust; inconsistent with our observations • Alternative model of untwisting bundle of current- carrying closed field lines in magnetosphere works better (Beloborodov 2009) • Other models being tested Summary
• Magnetar was still visible to Chandra in 2017 July • Day-long exposures measured spin • Two more long Chandra observations approved for 2018 July => follow spin evolution for 5 yr Lots more to do in the GC
Thanks, Ned!
Happy Birthday!
Ned @ 100?