ETA Observations of Crab Pulsar Giant Pulses

ETA Observations of Crab Pulsar Giant Pulses John Simonetti,, Dept of Physics, Virginia Tech October 7, 2005 Pulsars Crab Pulsar Crab Giant Pulses Observing Pulses --- Propagation Effects Summary

Pulsars --- Discovery Hewish and Bell 1967 2048 dipole antennas (!) ν = 81 MHz Search for quasars by scintillation PSR 1919+21 (P = 1.337 s) LGM, pulsars

Pulsars --- General ~ 1700 known (~20,000 observable in Galaxy) <P> = 0.79 s P max P min max = 8.5 s (PSR J2144-3933) 0.12 Hz min = 1.56 s (PSR B1937+21) 642 Hz Pulses brief (typically few % of period) Normal Pulsars: P ~ 0.5s dp/dt ~ 10-15 s/s P/(dP/dt dp/dt) ) ~ 10 7 y Handful: glitches P /P ~ 10-7 (e.g., Crab) < 1% found in binary systems Millisecond Pulsars: P ~ 3ms dp/dt ~ 10-20 s/s P/(dP/dt dp/dt) ) ~ 10 9 y ~ 80% found in binary systems

Only a handful of Pulsars Emit radiation outside the radio, or Exhibit giant pulses, or Associated with a supernova remnant Crab has all of these attributes

Pulsars --- Pulse Profiles PSR 1133+16 (MPIfR) Mode switching Drifting subpulses Nulling B1944+17 (Deich Deich et al. 1986)

Pulsar --- Sounds (Radio signals demodulated into audio) P(s) 1/P (Hz) B0329+54 0.71 1.4 B0833-45 (Vela) 0.089 11 B0531+21 (Crab) 0.033 30 J0437-4715 4715 0.00575 174 B1937+21 0.00156 642 (Jodrell Bank)

Pulsars = Rotating Neutron Stars M ~ 1.4 solar masses R ~ 10 km (SN Type II) The only periodic phenomenon that can work! P rot,min ~ 0.5 ms (centrifugal accel ~ gravitational accel) dp/dt > 0 Lighthouse model B large, greater than about 10 12 G (for a normal pulsar) (1G = 10-4 T) large induced E (F >> gravity) curvature radiation, pair production, relativistic beaming linear pol., angle sweeps through pulse Lower ν higher emission altitude (~ 100 km)

Crab Pulsar --- Crab Nebula

Crab Pulsar --- Optical Pulses

Crab Pulsar --- Pulse Profile, Flux Density P = 0.0333 s dp/dt = 4.21 x 10-13 s/s D = 2 kpc S ν (W m -2 Hz -1 ) Moffett and Hankins (1996) Lyne and Graham-Smith (1998)

Crab Pulsar --- Discovery Staelin and Reifenstein 1968 (300ft tele.. at GB) 110-115 115 MHz 0.1 MHz channels 0.6s sampling (0.06s? Time constant was 0.05s) Giant pulses! (slope due to dispersion)

Crab Pulsar --- Giant Pulses 10 1000 times the mean pulse intensity One 10x-mean GP per 10 3 pulses (30 seconds) Hankins and Rickett (1975), 430 MHz time scales t < 100 µs s Argyle and Gower (1972) S ν ~ 10 5 Jy Hankins et al. (2003), 5 GHz t ~ 2 ns S ν ~ 10 3 Jy nano-giant pulses S in units of mean pulse energy

Giant Pulse Brightness Temperature -- 1 Ι ν r Specific Intensity (W m -2 Hz -1 sr -1 ) Ι ν Flux density (W m -2 Hz -1 ) S ν = Ι ν πr 2 / D 2 (1 Jy = 10-26 W m - 2 Hz - 1 ) D

Giant Pulse Brightness Temperature -- 2 Blackbody radiator Ι ν = (2hν 3 /c 2 ) (e( hν/kt 1) 1) -1 Rayleigh-Jeans Limit (hν( << kt) Ι ν = 2kT / λ 2 Radio astronomers define T b = brightness temperature : Ι ν = 2kT b / λ 2 T b = actual T, if the radiator is a blackbody

Giant Pulse Brightness Temperature -- 3 S ν = Ι ν πr 2 / D 2 = (2kT b / λ 2 ) πr 2 / D 2 Light-travel travel-time time size argument: r < ct T b S ν (λ 2 / 2k) 2 ) (D( / ct) 2 = (S ν / 2k) 2 (D / νt) ν 2 T b 10 30.1 K S ν (Jy)) (ν( GHz t µs ) 2 (D / 2 kpc) 2 (Cordes et al. 2004) For t=100µs, S ν = 10 5 Jy, ν=430 MHz, get T b ~ 10 31 For t=2ns, S ν = 10 3 Jy, ν=5 GHz, get T b ~ 10 37 K 31 K T b = 10 37 K is the largest for any astrophysical source

Crab Giant Pulses --- Cordes et al. 2004

Observing Pulsars --- Propagation Effects Looking through the ISM (n( e ~ 10-2 cm -3, irregular) Index of refraction at radio wavelengths n r = ( 1 ω p2 /ω 2 ) 1/2 ω p2 = 4πn4 e e 2 / m e ω p ~ 1 MHz for ionosphere ~ 1 Hz for ISM n r = 1 ω p2 /2ω 2 = plasma frequency Deviation of n r from vacuum value proportional to λ 2 V phase = ω/k = c/n r > c V group = dω/dk = n r c < c

Propagation: Dispersion --- Pulse Delay t DM delay delay = 4.1 ms DM ν GHz GHz -2 DM = nedl (pc cm -3 ) = 2.8 s DM (ν( / 38 MHz) -2 for ETA = 160 s (DM / 56.8 pc cm-3) (ν( / 38 MHz) -2 for ETA Crab obs. Across B = 18MHz bandwidth: 170 s

Propagation: Dispersion --- Pulse Smearing t DM smear = 8.3 µs s DM ν GHz -3 GHz ν MHz = 0.15 s DM (ν( / 38 MHz) -3 ν ν MHz MHz for ETA = 8.6 s (DM / 56.8 pc cm-3) (ν( / 38 MHz) -3 ν for ETA Crab observation ν MHz = 0.13 s (DM / 56.8 pc cm-3) (ν( / 38 MHz) -3 ( ν ν / 15 khz) For ETA Crab obs., with smallest ν

Propagation: Scattering Thin Screen Model (Lorimer and Kramer 2005; Cordes 2002) φ rms proportional to λ 2 >1 radian for ν < 5 GHz, D > 1kpc (roughly) ( strong scattering ) θ d proportional to λ 2 for single-sized sized blobs (or a Gaussian size distribution) λ 2.2 for a Kolmogorov power spectrum of blob sizes

Scattering Effects: Pulse Broadening θ d τ d ~ D θ d2 / 2c λ 4.4 λ D For ETA Crab obs: τ d = 4.4 s (ν( / 38 MHz) -4.4 θ d = 1.4 (ν( / 38 MHz) -2.2 (using Cordes et al. 2004: τ d ~ 0.5 ms @ 0.3 GHz for Crab) (MPIfR Pulsar Group website)

Scattering Effects: Diffractive Scintillation Twinkling Stars twinkle, planets don t. Twinkling requires θ source < θ critical < l / D d so diffraction patterns of different parts of source don t blur each other (l d = characteristic length scale in diffraction pattern; see later) θ source < θ critical well satisfied for pulsars. (Other transient sources?) Then, in strong scattering case: m = σ Ι / <Ι> < > = 1 ( modulation index is unity) Probability (Ι( > S) = e -S/< S/<Ι> Ι < 0.5 <Ι> < > occurs 40% of the time Ι > 2 <Ι> < > occurs 14% of the time (unless instrumental parameters t and/or ν suppress scintillation*)

Scattering Effects: Diffractive Scintillation Scintles seen in dynamic c spectrum t d ~ 10 minutes scintillation illation time scale ν d ~ 2 MHz scintillation illation bandwidth for B0329+54, 810 MHz (Cordes)

Diffractive Scintillation Bandwidth Typical ray path length difference ~ c τ d Typical phase difference ϕ d ~ 2π2 c τ d / λ = 2π ν τ d For ϕ d = (dϕ( d / dν) ν = 2π ν τ d ~ 1 radian get major change in diffraction pattern at observer s plane Therefore ν d ~ 1 / 2πτ2 d For ETA Crab obs: 4.4 ν d ~ 3.6 x 10-5 khz (ν( / 38 MHz) 4.4

Diffractive Scintillation Time Scale Depends on transverse velocity V, scintillation length scale l d l d = λ / θ d (see diagram at right) θ d t d = l d / V = λ / θ d V λ / λ2.2 ν 1.2 Cordes et al. 2004, Crab: 1.2 GHz t d = 20 s ν GHz For ETA Crab obs: 1.2 t d = 0.4 s (ν( / 38 MHz) 1.2 λ l d observer s plane

Diffractive Scintillation: Modulation Index For observations smoothed over t and ν,, the number of scintles expected in one t or ν are approximately (Cordes( and Lazio 1991): N t = 1 + 0.2 t / t d N ν = 1 + 0.2 ν / ν d The observations therefore average over these scintles producing a modulation index m m = 1 / (N( t N ν ) Many scintles in one t and/or one ν will quench diffractive scintillations (m 0)

Scattering Effects: Refractive Scintillation Focusing/defocusing effects of blobs with sizes ~ D θ d m = σ Ι / <Ι> < > ~ 0.05 to 0.3 ν r ~ ν t r ~ l r / V ~ D θ d / V λ 2.2 Recall t d = λ / θ d V and τ d ~ D θ d2 / 2c Therefore t r ~ (D θ d2 / λ) t d ~ 2 τ d ν t d t r ~ 10 8 s (ν( / 38 MHz) -2.2 ~ 3 y (ν / 38 MHz) -2.2

Summary of Observing Parameters ETA design parameters B = 18 MHz, centered on ν = 38 MHz ν = 15 khz (at smallest; therefore 1200 freq. channels at most) t = 66 µs s (at smallest) Propagation t DM delay = 160 s DM 56.8 ν38 ( t DM delay = 170 s across B = 18 MHz) t DM smear = 0.13 s DM 56.8 ν -3 38 ν 15 (>> P, single pulses; ; >> small t) τ d = 4.4 s ν -4.4 38 (>> smallest t; best t ~ a few seconds) ν d = 3.6 x 10-5 khz ν 4.4 38 (<< smallest ν; diffractive scintillations quenched) t d = 0.4 s ν 1.2 38 (irrelevant since diff. scint.. quenched) t r = 3 y ν -2.2 38 (> grant period! Can t worry about it.)