Scuola nazionale de Astrofisica Radio Pulsars 1: Pulsar Basics
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Scuola nazionale de AstrofisicaRadio Pulsars 1: Pulsar Basics
Dick ManchesterAustralia Telescope National Facility, CSIRO
Outline• Rotating neutron stars, SN associations, Binaries, MSPs• Pulse profiles, polarisation, beaming, RVM model• Pulse fluctuations: drifting, nulling, mode changing
Basic References
• Manchester & Taylor 1977 “Pulsars”• Lyne & Smith 2005 “Pulsar Astronomy”• Lorimer & Kramer 2005 “Handbook of Pulsar Astronomy”
Books
Review Articles• Rickett 1990, ARAA - Scintillation• Science, 23 April 2004 - Three articles: NS, Isolated Pulsars, Binary Pulsars• Living Reviews articles: (http://relativity.livingreviews.org/Articles)
• Stairs 2003: GR and pulsar timing• Lorimer 2005: Binary and MS pulsars• Will, 2006: GR theory and experiment
• SKA science: New Astron.Rev. 48 (2004)• Cordes et al.: Pulsars as tools• Kramer et al.: Strong-field tests of GR
The sound of a pulsar:
Jocelyn Bell and Tony Hewish Bonn, August 1980
The Discovery of Pulsars
Spin-Powered Pulsars: A Census
• Number of known pulsars: 1765
• Number of millisecond pulsars: 170
• Number of binary pulsars: 131
• Number of AXPs: 12
• Number of pulsars in globular clusters: 99*
• Number of extragalactic pulsars: 20
Data from ATNF Pulsar Catalogue, V1.25 (www.atnf.csiro.au/research/pulsar/psrcat; Manchester et al. 2005)
* Total known: 129 in 24 clusters (Paulo Freire’s web page)
Pulsar Model
(Bennet Link)
• Rotating neutron star• Light cylinder RLC = c/= 5 x 104 P(s) km •Charge flow along open field lines• Radio beam from magnetic pole (in most cases)• High-energy emission from outer magnetosphere• Rotation braked by reaction to magnetic-dipole radiation and/or charge acceleration:
= -K -3
• Characteristic age: c = P/(2P)
• Surface dipole magnetic field: Bs ~ (PP)1/2
..
.
Pulsar Formation• ~30 young pulsars associated with SNR• Core of red giant collapses when its mass exceeds “Chandrasekhar Mass”• Energy release ~ 3GM/5R2 ~ 3 x 1053 erg ~ 0.1 Mc2
• Kinetic energy of SNR ~ 1051 erg; 99% of grav. energy radiated as neutrinos and anti-neutrinos• Asymmetry in neutrino ejection gives kick to NS• Measured proper motions: <V2D> = 211 km s-1
• <V3D> = 4<V2D>/ = 2<V1D> for isotropic velocities
(Hobbs et al. 2005)
Guitar Nebula
PSR B2224+65
(Cordes et al. 2003)
ESO-VLT
Neutron Stars• Formed in Type II supernova explosion - core collapse of massive star
• Diameter 20 - 30 km
• Mass ~ 1.4 Msun
(Stairs 2004)
(MT77)
(Lattimer & Prakash 2004)
P vs P.
Galactic disk pulsars
ATNF Pulsar Catalogue(www.atnf.csiro.au/research/pulsar/psrcat)
• Most pulsars have P ~ 10-15
• MSPs have P smaller by about 5 orders of magnitude
• Most MSPs are binary
• Only a few percent of normal pulsars are binary
• AXPs are slow X-ray pulsars with very strong fields - “magnetars”
• Some young pulsars are only detected at X-ray or -ray wavelengths
..
Pulsar Recycling• Young pulsars live for 106 or 107 years• MSPs have c 109 or 1010 years and most are binary• Accretion from an evolving binary companion leads to:
Increased spin rate for NS - angular momentum transferred from orbit to NS Decreased Bs - mechanism not understood. Could be simple “burial” of field by accreted matter• Minimum spin period: Pmin ~ (B9)6/7 (M/MEdd)-3/7
• Short-period MSPs from low-mass binary companions - long evolution time • Recycling is very effective in globular clusters - more than half of all MSPs in globular clusters: 22 in 47 Tucanae, 33 in Terzan 5 (Ransom et al. 2005, Friere 2007)• Old NS in core of cluster captured by low-mass stars and then recycled• About 30% of MSPs are single - what has happened to companion?
Blown away by relativistic wind from pulsar - ? Lost in 3-body encounter - only in core of globular cluster
47 Tucanae
. .
Pulsar Energetics
Spin-down Luminosity:
Radio Luminosity:
• For a typical pulsar, P = 1s and P = 10-15, Bs ~ 108 T or 1012 G.
• Typical electric field at the stellar surface E ~ RBs/c ~ 109 V/cm
• Electrons reach ultra-relativistic energies in < 1 mm.
• Emit -ray photons by curvature radiation. These have energy >> 1 MeV and hence decay into electron-positron pairs in strong B field.
• These in turn are accelerated to ultra-relativistic energies and in turn pair-produce, leading to a cascade of e+/e- pairs.
• Relativistic pair-plasma flows out along ‘open’ field lines.
• Instabilities lead to generation of radiation beams at radio to -ray energies.
Pulsar Electrodynamics
Cheng et al. (1986); Romani (2000)
Rotating neutron-star model: magnetospheric gaps
Inner (polar cap) gap
Outer gaps
Regions of particle acceleration!
.B = 0
Coherent Radio Emission• Source power is very large, but source area is very small• Specific intensity is very large• Pulse timescale gives limit on source size ~ ct• Brightness temperature: equivalent black-body temperature in Rayleigh-Jeans limit
Radio emission must be from coherent process!
Frequency Dependence of Mean Pulse Profile
Phillips & Wolsczcan (1992)
• Pulse width generally increases with decreasing frequency.
• Consistent with ‘magnetic-pole’ model for pulse emission.
• Lower frequencies are emitted at higher altitudes.
• Emission beamed tangential to open field lines• Radiation polarised with position angle determined by projected direction of magnetic field in (or near) emission region (Rotating Vector Model)
Magnetic-Pole Model for Emission Beam
Mean pulse shapes and polarisation
Lyne & Manchester (1988)
P.A.
Stokes I
Linear
Stokes V
Orthogonal-mode emission – PSR B2020+28
P.A.
Stinebring et al. (1984)
V
I
%L
Mean pulse profile of PSR J0437-4715
Binary millisecond pulsar• P = 5.75 ms• Pb = 5.74 d
Navarro et al. (1997)
Stokes I
Stokes V
Linear
I
L
V
P.A.
• Complex profile, at least seven components
• Complex PA variation, including orthogonal transition
Wide Beams from Young and MS PulsarsCrab
(Ulmer et al. 1994)
PSR B1259-63
• Pulsed (non-thermal) X-ray and -ray profiles from young pulsars have wide “double” shape• Emitted from field lines high in magnetosphere associated with a single magnetic pole • Some young radio pulsars have a similar pulse profile, e.g. PSR B1259-63 • Class of young pulsars with very high (~100%) linear polarisation, e.g. Vela, PSR B0740-28• Radio emission from high in pulsar magnetosphere?• MSPs also have very wide profiles - also single-pole emission from high in magnetosphere?
PSR B0740-28
Other Examples:
Vela
PSR J0737-3039A
PSR B0950+08
Drifting subpulses and periodic fluctuations
PULSE LONGITUDE
Drifting subpulses
Taylor et al. (1975)
Periodic fluctuations
Backer (1973)
(Weltevrede et al. 2006)
• Extensive survey of pulse modulation properties at Westerbork - 187 pulsars• Observations at 1.4 GHz, 80 MHz bw• Modulation indices, longitude-resolved and 2D fluctuation spectra computed• 42 new cases of drifting subpulses
Pulse Modulation
• At least 60% of all pulsars show evidence for drifting behaviour• “Coherent” drifters have large characteristic age, but drifting seen over most of P - P diagram
.
Pulsar Nulling
(Wang et al. 2006)
• Parkes observations of 23 pulsars, mostly from PM survey• Large null fractions (up to 96%) - mostly long-period pulsars• Nulls often associated with mode changing
(Esamdin et al. 2005)
PSR B0826-34• P = 1.848 s, pulsed emission across whole of pulse period• In “null” state ~80% of time• 5-6 drift bands across profile, variable drift rate with reversals• Weak emission in “null” phase, ~2% of “on” flux density• Different pulse profile in “null” phase:
Null is really a mode change.
On
“Null”
PSR B1931+24 - An extreme nuller
(Kramer et al. 2006)
• Quasi-periodic nulls: on for 5-10 d, off for 25-35 d• Period derivative is ~35% smaller when in null state!• Implies cessation of braking by current with G-J density• Direct observation of current responsible for observed pulses
(Hankins et al. 2003)
Giant Pulses
First observed in the Crab pulsar - discovered through its giant pulses!
Intense narrow pulses with a pulse energy many times that of an average pulse - characterised by a power-law distribution of pulse energies.
• Arecibo observations at 5.5 GHz• Bandwidth 0.5 GHz gives 2 ns resolution• Flux density > 1000 Jy implies Tb > 1037 K!• Highly variable polarisation• Suggests emission from plasma turbulence on scales ~ 1 m
Crab Giant Pulses
(Knight et al. 2006, Kuiper et al. 2004, Rutledge et al. 2004)
PSR J0218+4232
(Cusumano et al. 2003)
PSR B1937+21
Giant Pulses from Millisecond Pulsars• Giant pulses seen from several MSPs with high BLC
• Most also have pulsed non-thermal emission at X-ray energies• Giant pulses occur at phase of X-ray emission
RXTE
BeppoSAX
Radio
Chandra 0.1-10kev
GBT 850 MHz
Transient Pulsed Radio Emission from a Magnetar• AXP XTE J1810-197 - 2003 outburst in which X-ray luminosity increased by ~100• X-ray pulsations with P = 5.54 s observed• Detected as a radio source at VLA, increasing and variable flux density: 5 - 10 mJy at 1.4 GHz (Halpern et al. 2005)
• Within PM survey area, not detected in two obs. in 1997, 1998, S1.4 < 0.4 mJy• Observed in March 2006 at Parkes (Camilo et al. 2006)• Pulsar detected! • S1.4 ~ 6 mJy• Very unusual flat spectrum - individual pulses detected in GBT observations at 42 GHz!
Earlier unconfirmed detections (e.g. Malofeev et al 2005) accounted for by transient and highly variable nature of pulsed emission?
End of Part 1