lecture 4. magnetars: sgrs and axps
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Lecture 4. Magnetars: SGRs and AXPs. Sergei Popov (SAI MSU). Phenomenology of NSs. Trento. August 2007. Magnetars. dE/dt > dE rot /dt By definition: The energy of the magnetic field is released P-Pdot Direct measurements of the field (Ibrahim et al.). Magnetic fields 10 14 –10 15 G. - PowerPoint PPT PresentationTRANSCRIPT
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Lecture 4.Magnetars: SGRs and AXPs
Sergei Popov (SAI MSU)
Phenomenology of NSs. Trento. August 2007
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Magnetars
dE/dt > dErot/dt By definition: The energy of the magnetic field is released P-Pdot Direct measurements of the field (Ibrahim et al.)
Magnetic fields 1014–1015 G
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Known magnetarsSGRs 0526-66 1627-41 1806-20 1900+14 +candidates
AXPs CXO 010043.1-72 4U 0142+61 1E 1048.1-5937 CXOU J164710.3- 1 RXS J170849-40 XTE J1810-197 1E 1841-045 AX J1844-0258 1E 2259+586
(СТВ 109)
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Magnetars Strong convection in a rapidly rotating (P ~ 1
ms) newborn neutron star generates a very strong magnetic field via dynamo action
Magnetars: neutron stars with surface field B > 10 BQED ~ 4 x1014 G (Duncan & Thomson 1992; Thomson & Duncan 1993)
Rapid spin-down due to magneto-dipolar losses.
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Magnetars on the Galaxy
4 SGRs, 9 AXPs, plus candidates, plus radio pulsars with high magnetic fields…
Young objects (about 104 year). Probably about 10% of all NSs.
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Soft Gamma Repeaters - I Rare class of sources, 4 confirmed (+ 1): SGR
1900+14, SGR 1806-20, SGR 1627-41 in the Galaxy and SGR 0526-66 in the LMC
Strong bursts of soft γ-/hard X-rays: L ~ 1041 erg/s, duration < 1 s
Bursts from SGR 1806-20 (INTEGRAL/IBIS,,Gőtz et al 2004)
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Historical notes 05 March 1979. The ”Konus” experiment & Co. Venera-11,12 (Mazets et al., Vedrenne et al.) Events in the LMC. SGR 0520-66. Fluence: about 10-3 erg/cm2
Mazets et al. 1979
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N49 – supernovaremnant in theLarge Magellaniccloud(e.g. G. Vedrenne et al. 1979)
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Main types of activity of SGRs Weak bursts. L<1041 erg/s Intermediate. L=1041–1043 erg/s Giant. L<1045 erg/s Hyperflares. L>1046 erg/s
See the review inWoods, Thompsonastro-ph/0406133
Power distribution is similarto the distribution of earthquakes
in magnitude
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Normal bursts of SGRs and AXPs Typical bursts of SGR 1806-29, SGR 1900+14 and of AXP 1E 2259+586
detected by RXTE (from the review by Woods, Thompson,
astro-ph/0406133)
(from Woods, Thompson 2004)
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Intermediate SGR bursts
Examples of intermediate bursts.
The forth (bottom right) is sometimes defined as a giant burst (for example by Mazets et al.).
(from Woods, Thompson 2004)
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Giant flare of the SGR 1900+14 (27 August 1998) Ulysses observations
(figure from Hurley et al.) Initial spike 0.35 s P=5.16 s L>3 1044 erg/s ETOTAL>1044 erg
Hurley et al. 1999
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SGRs: periods and giant flares 0526-66 1627-41 1806-20 1900+14
P, s Giant flares
8.0
6.4
7.5
5.2
5 March 1979
27 Aug 1998
27 Dec 2004
18 June 1998 (?)
See the review inWoods, Thompsonastro-ph/0406133
New result:oscillationsin the “tail”.“Trembling”of the crust(Israel et al. 2005,Watts and Strohmayer 2005).
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Soft Gamma Repeaters: main properties Energetic “Giant Flares” (GFs, L ≈ 1045-1047 erg/s)
detected from 3 sources No evidence for a binary companion, association
with a SNR in one case Persistent X-ray emitters, L ≈ 1035 erg/s Pulsations discovered both in GFs tails and
persistent emission, P ≈ 5 -10 s Huge spindown rates, Ṗ/P ≈ 10-10 ss-1
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Anomalous X-ray pulsarsIdentified as a separate group in 1995. (Mereghetti, Stella 1995 Van Paradijs et al.1995)
• Similar periods (5-10 sec)• Constant spin down• Absence of optical companions• Relatively weak luminosity• Constant luminosity
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Anomalous X-ray Pulsars: main properties Eight sources known (+ 1 transient): 1E 1048.1-5937, 1E 2259+586, 4U 0142+614, 1
RXS J170849-4009, 1E 1841-045, CXOU 010043-721134, AX J1845-0258, CXOU J164710-455216 (+ XTE J1810-197)
Persistent X-ray emitters, L ≈ 1034 -1035 erg/s Pulsations with P ≈ 5 -10 s Large spindown rates, Ṗ/P ≈ 10-11 ss-1
No evidence for a binary companion, association with a SNR in three cases
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Known AXPs CXO 010043.1-72 8.0
4U 0142+61 8.7
1E 1048.1-5937 6.4
CXOU J164710.2- 10.6
1RXS J170849-40 11.0
XTE J1810-197 5.5
1E 1841-045 11.8
AX J1845-0258 7.0
1E 2259+586 7.0
Sources Periods, s
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Are SGRs and AXPs brothers? Bursts of AXPs Spectral properties Quiescent periods of
SGRs (0525-66 since 1983)
Gavriil et al. 2002
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R < ctrise ≈ 300 km: a compact objectPulsed X-ray emission: a neutron star
A Tale of Two Populations ?
SGRs: bursting X/γ-ray sources
Single class ofobjects
AXPs: peculiar class of steady X-ray sources
A Magnetar
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Pulse profilesof SGRs and AXPs
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SGRs and AXPs
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Hard X-ray EmissionMereghetti et al 2006INTEGRAL revealed
substantial emission in the 20 -100 keV band from SGRs and APXs
Hard power law tails with Г ≈ 1-3, hardeningwrt soft X-ray emissionrequired in AXPs Hard emission pulsed
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SGRs and AXPs X-ray Spectra 0.5 – 10 keV emission well represented by a
blackbody plus a power law
SGR 1806-20 (Mereghetti et al 2005)
AXP 1048-5937 (Lyutikov & Gavriil 2005)
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SGRs and AXPs X-ray Spectra
kTBB ~ 0.5 keV, does not change much in different sources
Photon index Г ≈ 1 – 4, AXPs tend to be softer
SGRs and AXPs persistent emission is variable (months/years)
Variability mostly associated with the non-thermal component
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Hardness vs Spin-down Rate
Harder X-ray spectrum
Larger Spin-down rate
Correlation between spectral hardness and spin-down rate in SGRs and AXPs (Marsden & White 2001)
Correlation holds also for different states within a single source (SGR 1806-20, Mereghetti et al 2005; 1 RXS J170849-4009, Rea et al 2005)
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Theory of magnetars
Thompson, Duncan ApJ 408, 194 (1993)
Convection in a protoNS results in generation of strong magnetic field
Reconfiguration of the magnetic field structure
(Figures from the web-page of Duncan)
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Generation of the magnetic field
The mechanism of the magnetic field generation is still unknown.
Turbulent dynamo
α-Ω dynamo (Duncan,Thompson) α2 dynamo (Bonanno et al.) or their combination
In any case, initial rotation of aprotoNS is the critical parameter.
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Strong field via flux conservation
There are reasons to suspect that the magnetic fields of magnetars are not due to any kind of dynamo mechanism, but just due to flux conservation:
1. Study of SNRs with magnetars (Vink and Kuiper 2006). If there was a rapidly rotating magnetar then a huge energy release is inevitable. No traces of such energy injections are found.
2. There are few examples of massive stars with field strong enough to produce a magnetars due to flux conservation (Ferrario and Wickramasinghe 2006)
Still, these suggestions can be criticized
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Alternative theory Remnant fallback disc Mereghetti, Stella 1995 Van Paradijs et al.1995 Alpar 2001 Marsden et al. 2001 Problems ….. How to generate strong bursts? Discovery of a passive disc in one of AXPs (Wang et al. 2006). New burst of interest to this model.
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Magnetic field estimates Direct measurements of
magnetic field (cyclotron lines)
Spin down Long spin periods
Ibrahim et al. 2002
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SGR 1806-20 - I
SGR 1806-20 displayed a gradual increase in the level of activity during 2003-2004 (Woods et al 2004; Mereghetti et al 2005)
enhanced burst rate increased persistent luminosity
The 2004 December 27 EventSpring2003
Spring2004
Autumn2003 Autumn
2004
Bursts / day (IPN)
20-60 keV flux (INTEGRAL IBIS)
Mereghetti et al 2005
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SGR 1806-20 - II Four XMM-Newton observations (last on October
5 2004, Mereghetti et al 2005) Pulsations clearly detected in all observations Ṗ ~ 5.5x10-10 s/s, higher than the “historical” value Blackbody component in addition to an absorbed
power law (kT ~ 0.79 keV) Harder spectra: Γ ~ 1.5 vs. Γ ~ 2 The 2-10 keV luminosity almost doubled (LX ~ 1036
erg/s)
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Twisted Magnetospheres – I
The magnetic field inside a magnetar is “wound up”
The presence of a toroidal component induces a rotation of the surface layers
The crust tensile strength resists A gradual (quasi-plastic ?) deformation of the
crust The external field twists up (Thompson, Lyutikov &
Kulkarni 2002) Thompson & Duncan 2001
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A Growing Twist in SGR 1806-20 ? Evidence for spectral
hardening AND enhanced spin-down
Γ-Pdot and Γ-L correlations
Growth of bursting activity
Possible presence of proton cyclotron line only during bursts
All these features are consistent with an increasingly twisted magnetosphere
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Conclusions & Future Developments Twisted magnetosphere model, within magnetar
scenario, in general agreement with observations Resonant scattering of thermal, surface photons
produces spectra with right properties Many issues need to be investigated further
Twist of more general external fields Detailed models for magnetospheric currents More accurate treatment of cross section including QED
effects and electron recoil (in progress) 10-100 keV tails: up-scattering by (ultra)relativistic (e±)
particles ? Create an archive to fit model spectra to observations (in
progress)
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Hyperflare of SGR 1806-20
27 December 2004 A giant flare from SGR 1806-20 was detected by many satellites: Swift, RHESSI, Konus-Wind, Coronas-F, Integral, HEND, …
100 times brighter than any other!
Palmer et al.astro-ph/0503030
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Integral
RHESSI
CORONAS-F
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27 Dec 2004: Giant flare of the SGR 1806-20
Spike 0.2 s Fluence 1 erg/cm2
E(spike)=3.5 1046 erg L(spike)=1.8 1047 erg/s Long «tail» (400 s) P=7.65 s E(tail) 1.6 1044 erg Distance 15 kpc
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Konus observations.SGR 1806-20 27 Dec 2004
Mazets et al. 2005
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The myth about Medusa
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SGRs: monitoring and extraG
[D. Frederiks et al. astro-ph/0609544]
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What is special about magnetars?
Westerlund 1
Link withLink with massive starsmassive starsThere are reasons to suspect that magnetars are connected to massive stars.
Link to binary starsThere is a hypothesis that magnetars are formed in close binary systems (astro-ph/0505406).
The question is still on the list.
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Neutron stars and massive progenitors
(astro-ph/0611589)
AXP in Westerlund 1 most probably hasa very massive progenitor >40 Msolar.
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Are there magnetors in binaries?
Magnetor
At the moment all known SGRs and AXPs are isolated objects.About 10% of NSs are expected to be in binaries.The fact that all known magnetars are isolated can be relatedto their origin, but this is unclear.
If a magnetar appears in a very close binary system, thenan analogue of a polar can be formed.The secondary star is insidethe huge magnetosphere of a magnetar.This can lead to interestingobservational manifestations.
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Binaries with magnetars - magnetors
Can RCW 103 be a prototype?6.7 hour period (de Luca et al. 2006)
RCW 103
Possible explanations:1. Magnetar, spun-down by disc2. Double NS system3. Low-mass companion + magnetar= magnetor