Magnetars: SGRs and AXPs
Magnetic field distribution
1805.01680 (taken from Olausen, Kaspi 2014)
Fields from P-Pdot using magneto-dipole formula
Magnetars in the Galaxy
◼ ~25 SGRs and AXPs, plus 6 candidates, plus radio
pulsars with high magnetic fields (about them see
arXiv: 1010.4592)…
◼ Young objects (about 103-5 year).
(see a review in arXiv:1503.06313 and the catalogue description in 1309.4167)
Catalogue: http://www.physics.mcgill.ca/~pulsar/magnetar/main.html
1703.00068
Spatial distribution
Scale height ~20 pc
The first parallax for magnetar XTE J1810−197
was measured due to radio observations, 2008.06438.
1907.13267
Birth rate of magnetars
Recent modeling favours somehow larger values: 1903.06718.
However, the result is model dependent.
In particular, it depends on the model of field decay.
Fraction of magnetars among NSs is uncertain.
Typically, the value ~10% is quoted (e.g. 0910.2190).
This is supported observationally and theoretically.
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
N49 – supernova
remnant in the
Large Magellanic
cloud
(e.g. G. Vedrenne
et al. 1979)
Magnetar on pension?
2003.11730
The source is not active since 1979.
Just in 2020 it was for the first time detected at E>10 keV in quiescence.
Main types of activity of SGRs
◼ Weak bursts. L<1042 erg/s
◼ Intermediate. L~1042–1043 erg/s
◼ Giant. L<1045 erg/s
◼ Hyperflares. L>1046 erg/s
See the review in
Rea, Esposito
1101.4472
Power distribution is similar
to the distribution of earthquakes
in magnitude
Normal bursts of SGRs and AXPs
◼ Typical weak bursts of
SGR 1806-29,
SGR 1900+14 and of
AXP 1E 2259+586
detected by RXTE
(from Woods, Thompson 2004)
Outbursts
Individual flares often appear
during period of activity.
They are called outbursts.
SGR J1935+2154 is
the most recurring transient
during last years.
127 bursts in 2-3 years.
This amount allows
detailed statistical studies.
2003.10582
See the review in
Rea, Esposito
1101.4472
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)
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
Hyperflare of SGR 1806-20
◼ 27 December 2004 A
giant flare from SGR
1806-20 was detected
by many satellites:
Swift, RHESSI, KonusWind,
Coronas-F,
Integral, HEND, …
◼ 100 times brighter than
any other!
Palmer et al.
astro-ph/0503030
Integral
RHESSI
C
O
R
O
N
A
S
-
F
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 – see the latest
data in arXiv: 1103.0006
Konus observations
Mazets et al. 2005
The myth about Medusa
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 EventSpring
2003
Spring
2004
Autumn
2003 Autumn
2004
Bursts / day (IPN)
20-60 keV flux (INTEGRAL IBIS)
Mereghetti et al 2005
SGR 1806-20 - II
◼ Four XMM-Newton observations before the burst
(the last one 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)
Growing twist
(images from Mereghetti arXiv: 0804.0250)
Anomalous X-ray pulsars
Identified 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
Anomalous X-ray Pulsars: main properties
◼ About fourteen sources known:
1E 1048.1-5937, 1E 2259+586, 4U 0142+614,
1 RXS J170849-4009, 1E 1841-045, 3XMM J185246.6+003317,
CXOU 010043-721134, AX J1845-0258,
CXOU J164710-455216, XTE J1810-197,
1E 1547.0-5408, PSR J1622-4950, CXOU J171405.7-381031
◼ Persistent X-ray emitters, L ≈ 1034 -1035 erg/s
◼ Pulsations with P ≈ 2 -10 s (0.33 sec for PSR 1846)
◼ Large spindown rates, Ṗ/P ≈ 10-11 s-1
◼ No evidence for a binary companion, association with a SNR in
several cases
Known AXPs
CXO 010043-7211 8.0
4U 0142+61 8.7
1E 1048.1-5937 6.4
1E 1547.0-5408 2.1
CXOU J164710-4552 10.6
1RXS J170849-40 11.0
XTE J1810-197 5.5
1E 1841-045 11.8
AX J1845-0258 7.0
PSR J1622-4950 4.3
CXOU J171405.7-381031 3.8
1E 2259+586 7.0
Sources Periods, s
http://www.physics.mcgill.ca/~pulsar/magnetar/main.html
Are SGRs and AXPs brothers?
◼ Bursts of AXPs
(more than half burst)
◼ Spectral properties
◼ Quiescent periods of
SGRs (0525-66 since
1983)
Gavriil et al. 2002
Bursts of the AXP 1E1547.0-5408
0903.1974
Bursts of the AXP 1E1547.0-5408
0903.1974
Some bursts have pulsating tails with spin period.
Unique AXP bursts?
(Woods et al. 2005 astro-ph/ astro-ph/0505039)
Bursts from AXP J1810-197. Note a long exponential tail with pulsations.
R < ctrise ≈ 300 km: a compact object
Pulsed X-ray emission: a neutron star
A Tale of Two Populations ?
SGRs: bursting
X/γ-ray sources
Single class of
objects
AXPs: peculiar class
of steady X-ray
sources
A Magnetar
Pulse profiles
of SGRs and AXPs
Hard X-ray Emission
Mereghetti et al 2006
INTEGRAL revealed
substantial emission in
the 20 -100 keV band
from SGRs and APXs
Hard power law tails
with Г ≈ 1-3
(see 1712.09643 about
spectral modeling)
Hard emission pulse
SGRs and AXPs
SGRs and AXPs soft X-ray Spectra
◼ 0.5 – 10 keV emission is well represented by
a blackbody plus a power law
SGR 1806-20 (Mereghetti et al 2005)
AXP 1048-5937 (Lyutikov & Gavriil 2005)
See also discussions in:
arXiv: 1001.3847, 1009.2810
SGRs and AXPs soft 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 is mostly associated with
the non-thermal component
◼ About polarization see 2001.07663
Magnetar spectra in comparison
1503.06313
1903.05648
Hard tails can be due to upscattering of
thermal photons from the surface in the magnetosphere,
see e.g. 2012.10815.
Magnetars can behave like radio pulsars
1908.04304
XTE J1810−197
Was the first magnetar
to show PSR-like
radio emission.
Activity in radio
is transient.
Shows short bursts
which resemble FRBs
(but are much weaker).
Young and fast magnetar with radio
Swift J1818.0–1607
Discovered in March 2020.
Spin period 1.36 s.
Characteristic age 240 yrs.
Radio pulses.
Weak quiescent emission.
2004.04083 About first radio detection of this source see
http://www.astronomerstelegram.org/?read=13577
Suppression of radio
during bursts
1710.03718
PSR J1119−6127
The rotationally powered radio emission
shuts off coincident with the occurrence
of multiple X-ray bursts.
Galactic center magnetar
SGR/PSR J1745−2900
1802.07884
1307.6331
Radio pulsations detection in 2013
The largest dispersion measure
and rotation measure among PSRs.
<1 pc from Sgr A*
Evolution of the Galactic center
magnetar after the outburst in 2013
2003.07235
Low-field magnetars
See a review in arXiv:1303.6052
SGR 0418+5729 and Swift J1822.3–160
The first low-field magnetar
1303.5579
Only after ~3 years of observations
it was possible to detect spin-down.
The dipolar field is ~6 1012 G.
The dipolar field could decay, and
activity is due to the toroidal field.
SGR 0418+5729
Large field (at last) ... But multipoles!
1308.4987
XMM-Newton observations allowed to detect a spectral line
which is variable with phase.
If the line is interpreted as a proton cyclotron line,
then the field in the absorbing region is 2 1014 – 1015 G
SGR 0418+5729
1308.4987
a. Spectrum for the phases 0.15-0.17
and the best-fit model (red) for the
phase averaged spectrum
b. Residuals for this model
c. Residuals for the model with a line
d. Residuals for the
BB+powel law model (no line)
Magnetars and supernovae
KASEN & BILDSTEN (2010)
With large field and short spin a newborn NS
can contribute a lot to the luminosity of a SN.
Parameters needed
About young millisecond magnetars see also 1906.02610, and a review in 2103.10878.
Magnetars and GRBs
1804.08652
Papers to read
• Woods, Thompson astro-ph/0406133 – old classical review
• Mereghetti arXiv: 0804.0250
• Rea, Esposito arXiv: 1101.4472 - outbursts
• Turolla, Esposito arXiv: 1303.6052 - Low-field magnetars
• Mereghetti et al. arXiv: 1503.06313
• Turolla, Zane, Watts arXiv: 1507.02924 – Big general review
• Beloborodov, Kaspi arXiv: 1703.00068
• Esposito et al. arXiv: 1803.05716
• Coti Zelati et al. arXiv: 1710.04671 – outbursts
• Gourgouliatos, Esposito 1805.01680 – magnetic fields
• Dall’Osso, Stella 2103.10878 - millisecond magnetars