张力 张力 2003 年 10 月 21 日于北京 2003 年 10 月 21 日于北京 gamma-ray luminosity...
TRANSCRIPT
张力 张力 20032003 年年 1010 月月 2121 日于北京日于北京
Gamma-ray Luminosity and Death Lines of Pulsars with Outer Gaps
OutlineOutlineIntroduction The Outer Gap Model Magnetospheric Geometry
X-ray Field in the Magnetosphere
The Fractional Size of an Outer Gap
High-Energy Gamma-ray LuminosityThe Death lines of Pulsars with Outer
GapsConclusion and Discussion
1.Introduction1) Observations of High-Energy Emission from Rot
ation-Powered Pulsars
History: SAS 2, COSB(1970’s-1980’s). EGRET (1990’s)
Coming satellite: GLAST
The Observations of Gamma-ray Pulsars
The OSSE/EGRET experiments have detected pulsed signals from eight rotation-powered pulsars.
Nolan et al. 1993, ApJ 409, 697 Crab Matz et al. 1994, ApJ 434, 288 B1509-58*
Kanbach et al. 1994, A&A 289, 855 Vela Mayer-Hasselwander et al. 1994, ApJ 421, 276 Geminga
Ramanamurthy et al. 1995, ApJ 447, L109 B1951+32 Thompson et al. 1996, ApJ 465, 385 B1706-44 Fierro et al. 1998, ApJ 494, 734 Crab, Vela, Geminga Thompson et al. 1999, ApJ 516, 297 B1055-52 Kaspi et al. 2000, ApJ 528, 445 B1046-58
Pulses at multi-wavebands
Energy spectra of gamma-ray pulsars
2) Models for High-Energy Emission from 2) Models for High-Energy Emission from PulsarPulsar
There are two kinds of models for high-energy emission from pulsars:(1) polar cap models (Harding et al. 1978, ApJ 225, 226; Daugherty & Harding 1982 ApJ 252, 337;1996 ApJ 458, 278; Zhang & Harding, 2000, ApJ; Sterner et al. 1995, ApJ 445, 736).(2) Outer gap models(Cheng, Ho, Ruderman ,1986, ApJ 300, 500; 300, 522; Chiang & Romani 1994, ApJ 436, 754;Romani, 1996, ApJ 470, 469, Zhang & Cheng 1997, ApJ 487 370; Hirotani & Shibata 2001, MNRAS 325, 1228)
Schematic geometry of polar and outer gaps. Dark solid regions are thin gaps of younger pulsars. Hatched regions are thick gaps of older pulsars
3) Outer gaps:charge density
surrounds a rotating NS with B and . The plasma is corotating with the NS within RL=c/ . In the corotating
region, E||= EB/B ~0. But, the flows of the plasma along open field lines will results in some plasma void regions (where 0) in the vicinity of null charge surfaces ( B=0). In such charge deficient regions, which are called outer gaps, E|| 0 is sustained,e-/e+ can be accelerated to relativistic energies and the subsequent high-energy -ray emission and pair production can maintain the current flow in the magnetosphere.
5)Motivations:Observation indicates (Thompson et al. 2001): L L ½ sd .New polar gap models (e.g. Zhang &Harding 2000; Harding et al. 2002): L L ½ sd for Lsd > Lbreak sd, L L sd for Lsd < Lbreak sd,where Lbreak sd,= 5 x 1033 P-1/2 erg/s.For previous outer gap models: L ~ f3 L sd f B -13/20 P33/20 (CHR II) f B -4/7 P26/21 (ZC97)ZC97 model predicts L (B/P) 0.3, e.g, the ratio of (B/P) 0.3 for PSR B1055-52 to that for Geminga is~ 0.9. But, the observed ratio ~8 (Kaspi et al. 2000). Therefore, other physics quantities shouldbe taken into account in order to explain the observed data.
We re-study the gamma-ray emission from the outer gaps of the rotation-powered pulsars. We take the magnetosphere geometry into account and show that the fractional size of the outer gap is a function of period, magnetic field, radial distance to the neutron star and magnetic inclination angle.
2. The Outer Gap Modele+ and e- are accelerated by E||
Relativistic e+/e- emit gamma-rays viaSynchro-curvature, and IC processes
Soft X-rays from stellar surface are produced by the collision of return current with NS. Gamma-rays collide with these soft photons to materialize as pairs in the accelerator to maintain the outer gap.
Based on ZC97 model, 2D and 3D models were developed
CrabCrab
The spectra of Crab
Emission projection and pulseprofile for Geminga parameter.Panel A: Photon emission from thepulsar as a function of phase.Panel B: Pulse profile.
Phase-resolved and phase-averaged gamma-ray spectra of the Geminga pulsar
Geminga Geminga
Magnetospheric Geometry
For an oblique magnetic dipole rotator with an angular velocity and the magnetic moment vector , let its spin axis be along the Oz axis, be in the plane xOz and be the angle between and .
= BpR3/2.
Effects of Inclination angle is not included in ZC97 model
New modelNew model:
It is believed that the outer gap is extended from its inner boundary to the light cylinder (CHR I). For the oblique magnetic dipole rotator, outer boundary is determined by (Kapoor & Shukre 1998)
Inner boundary:
The Goldreich-Julian current
X-ray Field in the Magnetosphere
Observed X-ray spectra: soft (thermal) + hard (non-thermal) X-rays thermal X-rays.
Thermal X-ray emission from neutron star cooling
Zhang & Harding (2000)
Hibschman & Arons (2001)
X-ray emission from polar cap heating
Harding and Muslimov (2001)
X-ray emission from outer gap heating
In the outer gap models, part of the relativistic particles from the outer gap will collide the stellar surface, producing the thermal X-rays. These relativistic inflowing particles from the outer gap radiate away much of their energy before reaching the polar cap (Zhang & Cheng 1997, Zhu et al. 1997; Wang et al. 1998; Cheng & Zhang 1999).
Average energy of X-rays
Two possible cases:NS cooling+ pc heating; og heating
Assuming these X-ray can be approximated as the black-body, their spectrum can be expressed as
NS cooling + pc heating:
Outer gap heating
The Fractional Size of an Outer Gap
In two dimensional geometry, the parallel electric field in the outer gap can be approximated as (ZC97)
Lesch et al. 1998
Typical energy of the gamma-rays in the outer gap :
Inside the outer gap, pair production condition :
X-rays are produced by the NS cooling and pc heating:
X-rays are produced by the outer gap heating:
In order to explain the average properties of high-energy photon emission from the outer gap, we assume that high-energy emission at a average radius <r> represents the typical emission of high-energy photons from a pulsar. The average radius is given by
Corresponding fractional size is
where f0 (P, B) = 5.5 P 26/21 B -4/712 is the fractional
size of outer gap by ignoring the effect of inclination angle (Zhang & Cheng 1997)
Fig.1 Variation of the fractional size of the outer gap with the magnetic inclination angle for some typical pulsar parameters.
3. High-Energy Gamma-ray Luminosity
In our model, L for each gamma-ray pulsar depends on P, B and . However, values are not known well. Once f(<r>,P,B) for a pulsar is estimated, L is
We find out statistically the relation between L and Lsdfor the canonical pulsars using Monte Carlo method. The details of this Monte Carlo method is given by Cheng & Zhang (1998) and Zhang et al. (2000).
Fig.2 The change of L with Lsd in the simulated -ray pulsar. In our simulation, we have used the EGRET threshold as the minimumdetectable -ray energy flux. Open circles and shaped circles are the model radio-quiet and radio-loud -ray pulsars respectively.
Radio-loud : L L 0.30 sd
Radio-quiet : L L 0.38 sd
Fig.3 L /L 0 versus L in the -ray pulsar population predicted by our outer gap model. We have used the EGRET threshold as the
minimum detectable -ray energy flux. Open circles are the expected data and solid line is the best fit. For comparison, we show the result given by Zhang & Cheng (1997) as a dashed line.
Fig. 4 L versus Lsd. Solid circles with error bar are the observed data given by Thompson et al. (2001).
Solid line:lg L 20.42+0.38lg Lsd
Dashed line: lg L 3.25+0.30lg Lsd
4. The Death lines of Pulsars with Outer Gaps
We now consider the condition which the outer gap of a pulsar exists. If the fractional size of the outer gap at rinis larger than unity, then the outer gap would not exist, I.e. f(rin)=1 give the death lines.
NS cooling+pc heating (Zhang & Harding 2000)
A1= 12.87-3.16lg Gpc ()A2= 12.92-1.17lg Gpc ()
Outer gap heating:
It was generally believed that the parent distribution of the magnetic inclinations satisfy an uniform distribution (Gunn & Ostriker 1970; Gil & Han 1996). But recent study by using polarization data of the radio pulsarsindicate that the parent distribution of the magnetic inclinations satisfies a cosine-like distribution (Tauris & Manchester 1998). Therefore, we estimate the average value of f(rin) in these two possible parent distributions of the magnetic inclinations, i.e.
For the uniform distribution, <Gpc()>~ 0.43 and <G()=0.38.
For cosine distribution,
NS+pc
NS+pc
OG
OG
Fig.5 Death lines of the pulsars with outer gaps. It is assumed that X-rays are produced by the neutron star cooling and polar cap heating. Two cases of the inclination angle distributions are considered: (i)an uniform distribution and (ii)a cosine distribution.
Fig.6 Death lines of the pulsars with self-sustained outer gaps. The observed data are taken from see website http://www.atnf.csiro.au/research/catalogue/.
4. Conclusion and Discussion
We studied the outer gap size, gamma-ray luminosity and death lines of gamma-ray emission of the pulsars with outer gaps when the geometry of dipole magnetic field is taken into account.f(P, B, <r>()) is not only the function of P and B, but also the function of <r>, which depends on . The outer gap will not exist if f(r, ) > 1. For all gamma-ray pulsars with self-sustained outer gaps simulated by using Monte Carlo method, L L sd , where the value of ~0.38 for EGRET sensitivity . The death lines of the pulsars with outer gaps in the two possible X-ray fields are given and thecomparison with the observed data are considered.
谢谢!谢谢!