The Fraction Geminga Alice K. Harding NASA Goddard Space Flight Center

Slides:

Advertisements

Similar presentations

Pulsars Multi-Accelerator Radiation model Peking University.

Advertisements

Gamma-ray pulsars discovery by Fermi Space Observatory Sergei Popov (SAI MSU)

Neutron Stars. Gradual compression of a stellar iron core  trans. [g cm -3 ] CompositionDegen. pressure Remarks Iron nuclei; nonrel. free e - nonrel.

Radio and Gamma-Ray Beams from Pulsars R. N. Manchester CSIRO Astronomy and Space Science Australia Telescope National Facility, Sydney Summary Pulse profiles.

Pulsar High Energy Emission Models: What Works and What Doesn't “Standard” outer magnetosphere models - successes Shortcomings of the models Next steps?

5th Science AGILE Workshop, June Observations of pulsars with MAGIC Marcos López (INFN/Padova) on behalf of the MAGIC collaboration.

Glitches; the Link Between the Typical Radio Pulsars and the Anomalous X- ray Pulsars Jinrong Lin & Shuangnan Zhang, 2003, in preparation Physics department.

Study on polarization of high- energy photons from the Crab pulsar 〇 J. Takata (TIARA-NTHU/ASIAA,Taiwan) H.-K. Chang (NTH Univ., Taiwan) K.S. Cheng (HK.

Pulsars Basic Properties. Supernova Explosion => Neutron Stars part of angular momentum carried away by shell field lines frozen into solar plasma (surface.

The Phase-Resolved Spectra of the Crab Pulsar Jianjun Jia Jan 3, 2006.

Neutron Stars Chandrasekhar limit on white dwarf mass Supernova explosions –Formation of elements (R, S process) –Neutron stars –Pulsars Formation of X-Ray.

Gamma-ray Emission from Pulsar Outer Magnetospheres Kouichi HIROTANI ASIAA/TIARA Aspen workshop on GeV and TeV Sources June 16, 2010 Crab nebula: Composite.

Emmision of the remarkable pulsar B : Continual changes in the subpulse drift rate and in integrated pulse shape, intensity and polarization at frequencies.

Matthew Kerr Stanford University / KIPAC.

EGRET unidentified sources and gamma-ray pulsars I. CGRO mission and the instrument EGRET and it’s scientific goals II. Simple introduction of EGRET sources.

X-ray pulsars through the eyes of INTEGRAL A.Lutovinov, S.Tsygankov (IKI) & the discussion with J.Poutanen, M.Revnivtsev and V.Suleimanov Funasdalen 2008.

Pu, Hung-Yi Institute of Astronomy, National Tsing-Hua University The Effects of Photon Path Bending on the Observed Pulse Profile and Spectra of Surface.

Likely continuous sources for detection by ITF C. Palomba Slides based on a paper appeared in MNRAS, 2005 Isolated neutron stars “Standard” EOS (no quark.

Neutron Stars and Black Holes PHYS390: Astrophysics Professor Lee Carkner Lecture 18.

Pei-Chun Hsu¹, Kouichi Hirotani², and Hsiang-Kuang Chang¹ 1 Department of Physics and Institute of Astronomy, National Tsing Hua University ASIAA/National.

Discovery (?) for new population of isolated neutron star “ Transient radio bursts from rotating neutron star ” M.A. McLaughlin et al., Nat. Feb. 16, 2006.

YERAC On the structure of radio pulsar magnetospheres On the structure of radio pulsar magnetospheres Igor F. Malov, Еlena Nikitina Pushchino Radio.

A THREE-DIMENSIONAL OUTER MAGETOSPHERIC MODEL FOR GAMMA-RAY PULSARS : GEOMETRY, PAIR PRODUCTION, EMISSION MORPHOLOGIES, AND PHASE- RESOLVED SPECTRA K.S.CHENG,

Marcus ZieglerAPS April Meeting Gamma-Ray Pulsars in the GLAST Era Gamma-ray Large Area Space Telescope Marcus Ziegler Santa Cruz Institute for.

High-Energy & Radio Pulsar Population Modeling (++) Maura McLaughlin & Jim Cordes Jodrell Bank Observatory Cornell University December 11, 2001.

The 511 keV Annihilation Emission From The Galactic Center Department of Physics National Tsing Hua University G.T. Chen 2007/1/2.

Gamma-ray emission mechanism in pulsar magnetosphere – electrodynamics and models 徐佩君清大天文所.

Integrated Profile Polarization : Observations and Speculations

1 Arecibo Synergy with GLAST (and other gamma-ray telescopes) Frontiers of Astronomy with the World’s Largest Radio Telescope 12 September 2007 Dave Thompson.

Detection of Giant pulses from pulsar PSR B Smirnova T.V. Pushchino Radio Astronomy Observatory of ASC FIAN Pushchino Radio Astronomy.

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 and Death Lines of Pulsars with Outer Gaps.

Qiao,G.J. Dept. of Astronomy, Peking Univ. Collaborators: Zhang, B.( University of Nevada ), Xu, R.X.(PKU), Han,J.L.(NAOC), Lin,W.P.(SHO),Lee,K.J.(PKU)

The population of pulsars with interpulses and the implications for beam evolution (astro-ph/ ) Patrick Weltevrede & Simon Johnston Low-Frequency.

Radio Observations of X-ray Binaries : Solitary and Binary Millisecond Pulsars Jeong-Sook Kim 1 & Soon-Wook Kim 2  Department of Space Science and Astronomy.

Giant Radio Pulses Radio Properties Mechanism High Energy Properties With Astrosat & LOFT.

Introduction A pulsar magnetosphere can be divided into two zones: The closed zone filled with a dense plasma co-rotating with the neutron star (NS), and.

No Longer! The Double Pulsar Maura McLaughlin West Virginia University 5 April 2012 Collaborators: Kramer (MPiFR), Stairs (UBC), Perera (WVU), Kim (WVU),

Simulations of radio emission from cosmic ray air showers Tim Huege & Heino Falcke ARENA-Workshop Zeuthen,

1 Study on Pulsar Multi-wavelength Emission Hong Guang Wang Center for Astrophysics, Guangzhou University  Introduction  Multi-wavelength emission regions.

What makes pulsars and magnetars radio laud? George Melikidze J. Kepler Institute of Astronomy, University of Zielona Góra Abastumani Astrophysical Observatory,

Institute of Radio Astronomy of NASU, Kharkov

The structure of the pulsar magnetosphere via particle simulation Shinpei Shibata (1), Shinya Yuki (1), Tohohide Wada (2),Mituhiro Umizaki (1) (1)Department.

The Millisecond Pulsar Contribution to the Rising Positron Fraction Christo Venter 34 th ICRC, The Hague, The Netherlands, 30 July – 6 August 2015 Collaborators:

Pulsars: The radio/gamma-ray Connection Prospects for pulsar studies with AGILE and GLAST Synergy with radio telescopes –Timing and follow-up –Radio vs.

AAS, LB 01/06 Press Conf -1 A Plethora of Pulsars Roger W. Romani Stanford University Alice K. Harding GSFC for the Fermi LAT collaboration.

Pulsar Radio Emission Height: PSR B Zhang Hui National Astronomical Observatories, Chinese Academic of Science Sino-German Bilateral Workshop on.

44 th Rencontres de Moriond 1 Blind Period Search gamma-ray pulsar by Fermi-LAT F. Giordano Dipartimento Interateneo di Fisica and INFN Sez. Bari for the.

Neutrinos produced by heavy nuclei injected by the pulsars in massive binaries Marek Bartosik & W. Bednarek, A. Sierpowska Erice ISCRA 2004.

I.F.Malov Pushchino Radio Astronomy Observatory, Lebedev Physical Institute RUSSIA Do «magnetars» really exist? AXPs and SGRs Magnetars (dP.

Peter F. Michelson Stanford University Principal Investigator, Large Area Telescope Collaboration on behalf of the Fermi LAT Collaboration.

Gamma-Ray Emission from Pulsars

Variability and Flares From Accretion onto Sgr A* Eliot Quataert (UC Berkeley) Collaborators: Josh Goldston, Ramesh Narayan, Feng Yuan, Igor Igumenshchev.

Pulsar Acceleration: The Chicken or the Egg? Alice Harding NASA Goddard Space Flight Center.

Low frequency pulsar science, 25 th June Wide profile drifting pulsars : Wide profile drifting pulsars : an elegant way to probe pulsar magnetosphere Low.

Binary Compact Object Inspiral: Rate Expectations Vicky Kalogera with Chunglee Kim Richard O’Shaughnessy Tassos Fragkos Physics & Astronomy Dept.

Damien Parent – Moriond, February PSR J , PSR J , and their cousins -- young & noisy gamma ray pulsars Damien Parent on behalf of.

Polarized Radio Emission within Pulsar Magnetosphere & Pulsar Observation with JMS 66m PengFei Wang PengFei Wang ( 王鹏飞 )NAOC

Observational constraints on theories of pulsations Can we expect to learn something fundamental about neutron stars from their variable radio emission?

Pulsars and PWNs as sources of high-energy particles Jarosław Dyks CAMK, Toruń.

Exploring  -ray emission models using millisecond pulsars in the Second Fermi Pulsar Catalog Alice K. Harding With T. Johnson, C. Venter, E. Grove Latest.

Collaborators Peking University Guojun Qiao, Renxin Xu, Jiguang Lu, Kejia Lee Qian Xuesen Laboratory of Space Technology Yuanjie Du China West Normal University.

A Fan Beam Model for Radio Pulsars Hongguang Wang （王洪光） Center for Astrophysics, Guangzhou University 广州大学天体物理中心 Fast Pulsar Symposium 4.

Pulsars: the Magnetosphere and the γ-ray emission

Predicting the BRAING INDEX OF INTERMITTENT AND NULLING PULSARS

Observation of Pulsars and Plerions with MAGIC

Basic Properties By Dr. Lohse, University of Berlin

Pulsar Polarization studies at low radio frequencies

Pulse Profile Decomposition: Geometry and Beam Patterns of EXO and 4U

Synchro-Curvature Self Compton Radiation

Pulse Nulling and Subpulse Drifting Properties in Pulsars

Presentation transcript:

The Fraction Geminga Alice K. Harding NASA Goddard Space Flight Center Isabelle Grenier CEA-Saclay Peter Gonthier Hope College How many UnID g-ray sources are radio-quiet pulsars? Recent revision of radio and g-ray beam geometries Re-assess fraction of radio-quiet g-ray pulsars (Gemingas) Some cuttoffs observed in EGRET band – the rest implied by TeV upper limits Several MSPs within 100-200 pc which are well above EGRET limits

Traditional radio beam geometry Model of Arzoumanian, Chernoff & Cordes (2002) – 400 MHz Frequency dependent cone width of Mitra & Deshpande (1999) rcore B q

Radio polarization of young pulsars Johnston & Weisberg 2006, Crawford et al. 2003) One of two pulse components Flat polarization swings (RVM) High linear polarization (> 70%) Emission height 1-10% RLC (Kijak & Gil 2003) Wide cone beams b = -30 b = -0.10 b = 30 b = 90 In pulsars with 2 components, second is always stronger and has circular polarization

Studies of 3-peak pulsars Gonthier et al. 2006

Revised radio beam geometry P = 50 ms

Traditional radio beam geometry Model of Arzoumanian, Chernoff & Cordes, 2002 P = 50 ms f

New radio beam - phase plots P = 50 ms, 400 MHz a=300 a=100 a=200 a=400 a=500 a=600 Observer angle z a=700 a=800 a=900 Phase f

Pulsar simulations Evolve neutron stars using population synthesis (Gonthier talk) Assign radio flux <SR>using revised emission cone/cone model RADIO LOUD if <SR> > Smin for any of 9 radio surveys Assign g-ray flux <Fg> using slot gap or outer gap models g-RAY LOUD if <Fg> > Fmin for EGRET, AGILE, GLAST SLOT GAP OUTER GAP We use an independent code to compute the radio and gamma-ray fluxes of the simulated pulsars Low-altitude pair cascade emission not included

Phase plots a RADIO (50 ms, 400 MHz) g-RAY SLOT GAP g-RAY OUTER GAP 300 600 900

Slot gap model Pair-free zone near last open field-line (Arons 1983, Muslimov & Harding 2003, 2004) Slower acceleration Pair formation front at higher altitude Slot gap forms between conducting walls E|| acceleration is not screened

Which pulsars have slot gaps? Harding, Muslimov & Zhang 2002 Only the younger pulsars above the death line for production of curvature radiation pairs will have SLOT GAPS Older pulsars below the death line for production of curvature radiation pairs will have unscreened E|| and NO SLOT GAPS

High-altitude slot gap model Muslimov & Harding 2003, 2004 Normalize phase plots Average flux derived from profile, given a and z Two-pole caustic geometry (Dyks & Rudak 2003, Dyks et al. 2004)

High energy “luminosity” from slot gaps For a=00

Outer gap model Zhang et al. 2004 Dependence of OG g-ray luminosity on inclination angle a f is fractional gap size <r>(a) is average emission radius in gap f determined by location of pair formation front wrt last open field line PFF determined by pair production condition EX is the self consistent PC temperature from heating by OG particles

Outer gap model Normalize phase plots f is fractional gap size Zhang et al. 2004, Jiang et al. 2006 Normalize phase plots f is fractional gap size Average flux derived from profile, given a and z

Outer gap luminosity This simulation Zhang et al. 2004

g-ray pulsar flux distribution RL and RQ EGRET GLAST 1yr LAT 32 pulsed RQ 157 pulsed RQ

g-ray pulsar spin-down luminosity RL and RQ EGRET GLAST 1yr LAT

g-ray pulsar age distribution EGRET RL and RQ GLAST 1yr LAT

g-ray pulsar distance distribution EGRET RL and RQ GLAST 1yr LAT

g-ray pulsar solid angle distribution EGRET RL and RQ GLAST 1yr LAT

Slot gap Geminga fraction Fraction of Gemingas = RQ/(RL + RQ) = 0.86 EGRET = 0.89 1 yr LAT

Outer gap Geminga fraction Fraction of Gemingas = RQ/(RL + RQ) = 0.98 EGRET = 0.96 1 yr LAT

Outer gap population studies compared Jiang et al. 2006 Our study GLAST 78 RL 740 RQ GLAST 9 RL 362 RQ EGRET 8 RL 24 RQ EGRET 3 RL 170 RQ

Recent change in outer gap geometry Takata et al. 2006 Outer gap exists below the null surface visible emission from both poles More like extended slot gap! Improved profile for Crab

Conclusions Geminga fraction is large for models where g-ray emission occurs at high altitude in the pulsar magnetosphere (e.g. extended slot gap and outer gap models) 86% for slot gap, 98% for outer gap Slot gap has (slightly) higher correlation with radio beams Even larger radio beams for young pulsars do not produce a small fraction of Gemingas size of radio beam decreases rapidly for P < 50 ms Large spread in g-ray emission solid angles and Lg vs Lsd Assumption of 1 sr is not accurate Radio loud pulsars are closer and have larger solid angles If many EGRET sources are radio loud pulsars, the emission must some from pair cascades of the low altitude slot gap (Gonthier talk)