Hard X-Ray Emission of Quasi- Thermal Electrons from the Galactic Ridge V. A. Dogiel 1,2, Hajime Inoue 1, Kuniaki Masai 3, V. Schoenfelder 4, and A. W.

Slides:

Advertisements

Similar presentations

X-ray Astronomy with High Spectral Resolution: Astro-E2 / ISAS Y. Tanaka.

Advertisements

Energy Release and Particle Acceleration in Flares Siming Liu University of Glasgow 9 th RHESSI Workshop, Genova, Italy, Sep

R. P. Lin Physics Dept & Space Sciences Laboratory University of California, Berkeley The Solar System: A Laboratory for the Study of the Physics of Particle.

Andrzej A. Zdziarski Centrum Astronomiczne im. M. Kopernika Warszawa, Poland Radiative processes and geometry of accreting black holes.

THE ORIGIN OF COSMIC RAYS Implications from and for X and γ-Ray Astronomy Pasquale Blasi INAF/Osservatorio Astrofisico di Arcetri, Firenze.

Strange Galactic Supernova Remnants G (the Tornado) & G in X-rays Anant Tanna Physics IV 2007 Supervisor: Prof. Bryan Gaensler.

RX J alias Vela Jr. The Remnant of the Nearest Historical Supernova : Impacting on the Present Day Climate? Bernd Aschenbach Vaterstetten, Germany.

Fitting X-ray Spectra with Imperfect Models Nancy S. Brickhouse Harvard-Smithsonian Center for Astrophysics Acknowledgments to Randall Smith and Adam Foster.

GAMMA-RAYS FROM COLLIDING WINDS OF MASSIVE STARS Anita Reimer, Stanford University Olaf Reimer, Stanford University Martin Pohl, Iowa State University.

Light. Photons The photon is the gauge boson of the electromagnetic force. –Massless –Stable –Interacts with charged particles. Photon velocity depends.

Luigina Feretti Istituto di Radioastronomia CNR Bologna, Italy Radio observations of cluster mergers X-Ray and Radio Connections, Santa Fe, NM February.

Electron thermalization and emission from compact magnetized sources

Working Group 2 - Ion acceleration and interactions.

Measuring the Temperature of Hot Solar Flare Plasma with RHESSI Amir Caspi 1,2, Sam Krucker 2, Robert P. Lin 1,2 1 Department of Physics, University of.

Potential Positron Sources around Galactic Center Department of Physics National Tsing Hua University G.T. Chen 2007/11/29.

Uses of solar hard X-rays Basics of observations Hard X-rays at flare onset The event of April 18, 2001 Conclusions Yohkoh 10th Jan. 21, 2002Hugh Hudson,

October 13, 2006Chandra Fellow Boston, MA1 Joint Chandra and Suzaku CCD Spectroscopy of Hard X-ray Emission in the Arches Cluster Masahiro.

Particles and Fields in Lobes of Radio Galaxies Naoki Isobe (NASDA, MAXI Mission) Makoto Tashiro (Saitama Univ.) Kazuo Makishima (Univ. of Tokyo) Hidehiro.

Hard X-ray Diagnostics of Solar Eruptions H. Hudson SSL, UC Berkeley and U. Of Glasgow.

Discovery of New SNR Candidates in the Galactic Center Region with ASCA and Chandra Atsushi Senda 1, Hiroshi Murakami 2, Aya Bamba 1, Shin-ichiro Takagi.

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

Cosmic Rays Discovery of cosmic rays Local measurements Gamma-ray sky (and radio sky) Origin of cosmic rays.

Zhang Ningxiao.  Emission of Tycho from Radio to γ-ray.  The γ-ray is mainly accelerated from hadronic processes.

ABSTRACT This work concerns with the analysis and modelling of possible magnetohydrodynamic response of plasma of the solar low atmosphere (upper chromosphere,

Radio lobes of Pictor A: an X-ray spatially resolved study G.Migliori(1,2,3), P.Grandi(2), G.C.G.Palumbo(1), G.Brunetti(4), C.Stanghellini(4) (1) Bologna.

The Galactic Center is a Treasure Box of High Energy Physics The Nearest AGN and Star Burst Galaxy. I will report a current picture of the Galactic Center,

「すざく」による SN1006 の観測 Suzaku observations of SN1006 Aya BAMBA (ISAS/JAXA)

NEEP 541 Radiation Interactions Fall 2003 Jake Blanchard.

Tycho’s SNR SNR G "To make an apple pie from scratch, you must first invent the universe." ~Carl Sagan.

The Hot Plasma in the Galactic Center with Suzaku Masayoshi Nobukawa, Yoshiaki Hyodo, Katsuji Koyama, Takeshi Tsuru, Hironori Matsumoto (Kyoto Univ.)

Modelling of the Effects of Return Current in Flares Michal Varady 1,2 1 Astronomical Institute of the Academy of Sciences of the Czech Republic 2 J.E.

Gamma-rays from SNRs and cosmic rays

The TeV view of the Galactic Centre R. Terrier APC.

About the 8 keV plasma at the Galactic Center CEA, Saclay Belmont R. Tagger M. UCLA Muno M. Morris M. Cowley S. High Energy Phenomena in the Galactic Center.

The Influence of the Return Current and the Electron Beam on the X-Ray Flare Spectra Elena Dzifčáková, Marian Karlický Astronomical Institute of the Academy.

Suzaku, XMM-Newton and Chandra Observations of the Central Region of M 31 Hiromitsu Takahashi (Hiroshima University, Japan) M. Kokubun, K. Makishima, A.

Summary(3) -- Dynamics in the universe -- T. Ohashi (Tokyo Metropolitan U) 1.Instrumentation for dynamics 2.Cluster hard X-rays 3.X-ray cavities 4.Dark.

Suzaku Study of X-ray Emission from the Molecular Clouds in the Galactic Center M. Nobukawa, S. G. Ryu, S. Nakashima, T. G. Tsuru, K. Koyama (Kyoto Univ.),

Extended X-ray Emissions from the Radio Galaxies Centaurus B and Fornax A Makoto Tashiro 1, Naoki Isobe 2, Masaya Suzuki 1 Kouichi Ito 1, Keiichi Abe 1,

1 Physics of GRB Prompt emission Asaf Pe’er University of Amsterdam September 2005.

Multi-Zone Modeling of Spatially Non-uniform Cosmic Ray Sources Armen Atoyan Concordia University, Montreal FAA60 Barcelona, 7 November 2012.

Suzaku observation of the Galactic Ridge K.Ebisawa,T.Takahashi, H.Murakami, Y.Ezoe (ISAS), Y.Tanaka (MPE), S.Yamauchi (Iwate), K.Koyama (Kyoto), M.Kokubun,

Internal Irradiation of the Sgr B2 Molecular Cloud Casey Law Northwestern University, USA A reanalysis of archived X-ray and radio observations to understand.

Search for Synchrotron X-ray Dominated SNRs with the ASCA Galactic Plane Survey Aya Bamba 1, Masaru Ueno 1, Katsuji Koyama 1, Shigeo Yamauchi 2, Ken Ebisawa.

Stochastic Wake Field particle acceleration in GRB G. Barbiellini (1), F. Longo (1), N.Omodei (2), P.Tommasini (3), D.Giulietti (3), A.Celotti (4), M.Tavani.

Jets Two classes of jets from X-ray binaries

Sgr B2 Galactic Center Survey with Chandr Radio Arc １ Sgr A East ： Young SNR 2 The GC Hot Plasma ： 10keV 3 Sgr B2, Radio Arc ： Molecular Clouds ~2 x 1.

Spatial Distribution of the Galactic Diffuse X-Rays and the Spectral/Timing Study of the 6.4-keV Clumps Katsuji Koyama Department of Physics, Graduate.

A Pulsar Wind Nebula Origin for Luminous TeV Source HESS J Joseph Gelfand (NYUAD / CCPP) Eric Gotthelf, Jules Halpern (Columbia University), Dean.

X-ray observation of the Cygnus Loop with Suzaku and XMM-Newton

Propagation of CR electrons and the interpretation of diffuse  rays Andy Strong MPE, Garching GLAST Workshop, Rome, 17 Sept 2003 with Igor Moskalenko.

E.G.Berezhko, L.T. Ksenofontov Yu.G.Shafer Institute of Cosmophysical Research and Aeronomy Yakutsk, Russia Energy spectra of electrons and positrons,

Discovery of K  lines of neutral S, Ar, Ca, Cr, & Mn atoms from the Galactic center with Suzaku Masayoshi Nobukawa, Katsuji Koyama, Takeshi Go Tsuru,

Gamma-ray Measurements of the distribution of Gas and Cosmic Ray in the Interstellar Space Yasushi Fukazawa Hiroshima University.

CLUSTERS OF GALAXIES IGM, and Scaling Laws. Emission Processes of Clusters of Galaxies in the X-ray Band.

Hiroyasu Tajima Stanford Linear Accelerator Center Kavli Institute for Particle Astrophysics and Cosmology October 26, 2006 GLAST lunch Particle Acceleration.

Gamma-ray Bursts from Synchrotron Self-Compton Emission Juri Poutanen University of Oulu, Finland Boris Stern AstroSpace Center, Lebedev Phys. Inst., Moscow,

Stochastic wake field particle acceleration in Gamma-Ray Bursts Barbiellini G., Longo F. (1), Omodei N. (2), Giulietti D., Tommassini P. (3), Celotti A.

Suzaku Observation of the Galactic Center Region Takeshi Go Tsuru (Kyoto University) _Suzaku2011_GC_v14.key R.Fukuoka, Y.Hyodo, T.Inui, K.Koyama,

High Energy Observational Astrophysics. 1 Processes that emit X-rays and Gamma rays.

Tobias Jogler Max-Planck Institut für Physik IMPRS YSW Ringberg 2007 VHE emission from binary systems Outline Binary systems Microquasar Pulsar binaries.

Physics of Solar Flares

High Energy emission from the Galactic Center

Particle Acceleration in the Universe

Gamma Ray Emission Mechanisms

Lecture 2 IGM, Scaling Laws Clusters Cosmology Connection

Modelling of non-thermal radiation from pulsar wind nebulae

超新星遗迹的XTP 观测模拟南京大学陈阳、周平、张潇.

SNR 的XTP 观测模拟南京大学陈阳、周平、张潇.

Stochastic Wake Field particle acceleration in GRB

Presentation transcript:

Hard X-Ray Emission of Quasi- Thermal Electrons from the Galactic Ridge V. A. Dogiel 1,2, Hajime Inoue 1, Kuniaki Masai 3, V. Schoenfelder 4, and A. W. Strong 4 1 Institute of Space and Astronautical Science, Sagamihara, Japan 2 P.N.Lebedev Physical Institute, Moscow, Russia 3 Tokyo Metropolitan University, Tokyo, Japan 4 Max-Planck Institut fuer extraterrestrische Physik, Garching, FRG

Galactic Ridge X-Ray Emission 30 years since its discovery (Bleach et al., 1970), but the origin has not been resolved yet. 30 years since its discovery (Bleach et al., 1970), but the origin has not been resolved yet. The total energy flux in the range 2-10 keV is Q=10 The total energy flux in the range 2-10 keV is Q x =10 38 erg/s Distribution |l|< 50 o, |b|< 10 o. Distribution |l|< 50 o, |b|< 10 o.

Thermal bremsstrahlung origin. Thermal bremsstrahlung origin. X-ray emission from hot plasma with the temperature 5-10 keV. Too high rate of SN explosions. Excluded. The ridge emission is truly diffuse and nonthermal. Discrete sources. Discrete sources. Galactic point-like sources with required properties are not found from the ASCA and CHANDRA observations. Excluded. Inverse Compton Scattering. Inverse Compton Scattering. Inconsistent with the observed Galactic radio emission. Excluded. Nonthermal bremsstrahlung radiation Nonthermal bremsstrahlung radiation of subrelativistic electrons or protons. Q~ erg/s> Q SN. A new class “unseen” of CR sources? (or exluded). Origin of the Ridge X-Ray Flux

Therma l vs Nonthermal Multi-temperature interpretation Regions with temperatures 0.75, 1.8 and 10 keV are needed to reproduce the Ridge spectrum (Tanaka 2001) The position of the Fe-line, 6.61 keV corresponds to a highly ionized hot medium (Kaneda et al.1997) with the temperature 5-10 keV 10 kev plasma is unstable!

A flux of 6.4 keV Fe-line has to be generated by nonthermal electrons. The energy output of the electrons as high as erg/s is needed, i.e. more than can be supplied by SN stars! Thermal vs Nonthermal The ridge spectrum is reproduced by a two-temperature plasma (0.6 and 2.8 keV) + a hard flux of nonthermal subrelativistic electrons (Valinia et al. 2000)

Particle Acceleration from Background Plasma The large scale association of the hard X-ray emission with the thermal X-rays implies that these two components are linked This leads to the idea that thermal particle in the hot plasma are accelerated. The X-ray flux is produced in the regions where particles are freshly accelerated (Yamasaki et al. 1997). There is an extended transition region of quasi- thermal particles between the energy ranges of thermal and non-thermal particles (Gurevich, 1960 – Fermi acceleration, Bulanov and Dogiel, 1979 – shock wave acceleration)!

Bremsstrahlung of Quasi-Thermal Particles Equation for accelerated particles E<kT/( a/n) thermal particles E>kT/( a/n) nonthermal particles kT/( a/n ) 0.66 >E>kT/( a/n) quasi-thermal particles Bresstrahlung emission of quasi-thermal particles – the ridge X-ray emission?

List of Problems has to be Resolved Energetical problem Energetical problem Problem of plasma hydrostatic stability Problem of plasma hydrostatic stability Problem of multi-temperature medium Problem of multi-temperature medium Problem of highly ionized medium Problem of highly ionized medium Single X-ray spectrum from different regions of the Galactic Ridge Single X-ray spectrum from different regions of the Galactic Ridge

Multi-Temperature X-Ray Spectra Two processes form the particle spectrum: Coulomb collisions which form the background spectrum; Stochastic acceleration which forms a power- law “tail” of non-thermal particles. The acceleration violates the equilibrium state of the background plasma that produces a particle “run-away” flux into acceleration region. Coulomb collisions form an extended transition region of quasi-thermal particles that mimics the effect of many temperature distribution.

THQTHNTH

Energy Output Thermal particles x titi x x x F x =10 -5 N/t i N N, t=t br Q= Q x = N/t br ~10 38 erg/s x Q=10 5 Q x =10 43 erg/s Nonthermal particles titi xx x x x x x N 0, t=t i, t i /t br ~10 -5 F x ~N/ t br ~10 -5 N/ t i

Bremsstrahlung of quasi-thermal electrons erg/s<Q<10 43 erg/s Quasi-thermal particles x titi F x =10 -5 N titi F x =10 -5 N/ t i, Q=N/ t x x N N’< N, t i < t < t br Q=Q x t br /t e =Q x t br /t i t i /t e = Q x =10 38 erg/s Q<10 42 erg/s =10 5 Q x t i / t e

Electrons or protons? 10 keV photons are emitted either by a ~10 keV electron or by a 20 MeV proton. For a 0.3 keV plasma the range of quasi-thermal electrons 5 50 keV the range of nonthermal particles. 20 MeV protons are nonthermal. Q p ~10 43 erg/s Q e <10 42 erg/s !!!

electrons protons

Pressure of quasi-thermal particles Region of X-ray emission of thermal and quasi- thermal particles Region of X-ray emission of nonthermal particles Acceleration region Surrounding medium Particle lifetime in acceleration region: t th = t br ; t br < t qth < t i ; t nth = t acc < t i Particle pressure in acceleration region: P th =1, P qth <0.3, P nth ~0. Plasma hydrostatically stable!!!

Quasi-Thermal Origin of the Line Emission Three components of the electron spectrum: thermal (T~0.6 keV), quasi-thermal, and nonthermal Thermal component – ionization state of iron nuclei +16 Nonthermal component keV line Quasi-thermal component – additional ionization of Fe nuclei. Result – 6.61 keV line emission in relatively cold plasma!

T=0.3 keV

T=0.6 keV

List of Resolved Problems Energetical problem - <10 42 erg/s Energetical problem - <10 42 erg/s Problem of plasma hydrostatic stability - plasma temperature T<T gr Problem of plasma hydrostatic stability - plasma temperature T<T gr Problem of multi-temperature medium – Artifact. Emission of quasi-thermal electrons Problem of multi-temperature medium – Artifact. Emission of quasi-thermal electrons Problem of highly ionized medium- Ionization by quasi-thermal electrons Problem of highly ionized medium- Ionization by quasi-thermal electrons Single spectrum – single process of the electron spectrum formation Single spectrum – single process of the electron spectrum formation

Conclusion Emitting particles - electrons Emitting particles - electrons Emitting space – regions of particle acceleration Emitting space – regions of particle acceleration Parameters of the space – T~ keV Parameters of the space – T~ keV Energy range of emitting particles – quasi-thermal electron (with E~5-50 keV) Energy range of emitting particles – quasi-thermal electron (with E~5-50 keV) Acceleration time necessary to produce the ridge X-ray flux – t e = s Acceleration time necessary to produce the ridge X-ray flux – t e = s The energy output of the emitting electrons – (1-3) erg/s The energy output of the emitting electrons – (1-3) erg/s