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PheniX: a new vision for the hard X-ray sky
Roques J.-P., Jourdain E., Bassani L., Bazzano A., Belmont R. et al
Experimental Astronomy 34 (2012) 489-517 - http://hal.archives-ouvertes.fr/hal-00714861
Planète et Univers/Astrophysique/Phénomènes cosmiques de haute energie
Physique/Astrophysique/Phénomènes cosmiques de haute energie
PheniX: a new vision for the hard X-ray sky
J.-P. Roques1, E. Jourdain1, L. Bassani, A. Bazzano2, R. Belmont1, A.J. Bird3, E. Caroli, M. Chauvin, D. Clark, N. Gehrels, U. Goerlach4, F. Harrisson, P. Laurent5, 6, J. Malzac, P. Medina7, A. Merloni8, S. Paltani, J. Stephen, P. Ubertini9, J. Wilms
1 :  IRAP - Institut de recherche en astrophysique et planétologie
CNRS : UMR5277 – Université Paul Sabatier (UPS) - Toulouse III – Observatoire Midi-Pyrénées
France
2 :  INAF-IASF/Rome
INAF
Via Fosso del cavaliere 100 00133 Roma
Italie
3 :  School of Physics and Astronomy
University of Southampton
Royaume-Uni
4 :  DRS-IPHC - Département Recherches Subatomiques
CNRS : UMR7178 – IN2P3 – Université de Strasbourg
23 rue du Loess - BP28 67037 Strasbourg cedex 2
France
5 :  APC - UMR 7164 - AstroParticule et Cosmologie
http://www.apc.univ-paris7.fr/
CNRS : UMR7164 – IN2P3 – Observatoire de Paris – Université Paris VII - Paris Diderot – CEA : DSM/IRFU
APC - UMR 7164, Université Paris Diderot, 10 rue Alice Domon et Léonie Duquet, case postale 7020, F-75205 Paris Cedex 13
France
6 :  IRFU - Institut de Recherches sur les lois Fondamentales de l'Univers (ex DAPNIA)
CEA : DSM/IRFU
France
7 :  IPHC - Institut Pluridisciplinaire Hubert Curien
CNRS : UMR7178 – Université de Strasbourg
France
8 :  Max-Planck-Institut für Astrophysik
Max-Planck-Institut
Karl-Schwarzschild-Strasse 1, D-85741, Garching, Germany
Allemagne
9 :  IASF-Roma - Istituto di Astrofisica Spaziale e Fisica cosmica - Roma
http://www.rm.iasf.cnr.it/index.htm
INAF
Via del Fosso del Cavaliere 100 00133 Roma
Italie
APC - AHE
We are proposing a mission devoted to high energy X-ray astronomy that is based on a focusing telescope operating in the 1-200 keV energy range but optimized for the hard X-ray range. The main scientific topics concern: Physics of compact objects: The proximity of compact objects provides a unique laboratory to study matter and radiation in extreme conditions of temperature and density in strong gravitational environment. The emission of high energy photons from these objects is far from being understood. The unprecedented sensitivity in the high energy domain will allow a precise determination of the non-thermal processes at work in the vicinity of compact objects. The full 1-200 keV energy coverage will be ideal to disentangle the emission processes produced in the spacetime regions most affected by strong-gravity, as well as the physical links: disk-thermal emission-iron line-comptonisation-reflection-non-thermal emission-jets. Neutron stars-magnetic field-cyclotron lines: Time resolved spectroscopy (and polarimetry) at ultra-high sensitivity of AXP, milliseconds pulsars and magnetars will give new tools to study the role of the synchrotron processes at work in these objects. Cyclotron lines-direct measurement of magnetic filed-equation of state constraints-short bursts-giant flares could all be studied with great details. AGN: The large sensitivity improvement will provide detailed spectral properties of the high energy emission of AGN's. This will give a fresh look to the connection between accretion and jet emission and will provide a new understanding of the physical processes at work. Detection of high-redshift active nuclei in this energy range will allow to introduce an evolutionary aspect to high-energy studies of AGN, probing directly the origin of the Cosmic X-ray Background also in the non-thermal range (> 20 keV). Element formation-Supernovae: The energy resolution achievable for this mission (<0.5 keV) and a large high energy effective area are ideally suited for the 44Ti line study (68 and 78 keV). This radioactive nuclei emission will give an estimate of their quantities and speed in their environment. In addition the study of the spatial structure and spectral emission of SNR will advance our knowledge of the dynamics of supernovae explosions, of particles acceleration mechanisms and how the elements are released in the interstellar medium. Instrumental design: The progress of X-ray focusing optics techniques allows a major step in the instrumental design: the collecting area becomes independent of the detection area. This drastically reduces the instrumental background and will open a new era. The optics will be based on depth-graded multi-layer mirrors in a Wolter I configuration. To obtain a significant effective area in the hundred of keV range a focal length in the 40-50 meters range (attainable with a deployable mast) is needed. In addition such a mission could benefit from recent progress made on mirror coating. We propose to cover the 1-200 keV energy range with a single detector, a double-sided Germanium strip detector operating at 80 K. The main features will be: (a) good energy resolution (.150 keV at 5 keV and <.5 keV at 100 keV), (b) 3 dimensional event localization with a low number of electronic chains, (c) background rejection by the 3D localization, (d) polarisation capabilities in the Compton regime.
Anglais

Experimental Astronomy
internationale
Articles dans des revues avec comité de lecture
10/2012
34
489-517

Hard X-rays – Germanium – Grazing incidence optics – Space instrument
From the issue entitled "Special Issue: ESA's Cosmic Vision 2015-2025 Astrophysics and Fundamental Physics Mission Proposals"

PheniX