Your search keyword '"Hiroyuki Ogawa"' showing total 11 results

1. Cryogenic thermal design and analysis for LiteBIRD payload module

Author

Kimihide Odagiri, Masaru Saijo, Keisuke Shinozaki, Frederick T. Matsuda, Shugo Oguri, Toyoaki Suzuki, Hiroyuki Ogawa, Yutaro Sekimoto, Tadayasu Dotani, Kazuya Watanuki, Ryo Sugimoto, Keisuke Yoshihara, Katsuhiro Narasaki, Masahito Isshiki, Seiji Yoshida, Thomas Prouvé, Jean-Marc Duval, and Keith L. Thompson

Published

2022

2. Mechanical cooler system for the infrared space mission SPICA

Author

Seiji Yoshida, Hiroyuki Sugita, Keisuke Shinozaki, Takao Nakagawa, Kenichiro Sawada, C. Tokoku, Yoichi Sato, Hiroyuki Ogawa, Shoji Tsunematsu, Hiroshi Shibai, Kenichi Kanao, Masaru Saijo, Hideo Matsuhara, Katsuhiro Narasaki, Akinobu Okabayashi, and Tadahito Mizutani

Subjects

Physics, Stirling engine, business.industry, Infrared telescope, Joule–Thomson effect, Astrophysics::Instrumentation and Methods for Astrophysics, Lagrangian point, Spica, Radiant cooling, law.invention, Telescope, symbols.namesake, law, symbols, Water cooling, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Astrophysics::Galaxy Astrophysics

Abstract

The Space Infrared Telescope for Cosmology and Astrophysics (SPICA) mission is to be launched into orbit around the second Lagrangian point (L2) in the Sun-Earth system. Taking advantage of the thermal environment in L2, a 2.5m-class large IR telescope is cooled below 8K in combination with effective radiant cooling and a mechanical cooling system. SPICA adopts a cryogen-free system to prevent the mission operation lifetime being limited by the amount of cryogen as a refrigerant. Currently, the mechanical cooler system with the feasible solution giving a proper margin is proposed. As a baseline design, 4K / 1K-class Joule-Thomson coolers are used to cool the telescope and thermal interface for Focal Plane Instruments (FPIs). Additionally, two sets of double stage stirling coolers (2STs) are used to cool the telescope shield. In this design, nominal operation of FPIs can be kept when one mechanical cooler is in failure. In this paper, current baseline configuration of the mechanical cooler system and current status of mechanical coolers developments which need to satisfy the specific requirements of SPICA cryogenic system are presented.

Published

2020

3. The joint infrared space observatory SPICA: unveiling the obscured universe

Author

Willem Jellema, Gert de Lange, Toru Yamada, Takashi Onaka, Francisco Najarro, Marc Sauvage, Shoko Jin, R. Szczerba, Tohru Nagao, Hiroshi Shibai, Stafford Withington, Inga Kamp, Bart Vandenbussche, Takao Nakagawa, Hideko Nomura, Hiroyuki Ogawa, David Elbaz, Matthew Joseph Griffin, Charles M. Bradford, Mika Juvela, Jacques Rouquet, Hideo Matsuhara, Floris van der Tak, Csaba Kiss, Kotaro Kohno, Shiang-Yu Wang, Martin Giard, Pieter Dieleman, Peter Roelfsema, Yasuo Doi, Jesús Martín-Pintado, David A. Naylor, Marc Audard, A. Heske, Jan Tauber, Frank Helmich, Franz Kerschbaum, Hidehiro Kaneda, Bengt Larsson, Mitsuhiko Honda, Luigi Spinoglio, and Oliver Krause

Subjects

Astronomical Objects, Physics, media_common.quotation_subject, Milky Way, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, 02 engineering and technology, Spica, 021001 nanoscience & nanotechnology, 01 natural sciences, Physics::History of Physics, Galaxy, Universe, 010309 optics, Far infrared, Observatory, 0103 physical sciences, Galaxy formation and evolution, Astrophysics::Earth and Planetary Astrophysics, 0210 nano-technology, Astrophysics::Galaxy Astrophysics, media_common

Abstract

The mid/far infrared hosts a wealth of spectral information that allows direct determination of the physical state of matter in a large variety of astronomical objects, unhindered by foreground obscuration. Accessing this domain is essential for astronomers to much better grasp the fundamental physical processes underlying the evolution of many types of celestial objects, ranging from protoplanetary systems in our own milky way to 10-12 billion year old galaxies at the high noon of galaxy formation in our universe. The joint ESA/JAXA SPICA mission will give such access for the astronomical community at large, by providing an observatory with unprecedented mid- to far-infrared imaging, polarimetric and spectroscopic capabilities.

Published

2020

4. Cryogenic system of the infrared space mission SPICA

Author

Hiroyuki Ogawa, Shinsuke Takeuchi, Yoichi Sato, Jun Matsumoto, Hideki Uchida, Tadahito Mizutani, Hiroyuki Sugita, T. Tirolien, Hidehiro Kaneda, Ken Goto, Masaru Saijo, Keisuke Shinozaki, Kenichiro Sawada, Chihiro Tokoku, Hiroshi Shibai, Hideo Matsuhara, and Takao Nakagawa

Subjects

Physics, Radiative cooling, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Shields, Cryogenics, Spica, Cryocooler, law.invention, Telescope, Observatory, law, Radiative transfer, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Astrophysics::Galaxy Astrophysics

Abstract

We present an overview of the cryogenic system of the next-generation infrared observatory mission SPICA. One of the most critical requirements for the SPICA mission is to cool the whole science equipment, including the 2.5 m telescope, to below 8 K to reduce the thermal background and enable unprecedented sensitivity in the mid- and far-infrared region. Another requirement is to cool focal plane instruments to achieve superior sensitivity. We adopt the combination of effective radiative cooling and mechanical cryocoolers to accomplish the thermal requirements for SPICA. The radiative cooling system, which consists of a series of radiative shields, is designed to accommodate the telescope in the vertical configuration. We present thermal model analysis results that comply with the requirements to cool the telescope and focal plane instruments.

Published

2020

5. Thermal and mechanical design of SPICA payload module

Author

Takao Nakagawa, Tadahito Mizutani, Hiroyuki Ogawa, Mitsunobu Kawada, Keisuke Shinozaki, Shinsuke Takeuchi, Hideo Matsuhara, Masaru Saijo, Y. Sato, Chihiro Tokoku, Hidehiro Kaneda, Ken Goto, and Hiroshi Shibai

Subjects

Physics, Radiative cooling, business.industry, Payload, Infrared telescope, Cryogenics, Spica, Cryocooler, law.invention, Telescope, law, Active cooling, Aerospace engineering, business

Abstract

We present an overview of the thermal and mechanical design of the Payload Module (PLM) of the next- generation infrared astronomy mission Space Infrared Telescope for Cosmology and Astrophysics (SPICA). The primary design goal of PLM is to cool the whole science assembly including a 2.5 m telescope and focal-plane instruments below 8 K. SPICA is thereby expected to have very low background conditions so that it can achieve unprecedented sensitivity in the mid- and far-infrared. PLM also provides the instruments with the 4.8 K and 1.8 K stages to cool their detectors. The SPICA cryogenic system combines passive, effective radiative cooling by multiple thermal shields and active cooling by a series of mechanical cryocoolers. The mechanical cryocoolers are required to provide 40 mW cooling power at 4.8 K and 10 mW at 1.8 K at End-of-Life (EoL). End-to-end performance of the SPICA cryocooler-chain from 300 K to 50 mK was demonstrated under the framework of the ESA CryoChain Core Technology Program (CC-CTP). In this paper, we focus on the recent progress of the thermal and mechanical design of SPICA PLM which is based on the SPICA mission proposal to ESA.

Published

2018

6. SPICA: a joint infrared space observatory (Conference Presentation)

Author

Luigi Spinoglio, Martin Giard, Oliver Krause, Floris van der Tak, Hideo Matsuhara, Francisco Najarro, Bart Vandenbussche, Matthew Joseph Griffin, Kees Wafelbakker, Gert de Lange, Sue Madden, Ciska Kemper, Franz Kerschbaum, Yasuo Doi, Kotaro Kohno, Toru Yamada, Hidehiro Kaneda, Marc Audard, David A. Naylor, Charles M. Bradford, Takashi Onaka, Frank Helmich, Hiroshi Shibai, Lee Armus, Bengt Larsson, Inga Kamp, Takao Nakagawa, Hiroyuki Ogawa, and Peter Roelfsema

Subjects

Physics, Infrared astronomy, Milky Way, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, Spica, Planetary system, Galaxy, law.invention, Telescope, law, Galaxy formation and evolution, Astrophysics::Earth and Planetary Astrophysics, Stellar evolution, Astrophysics::Galaxy Astrophysics

Abstract

Measurements in the infrared wavelength domain allow us to assess directly the physical state and energy balance of cool matter in space, thus enabling the detailed study of the various processes that govern the formation and early evolution of stars and planetary systems in the Milky Way and of galaxies over cosmic time. Previous infrared missions, from IRAS to Herschel, have revealed a great deal about the obscured Universe, but sensitivity has been limited because up to now it has not been possible to fly a telescope that is both large and cold. Such a facility is essential to address key astrophysical questions, especially concerning galaxy evolution and the development of planetary systems. SPICA is a mission concept aimed at taking the next step in mid- and far-infrared observational capability by combining a large and cold telescope with instruments employing state-of-the-art ultra-sensitive detectors. The mission concept foresees a 2.5-meter diameter telescope cooled to below 8 K. Rather than using liquid cryogen, a combination of passive cooling and mechanical coolers will be used to cool both the telescope and the instruments. With cooling not dependent on a limited cryogen supply, the mission lifetime can extend significantly beyond the required three years. The combination of low telescope background and instruments with state-of-the-art detectors means that SPICA can provide a huge advance on the capabilities of previous missions. The SPICA instrument complement offers spectral resolving power ranging from ~50 through 11000 in the 17-230 µm domain as well as ~28.000 spectroscopy between 12 and 18 µm. Additionally, SPICA will be capable of efficient 30-37 µm broad band mapping, and small field spectroscopic and polarimetric imaging in the 100-350 µm range. SPICA will enable far infrared spectroscopy with an unprecedented sensitivity of ~5x10-20 W/m2 (5σ/1hr) - at least two orders of magnitude improvement over what has been attained to date. With this exceptional leap in performance, new domains in infrared astronomy will become accessible, allowing us, for example, to unravel definitively galaxy evolution and metal production over cosmic time, to study dust formation and evolution from very early epochs onwards, and to trace the formation history of planetary systems.

Published

2018

7. Design of temperature-independent zero-birefringence pressure sensitive adhesives (Conference Presentation)

Author

Hiroyuki Ogawa, Sumihisa Oda, Akihiro Tagaya, Yasuhiro Koike, Houran Shafiee, and Kaoru Kosaka

Subjects

chemistry.chemical_classification, Acrylate, Liquid-crystal display, Materials science, Birefringence, business.industry, Polymer, Backlight, Atmospheric temperature range, Polarizer, law.invention, chemistry.chemical_compound, Optics, chemistry, law, Adhesive, Composite material, business

Abstract

Liquid crystal displays (LCDs) are composed of two glass substrates, two polarizers and some optical films. These components are laminated by pressure sensitive adhesives (PSAs). When a polarizer shrinks by humidity or the heat from a backlight of LCDs, stress appears and deforms PSAs. PSAs tend to exhibit birefringence due to applied stress and temperature change, which causes light leakage degrading image quality of LCDs. PSAs are consisted of main chain polymers and cross-linkers. To evaluate birefringence of PSAs at room temperature is difficult because PSAs easily plastically deform at the temperature. The purpose of this article is to design temperature-independent zero-birefringence PSAs (TIZBPSAs) exhibiting almost no birefringence even during stress-induced deformation over a wide temperature range. Butyl acrylate (BA) and phenoxyethyl acrylate (PHEA) were selected as the monomers of main chain polymers and an isocyanate-type cross-linker was added. Trilaminar films were prepared in which PSAs were sandwiched between two supporting films. We successfully evaluated birefringence and temperature dependence of birefringence of PSAs for the first time by using temperature-independent zero-birefringence polymers (TIZBPs) as the supporting films. TIZBPs, designed in our group, show almost no orientational birefringence even when the polymer main chain is in an oriented state and almost no temperature dependence of orientational birefringence over a wide temperature range. We have proposed a novel method to design PSAs having desirable the birefringence properties by determining the contributions of BA, PHEA and the cross-linker to birefringence and temperature dependence of PSAs quantitatively. Furthermore, we have designed TIZBPSAs by the proposed method.

Published

2017

8. New cryogenic system of the next-generation infrared astronomy mission SPICA

Author

Ken Goto, Keisuke Shinozaki, Hiroyuki Sugita, M. Kawada, S. Takeuchi, Takao Nakagawa, Tadahito Mizutani, Hiroyuki Ogawa, Y. Sato, Naoki Isobe, Hideo Matsuhara, Hiroshi Shibai, and Toshihiko Yamawaki

Subjects

Physics, Infrared astronomy, Radiative cooling, Physics::Instrumentation and Detectors, Cryogenic system, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Cryogenics, Spica, Cryocooler, 01 natural sciences, law.invention, Telescope, symbols.namesake, law, 0103 physical sciences, symbols, Astrophysics::Earth and Planetary Astrophysics, Planck, 010306 general physics, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics

Abstract

We present the new design of the cryogenic system of the next-generation infrared astronomy mission SPICA under the new framework. The new design employs the V-groove design for radiators, making the best use of the Planck heritage. The new design is based on the ESA-JAXA CDF study (NG-CryoIRTel, CDF-152(A)) with a 2 m telescope, and we modified the CDF design to accommodate the 2.5 m telescope to meet the science requirements of SPICA. The basic design concept of the SPICA cryogenic system is to cool the Science Instrument Assembly (SIA, which is the combination of the telescope and focal-plane instruments) below 8K by the combination of the radiative cooling system and mechanical cryocoolers without any cryogen.

Published

2016

9. Mechanical cooler system for the next-generation infrared space telescope SPICA

Author

Tadahito Mizutani, Mitsunobu Kawada, Akinobu Okabayashi, Shoji Tsunematsu, Toshihiko Yamawaki, Hideo Matsuhara, Hiroshi Shibai, Katsuhiro Narasaki, Keisuke Shinozaki, Hiroyuki Sugita, Yoichi Sato, Takao Nakagawa, and Hiroyuki Ogawa

Subjects

Physics, business.industry, Infrared telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Spica, Radiant cooling, Orbital mechanics, 01 natural sciences, law.invention, Telescope, Optics, Spitzer Space Telescope, law, 0103 physical sciences, Water cooling, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, 010306 general physics, business, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Halo orbit

Abstract

The Space Infrared Telescope for Cosmology and Astrophysics (SPICA) is a pre-project of JAXA in collaboration with ESA to be launched in the 2020s. The SPICA mission is to be launched into a halo orbit around the second Lagrangian point in the Sun-Earth system, which allows us to use effective radiant cooling in combination with a mechanical cooling system in order to cool a 2.5m-class large IR telescope below 8K. Recently, a new system design in particular thermal structure of the payload module has been studied by considering the technical feasibility of a cryogenic cooled telescope within current constraints of the mission in the CDF (Concurrent Design Facility) study of ESA/ESTEC. Then, the thermal design of the mechanical cooler system, for which the Japanese side is responsible, has been examined based on the CDF study and the feasible solution giving a proper margin has been obtained. As a baseline, 4K / 1K-class Joule-Thomson coolers are used to cool the telescope and thermal interface for Focal Plane Instruments (FPIs). Additionally, two sets of double stirling coolers (2STs) are used to cool the Telescope shield. In this design, nominal operation of FPIs can be kept when one mechanical cooler is in failure.

Published

2016

10. Thermal study of payload module for the next-generation infrared space telescope SPICA in risk mitigation phase

Author

Hiroyuki Sugita, Kenichiro Sawada, Akinobu Okabayashi, Hideo Matsuhara, Makoto Takada, Keisuke Shinozaki, Takao Nakagawa, Keiji Komatsu, Hiroyuki Ogawa, Makiko Ando, Shun Okazaki, Toshihiko Yamawaki, Yoichi Sato, Katsuhiro Narasaki, Shoji Tsunematsu, and Tadahito Mizutani

Subjects

Physics, Payload, business.industry, Infrared telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Lagrangian point, Spica, Radiant cooling, law.invention, Telescope, Spitzer Space Telescope, law, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Astrophysics::Galaxy Astrophysics, Remote sensing, Halo orbit

Abstract

The Space Infrared Telescope for Cosmology and Astrophysics (SPICA) is a pre-project of JAXA in collaboration with ESA to be launched around 2025. The SPICA mission is to be launched into a halo orbit around the second Lagrangian point in the Sun-Earth system, which allows us to use effective radiant cooling in combination with a mechanical cooling system in order to cool a 3m large IR telescope below 6K. The use of 4K / 1K-class Joule-Thomson coolers is proposed in order to cool the telescope and provide a 4K / 1K temperature region for Focal Plane Instruments (FPIs). This paper introduces details of the thermal design study for the SPICA payload module in the Risk-Mitigation-Phase (RMP), in which the activity is focused on mitigating the mission’s highest risks. As the result of the RMP activity, most of all the goals have been fully satisfied and the thermal design of the payload module has been dramatically improved.

Published

2014

11. The ASTRO-H X-ray astronomy satellite

Author

Hironori Matsumoto, Yasuharu Sugawara, Hiroshi Tsunemi, Steve Allen, Ikuyuki Mitsuishi, James Pontius, Luigi C. Gallo, Dmitry Khangulyan, Hiroyuki Uchida, Yuichi Terashima, Yoichi Yatsu, Kazutaka Yamaoka, Kiyoshi Hayashida, Makoto Sawada, Peter Shirron, Hirofumi Noda, Andrew C. Fabian, Nicholas E. White, Brian R. McNamara, Dan R. Wilkins, Franco Moroso, Maxim Markevitch, Tadayuki Takahashi, Shin Mineshige, Peter J. Serlemitsos, Stephanie M. LaMassa, Tahir Yaqoob, Richard Mushotzky, Satoshi Sugita, Akihiro Furuzawa, Philipp Azzarello, Atsushi Wada, Yoh Takei, Yoshito Haba, Jun Kataoka, Daisuke Yonetoku, Yoshitaka Ishisaki, Helen Russell, Satoru Katsuda, Hiroaki Takahashi, Knox S. Long, Shinya Nakashima, Meg Urry, Housei Nagano, Chris Baluta, Atsushi Okamoto, Maria Chernyakova, Shin Watanabe, Randall K. Smith, Hans A. Krimm, Samar Safi-Harb, Yuichiro Ezoe, Tsuyoshi Okazaki, Takeshi Go Tsuru, Hiroshi Nakajima, Shin-ichiro Sakai, Katja Pottschmidt, Timothy R. Kallman, Stefan Funk, Kosuke Sato, Naomi Ota, Chikara Natsukari, Kazuo Makishima, Ken Ebisawa, Yasuyuki T. Tanaka, Massimiliano Galeazzi, Tatsuro Kosaka, Mina Ogawa, Jan-Willem den Herder, Atsumasa Yoshida, Joseph Miko, Chris Done, Shin'ichiro Uno, Kosei Ishimura, Hideyuki Mori, Takeshi Nakamori, H. Sameshima, Edward M. Cackett, Francesco Tombesi, Jelle Kaastra, Naoko Iyomoto, Kumi Ishikawa, Takashi Okajima, Yoshihiro Ueda, Hiroyasu Tajima, Mark O. Kimball, Arvind Parmar, Yasuko Shibano, Ryo Iizuka, Masayuki Ohta, Gary A. Sneiderman, Thomas G. Bialas, Toshio Murakami, Masanori Ohno, Christopher S. Reynolds, Masashi Kimura, Yoshiyuki Inoue, Masayuki Ito, Masayoshi Nobukawa, Marshall W. Bautz, Atsushi Harayama, Olivier Limousin, Naohisa Anabuki, Taro Kawano, Maki Shida, Martin Pohl, Saori Konami, Katsuhiro Hayashi, Aya Kubota, Chris Jewell, Yoshitomo Maeda, Steve O' Dell, Yukikatsu Terada, Keiji Ogi, Masanobu Ozaki, Kenji Minesugi, Takahiro Yamada, Edgar Canavan, Hiroki Akamatsu, Katsuji Koyama, Tomomi Watanabe, Marc Audard, Andrew Szymkowiak, Eric J. Miller, Ciro Pinto, Irina Zhuravleva, Shigeo Kawasaki, Jon M. Miller, Grzegorz Madejski, Makoto Tashiro, Ann Hornschemeier, Robert Petre, Koji Mori, Yasunobu Uchiyama, David H. Lumb, Brian D. Ramsey, Alex Koujelev, Shin'ichiro Takeda, Keisuke Shinozaki, Una Hwang, D. Haas, Shiro Ueno, Koji Mukai, Theodore Muench, Shinya Yamada, Masaharu Nomachi, Hiroshi Murakami, Kirk Gilmore, Keith A. Arnaud, Yoichi Sato, Kyoko Matsushita, Yoshiharu Namba, Takuya Miyazawa, Claudio Ricci, Teruaki Enoto, Masahiro Tsujimoto, Ryuichi Fujimoto, Dan McCammon, Daniel S. McGuinness, Abderahmen Zoghbi, Carlo Ferrigno, Motohide Kokubun, Stéphane Paltani, Elisa Costantini, Hiroshi Tomida, Maurice A. Leutenegger, Laura Brenneman, Tsunefumi Mizuno, Keisuke Tamura, Aurora Simionescu, Toru Tamagawa, Paolo De Coppi, Hiroyuki Sugita, Rie Sato, F. Scott Porter, Yusuke Nishioka, Franccois Lebrun, Takanobu Shimada, Yuzuru Tawara, Takayoshi Kohmura, Makoto Yamauchi, Shinya Saito, Jelle de Plaa, Michael J. DiPirro, Poshak Gandhi, Yasushi Fukazawa, Richard L. Kelley, Hirokazu Odaka, Nobuyuki Kawai, Junko S. Hiraga, Frits Paerels, Hiromi Seta, Takao Nakagawa, Rubens Reis, Tetsu Kitayama, Manabu Ishida, Cor P. de Vries, Hiromitsu Takahashi, Kazuhisa Mitsuda, Akio Hoshino, Kazuhiro Nakazawa, Felix Aharonian, Matteo Guainazzi, Meng P. Chiao, Eugenio Ursino, Adam R. Foster, John ZuHone, Hiroyuki Ogawa, John P. Doty, Takayuki Hayashi, Yasuo Tanaka, Junichiro Katsuta, Madoka Kawaharada, Hisamitsu Awaki, Kevin R. Boyce, John P. Hughes, Hiroya Yamaguchi, Ryo Nagino, Lorella Angelini, Philippe Laurent, Michael Loewenstein, Tuneyoshi Kamae, Yang Soong, Takaaki Tanaka, Tadayasu Dotani, Candace Masters, Aya Bamba, Kenji Hamaguchi, Roger Blandford, Kazunori Ishibashi, Takayuki Yuasa, Hideki Uchiyama, Takayuki Tamura, Kazuyuki Hirose, Naoko Iwata, Shunji Kitamoto, Goro Sato, Greg Brown, Shutaro Ueda, Megan E. Eckart, Cynthia Simmons, Takaya Ohashi, Hideyo Kunieda, Lukasz Stawarz, Yohko Tsuboi, Norbert Werner, Fumie Akimoto, Shigeo Yamauchi, Noriko Y. Yamasaki, Nobutaka Bando, Isamu Hatsukade, Caroline A. Kilbourne, and Makoto Asai

Subjects

Physics, Astronautics, X-ray astronomy, Astrophysics::High Energy Astrophysical Phenomena, gamma radiation, Dark matter, Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astronomy, x-rays, x-ray astronomy, Redshift, Gravitation, satellites, Settore FIS/05 - Astronomia e Astrofisica, spectral resolution, Satellite, equipment and services, Spectral resolution, Astrophysics - Instrumentation and Methods for Astrophysics, galaxy groups and clusters, Instrumentation and Methods for Astrophysics (astro-ph.IM), Galaxy cluster

Abstract

The joint JAXA/NASA ASTRO-H mission is the sixth in a series of highly successful X-ray missions developed by the Institute of Space and Astronautical Science (ISAS), with a planned launch in 2015. The ASTRO-H mission is equipped with a suite of sensitive instruments with the highest energy resolution ever achieved at E > 3 keV and a wide energy range spanning four decades in energy from soft X-rays to gamma-rays. The simultaneous broad band pass, coupled with the high spectral resolution of Delta E < 7 eV of the micro-calorimeter, will enable a wide variety of important science themes to be pursued. ASTRO-H is expected to provide breakthrough results in scientific areas as diverse as the large-scale structure of the Universe and its evolution, the behavior of matter in the gravitational strong field regime, the physical conditions in sites of cosmic-ray acceleration, and the distribution of dark matter in galaxy clusters at different redshifts., 24 pages, 18 figures, Proceedings of the SPIE Astronomical Instrumentation "Space Telescopes and Instrumentation 2014: Ultraviolet to Gamma Ray"

Published

2014