Hiroshima Synchrotron Radiation Center: Difference between revisions
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== Hiroshima Synchrotron Radiation Center == |
== Hiroshima Synchrotron Radiation Center == |
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The '''Hiroshima Synchrotron Radiation Center''', also known as '''Hiroshima Synchrotron Orbital Radiation''' ('''HiSOR'''), at [[Hiroshima University]] is a national user research facility in [[Japan]]. It was founded in 1996 by the University Science Council at Hiroshima University initially as a combined educational and research facility before opening to users in Japan and across the world in 2002. It is the only [[synchrotron]] [[radiation]] experimental facility located at a national university in Japan. |
The '''Hiroshima Synchrotron Radiation Center''', also known as '''Hiroshima Synchrotron Orbital Radiation''' ('''HiSOR'''), at [[Hiroshima University]] is a national user research facility in [[Japan]]. <ref>[http://www.spectroscopynow.com/details/ezine/14de2ba5f37/Beating-the-heat-Cooler-chips.html?&tzcheck=1 "Beating the heat: Cooler chips"].''Spectroscopy Now'', Jun 15, 2015, David Bradley</ref>It was founded in 1996 by the University Science Council at Hiroshima University initially as a combined educational and research facility before opening to users in Japan and across the world in 2002. It is the only [[synchrotron]] [[radiation]] experimental facility located at a national university in Japan. |
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⚫ | The HiSOR experimental hall contains two [[Undulator|undulators]] that produce light in the [[ultraviolet]] to soft [[x-ray]] range. A total of 16 [[beamline|beamlines]]<ref>{{cite web | url=http://www.lightsources.org/facility/hsrc | accessdate = March 27, 2015 | publisher=Lightsources.org | title=Hiroshima Synchrotron Radiation Center (HISOR)}}</ref> are supported by [[bending magnet]] and undulator radiation for use in basic studies of [[life sciences]] and [[physical sciences]], especially [[solid-state physics]]. |
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⚫ | The HiSOR experimental hall contains two [[Undulator|undulators]] that produce light in the [[ultraviolet]] to soft [[x-ray]] range. A total of 16 [[beamline|beamlines]]<ref>{{cite web | url=http://www.lightsources.org/facility/hsrc | accessdate = March 27, 2015 | publisher=Lightsources.org | title=Hiroshima Synchrotron Radiation Center (HISOR)}}</ref> are supported by [[bending magnet]] and undulator radiation for use in basic studies of [[life sciences]] and [[physical sciences]], especially [[solid-state physics]]. |
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== History == |
== History == |
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== Design == |
== Design == |
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A [[microtron]] developed by [[Sumitomo Heavy Industries]] isused as the injection system, |
A [[microtron]] developed by [[Sumitomo Heavy Industries]] isused as the injection system, an extension of a design concept from the [[Synchrotron Radiation Center|University of Wisconsin]]. Its compact design uses 2.7 T bending magnets instead of conventional 1.2 T bending magnets, allowing the light to achieve the same power and wavelength as a medium-scale synchrotron without using a higher energy beam.<ref name="Taniguchi1998"></ref> |
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The HiSOR has two [[insertion device|insertion devices]], a linear undulator and a helical undulator, in the two linear sections of the ring and has an electron energy of 0.7 GeV with a nominal beam current of 300 mA.<ref>{{cite web | url=http://www.lightsources.org/sites/default/files/legacy/posters/facility/Poster_HiSOR_SRI_A0.pdf | accessdate=March 27, 2015 |publisher=Hiroshima University | date=2011| title=Hiroshima Synchrotron Radiation |
The HiSOR has two [[insertion device|insertion devices]], a linear undulator and a helical undulator, in the two linear sections of the ring and has an electron energy of 0.7 GeV with a nominal beam current of 300 mA.<ref>{{cite web | url=http://www.lightsources.org/sites/default/files/legacy/posters/facility/Poster_HiSOR_SRI_A0.pdf | accessdate=March 27, 2015 |publisher=Hiroshima University | date=2011| title=Hiroshima Synchrotron Radiation |
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Center, Hiroshima University}}</ref><ref name="Taniguchi1998"></ref> The ring itself has a circumference of 22 m. The photon yield is 1.2×10<sup>11</sup> photons s<sup>-1</sup> mrad<sup>-2</sup> at 5 keV, in 0.1% bandwidth, for 300 mA.<ref name="Taniguchi1998" |
Center, Hiroshima University}}</ref><ref name="Taniguchi1998"></ref> The ring itself has a circumference of 22 m. The photon yield is 1.2×10<sup>11</sup> photons s<sup>-1</sup> mrad<sup>-2</sup> at 5 keV, in 0.1% bandwidth, for 300 mA.<ref name="Taniguchi1998" /> |
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==References== |
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{{reflist}} |
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==External links== |
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*{{cite web | url=http://www.hiroshima-u.ac.jp/en/top/kenkyusyo/p_jpi2wa.html | title = Hiroshima University - Hiroshima Synchrotron Radiation Center | accessdate=March 27, 2015 | publisher=Hiroshima University}} |
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{{AfC postpone G13}} |
{{AfC postpone G13}} |
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Hiroshima Synchrotron Radiation Center
The Hiroshima Synchrotron Radiation Center, also known as Hiroshima Synchrotron Orbital Radiation (HiSOR), at Hiroshima University is a national user research facility in Japan. [1]It was founded in 1996 by the University Science Council at Hiroshima University initially as a combined educational and research facility before opening to users in Japan and across the world in 2002. It is the only synchrotron radiation experimental facility located at a national university in Japan. The HiSOR experimental hall contains two undulators that produce light in the ultraviolet to soft x-ray range. A total of 16 beamlines[2] are supported by bending magnet and undulator radiation for use in basic studies of life sciences and physical sciences, especially solid-state physics.
History
Development began with a exploratory committee formed in 1982, which gathered input from Hiroshima University, local agencies, and prefectural agencies. [3] Between 1986 and 1988, several proposals and budget requests were submitted to the Ministry of Education of Japan for a medium-scale synchrotron radiation facility.[4] In 1989, a chair for synchrotron radiation was established at Hiroshima University Graduate School of Science and studies began for the planning of a medium-scale synchrotron radiation source.[3] However, with the approval of SPring-8 just 210 km away, the design emphasis of the project shifted away from the originally planned 1.5 GeV to a compact light source design which would be more complementary to a high-energy accelerator like SPring-8 and more appropriate for a university. The compact synchrotron concept was then renamed as the HSRC, while the storage ring itself would be named HiSOR.
In 1996, the HSRC building was inaugurated and a 10-year research organization plan was developed for HiSOR by the Education and Research Council of Hiroshima University. The intent was to create a facility as part of the Graduate School of Science to serve as both a research and educational tool, specifically supporting master's students in the Department of Physical Sciences. Originally, two divisions were created (still need to research this more). In 1997, the first light from HiSOR was emitted and in 1999, the Okayama University beamline was constructed.[4]
In April 2002, the HSRC was repurposed as a national user facility and the divisions were expanded to basic science, accelerator research, and synchrotron radiation research. As part of the reopening, the HSRC joined the Council for Research Institutes and Centers of Japanese National Universities.
An annual Hiroshima International Symposium on Synchrotron Radiation is held to showcase synchrotron radiation and nanoscience research work from Japan and abroad and for students to promote their dissertation research and HSRC's activities. In terms of outreach, the HSRC also has programs for facility tours, synchrotron radiation training, involvement with high schools, and open lectures to the public.
Design
A microtron developed by Sumitomo Heavy Industries isused as the injection system, an extension of a design concept from the University of Wisconsin. Its compact design uses 2.7 T bending magnets instead of conventional 1.2 T bending magnets, allowing the light to achieve the same power and wavelength as a medium-scale synchrotron without using a higher energy beam.[3]
The HiSOR has two insertion devices, a linear undulator and a helical undulator, in the two linear sections of the ring and has an electron energy of 0.7 GeV with a nominal beam current of 300 mA.[5][3] The ring itself has a circumference of 22 m. The photon yield is 1.2×1011 photons s-1 mrad-2 at 5 keV, in 0.1% bandwidth, for 300 mA.[3]
References
- ^ "Beating the heat: Cooler chips".Spectroscopy Now, Jun 15, 2015, David Bradley
- ^ "Hiroshima Synchrotron Radiation Center (HISOR)". Lightsources.org. Retrieved March 27, 2015.
- ^ a b c d e Masaki Taniguchi, Jacques Ghijsen (January 15, 1998). "The Hiroshima Synchrotron Radiation Center (HSRC)". J. Synchrotron Rad. 5 (3): 1176–1179. doi:10.1107/S0909049597018347.
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(help) - ^ a b "History". Hiroshima Synchrotron Radiation Center. Retrieved March 27, 2015.
- ^ "Hiroshima Synchrotron Radiation Center, Hiroshima University" (PDF). Hiroshima University. 2011. Retrieved March 27, 2015.
{{cite web}}
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External links
- "Hiroshima University - Hiroshima Synchrotron Radiation Center". Hiroshima University. Retrieved March 27, 2015.