Shintake Monitor Nanometer Beam Size Measurement and Beam Tuning

Jacqueline Yan; Masahiro Oroku; Youhei Yamaguchi; Takashi Yamanaka; Yoshio Kamiya; Taikan Suehara; Sachio Komamiya; Toshiyuki Okugi; Nobuhiro Terunuma; Toshiaki Tauchi; Sakae Araki; Junji Urakawa

doi:10.1016/j.phpro.2012.02.522

Shintake Monitor Nanometer Beam Size Measurement and Beam Tuning

Jacqueline Yan, Masahiro Oroku, Youhei Yamaguchi, Takashi Yamanaka, Yoshio Kamiya, Taikan Suehara, Sachio Komamiya, Toshiyuki Okugi, Nobuhiro Terunuma, Toshiaki Tauchi, Sakae Araki, Junji Urakawa

Research output: Contribution to journal › Conference article › peer-review

2 Citations (Scopus)

Abstract

A novel final focus system design featuring the Local Chromaticity Correction scheme has beenproposed for ILC. This is to be verified at ATF2, a test facility for ILC, through focusing an e-beam down to the design vertical beam size ("σy") of 37 nm. Shintake Beam Size Monitor ("IPBSM"),installed at the virtual interaction point of ATF2, is the only existing device capable of measuring σy below 100 nm, making it indispensable for achieving the goals of ATF2 and a strong candidate for R&D at future linear colliders. This is attributed to its ingenious technique of scanning the phase oflaser interference fringes relative to the e-beam. Beam sizes are derived from the resulting Compton signal modulation measured by a downstream detector. Having been upgraded in a variety of ways since its first debut at FFTB, Shintake Monitor is capable of measuring a wide range of σy from 25 nm to 6 μm with better than 10% resolution. This paper describes the system's design, role in beam tuning, and various hardware upgrades to further improve its performance.

Original language	English
Pages (from-to)	1989-1996
Number of pages	8
Journal	Physics Procedia
Volume	37
DOIs	https://doi.org/10.1016/j.phpro.2012.02.522
Publication status	Published - 2012
Externally published	Yes
Event	2nd International Conference on Technology and Instrumentation in Particle Physics, TIPP 2011 - Chicago, United States Duration: Jun 9 2011 → Jun 14 2011

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)

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10.1016/j.phpro.2012.02.522

Cite this

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title = "Shintake Monitor Nanometer Beam Size Measurement and Beam Tuning",

abstract = "A novel final focus system design featuring the Local Chromaticity Correction scheme has beenproposed for ILC. This is to be verified at ATF2, a test facility for ILC, through focusing an e-beam down to the design vertical beam size ({"}σy{"}) of 37 nm. Shintake Beam Size Monitor ({"}IPBSM{"}),installed at the virtual interaction point of ATF2, is the only existing device capable of measuring σy below 100 nm, making it indispensable for achieving the goals of ATF2 and a strong candidate for R&D at future linear colliders. This is attributed to its ingenious technique of scanning the phase oflaser interference fringes relative to the e-beam. Beam sizes are derived from the resulting Compton signal modulation measured by a downstream detector. Having been upgraded in a variety of ways since its first debut at FFTB, Shintake Monitor is capable of measuring a wide range of σy from 25 nm to 6 μm with better than 10% resolution. This paper describes the system's design, role in beam tuning, and various hardware upgrades to further improve its performance.",

author = "Jacqueline Yan and Masahiro Oroku and Youhei Yamaguchi and Takashi Yamanaka and Yoshio Kamiya and Taikan Suehara and Sachio Komamiya and Toshiyuki Okugi and Nobuhiro Terunuma and Toshiaki Tauchi and Sakae Araki and Junji Urakawa",

note = "Publisher Copyright: {\textcopyright} 2012 Published by Elsevier B.V.; 2nd International Conference on Technology and Instrumentation in Particle Physics, TIPP 2011 ; Conference date: 09-06-2011 Through 14-06-2011",

year = "2012",

doi = "10.1016/j.phpro.2012.02.522",

language = "English",

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TY - JOUR

T1 - Shintake Monitor Nanometer Beam Size Measurement and Beam Tuning

AU - Yan, Jacqueline

AU - Oroku, Masahiro

AU - Yamaguchi, Youhei

AU - Yamanaka, Takashi

AU - Kamiya, Yoshio

AU - Suehara, Taikan

AU - Komamiya, Sachio

AU - Okugi, Toshiyuki

AU - Terunuma, Nobuhiro

AU - Tauchi, Toshiaki

AU - Araki, Sakae

AU - Urakawa, Junji

PY - 2012

Y1 - 2012

N2 - A novel final focus system design featuring the Local Chromaticity Correction scheme has beenproposed for ILC. This is to be verified at ATF2, a test facility for ILC, through focusing an e-beam down to the design vertical beam size ("σy") of 37 nm. Shintake Beam Size Monitor ("IPBSM"),installed at the virtual interaction point of ATF2, is the only existing device capable of measuring σy below 100 nm, making it indispensable for achieving the goals of ATF2 and a strong candidate for R&D at future linear colliders. This is attributed to its ingenious technique of scanning the phase oflaser interference fringes relative to the e-beam. Beam sizes are derived from the resulting Compton signal modulation measured by a downstream detector. Having been upgraded in a variety of ways since its first debut at FFTB, Shintake Monitor is capable of measuring a wide range of σy from 25 nm to 6 μm with better than 10% resolution. This paper describes the system's design, role in beam tuning, and various hardware upgrades to further improve its performance.

AB - A novel final focus system design featuring the Local Chromaticity Correction scheme has beenproposed for ILC. This is to be verified at ATF2, a test facility for ILC, through focusing an e-beam down to the design vertical beam size ("σy") of 37 nm. Shintake Beam Size Monitor ("IPBSM"),installed at the virtual interaction point of ATF2, is the only existing device capable of measuring σy below 100 nm, making it indispensable for achieving the goals of ATF2 and a strong candidate for R&D at future linear colliders. This is attributed to its ingenious technique of scanning the phase oflaser interference fringes relative to the e-beam. Beam sizes are derived from the resulting Compton signal modulation measured by a downstream detector. Having been upgraded in a variety of ways since its first debut at FFTB, Shintake Monitor is capable of measuring a wide range of σy from 25 nm to 6 μm with better than 10% resolution. This paper describes the system's design, role in beam tuning, and various hardware upgrades to further improve its performance.

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SN - 1875-3892

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JO - Physics Procedia

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ER -

Shintake Monitor Nanometer Beam Size Measurement and Beam Tuning

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