Associate for Education and Public Outreach

Shugo Oguri

  (小栗 秀悟)

Profile Information

Affiliation
Assistant Professor, Institute of Space and Astronautical Science, Department of Space Astronomy and Astrophysics, Japan Aerospace Exploration Agency
Degree
Ph. D(Jul, 2012, The University of Tokyo)

Researcher number
20751176
ORCID ID
 https://orcid.org/0000-0002-5902-2672
J-GLOBAL ID
201901005927826680
researchmap Member ID
B000348585

宇宙素粒子物理学が専門です。現在はCMB偏光観測を行う衛星実験LiteBIRDの研究開発をしています。

宇宙初期の物理学、特にインフレーションやダークマターなどに興味があります。


Papers

 52

Misc.

 50
  • Miku Tsujii, Jochem J. A. Baselmans, Jihoon Choi, Antonio H. M. Coppens, Alessandro Fasano, Ricardo Tanausú Génova-Santos, Makoto Hattori, Masashi Hazumi, Shunsuke Honda, Takuji Ikemitsu, Hidesato Ishida, Hikaru Ishitsuka, Hoyong Jeong, Yonggil Jo, Kenichi Karatsu, Keisuke Kataoka, Kenji Kiuchi, Junta Komine, Ryo Koyano, Hiroki Kutsuma, Kyungmin Lee, Satoru Mima, Makoto Nagai, Taketo Nagasaki, Masato Naruse, Shugo Oguri, Chiko Otani, Michael W. Peel, Rafael Rebolo, José Alberto Rubiño-Martín, Yutaro Sekimoto, Yoshinori Sueno, Junya Suzuki, Tohru Taino, Osamu Tajima, Tomonaga Tanaka, David J. Thoen, Nozomu Tomita, Yuta Tsuji, Tomohisa Uchida, Eunil Won, Mitsuhiro Yoshida
    Jul 24, 2024  
    GroundBIRD is a ground-based cosmic microwave background (CMB) experiment for observing the polarization pattern imprinted on large angular scales ($\ell > 6$ ) from the Teide Observatory in Tenerife, Spain. Our primary scientific objective is a precise measurement of the optical depth $\tau$ ($\sigma(\tau) \sim 0.01$) to the reionization epoch of the Universe to cross-check systematic effects in the measurements made by previous experiments. GroundBIRD observes a wide sky area in the Northern Hemisphere ($\sim 40\%$ of the full sky) while continuously rotating the telescope at a high speed of up to 20 rotations per minute (rpm) to overcome the fluctuations of atmospheric radiation. We have adopted the NbTiN/Al hybrid microwave kinetic inductance detectors (MKIDs) as focal plane detectors. We observe two frequency bands centered at 145 GHz and 220 GHz. The 145 GHz band picks up the peak frequency of the CMB spectrum. The 220 GHz band helps accurate removal of the contamination of thermal emission from the Galactic interstellar dust. The MKID arrays (138 MKIDs for 145GHz and 23 MKIDs for 220GHz) were designed and optimized so as to minimize the contamination of the two-level-system noise and maximize the sensitivity. The MKID arrays were successfully installed in May 2023 after the performance verification tests were performed at a laboratory. GroundBIRD has been upgraded to use the full MKID arrays, and scientific observations are now underway. The telescope is automated, so that all observations are performed remotely. Initial validations, including polarization response tests and observations of Jupiter and the moon, have been completed successfully. We are now running scientific observations.
  • Miki Kurihara, Masahiro Tsujimoto, Megan E. Eckart, Caroline A. Kilbourne, Frederick T. Matsuda, Brian McLaughlin, Shugo Oguri, Frederick S. Porter, Yoh Takei, Yoichi Kochibe
    SPACE TELESCOPES AND INSTRUMENTATION 2022: ULTRAVIOLET TO GAMMA RAY, 12181, Mar 2, 2023  
    Electromagnetic interference (EMI) for low-temperature detectors is a serious concern in many missions. We investigate the EMI caused by the spacecraft components to the x-ray microcalorimeter of the Resolve instrument onboard the X-Ray Imaging and Spectroscopy Mission (XRISM), which is currently under development by an international collaboration and is planned to be launched in 2023. We focus on the EMI from (a) the low-frequency magnetic field generated by the magnetic torquers (MTQ) used for the spacecraft attitude control and (b) the radio-frequency (RF) electromagnetic field generated by the S and X band antennas used for communication between the spacecraft and the ground stations. We executed a series of ground tests both at the instrument and spacecraft levels using the flight-model hardware in 2021-2022 in a JAXA facility in Tsukuba. We also conducted electromagnetic simulations partially using the Fugaku high-performance computing facility. The MTQs were found to couple with the microcalorimeter, which we speculate through pick-ups of low-frequency magnetic field and further capacitive coupling. There is no evidence that the resultant energy resolution degradation is beyond the current allocation of noise budget. The RF communication system was found to leave no significant effect. We present the result of the tests and simulation in this article.
  • 末野慶徳, 池満拓司, 石田秀郷, 石田秀郷, 石塚光, 内田智久, 内田智久, 大谷知行, 小栗秀悟, 唐津謙一, 唐津謙一, 木内健司, 沓間弘樹, 沓間弘樹, 小峯順太, 古谷野凌, 鈴木惇也, 関本裕太郎, 田井野徹, 田島治, 田中智永, 辻悠汰, 辻悠汰, 辻井未来, 富田望, 永井誠, 長崎岳人, 成瀬雅人, 羽澄昌史, 羽澄昌史, 服部誠, 本多俊介, 美馬覚, 吉田光宏, 吉田光宏, CHOI Jihoon, GENOVA-SANTOS Ricardo Tanausu, JO Yonggil, LEE Kyungmin, PEEL Michael, REBOLO Rafael, RUBINO-MARTIN Jose Alberto, WON Eunil
    日本物理学会講演概要集(CD-ROM), 78(1), 2023  
  • 辻井未来, 池満拓司, 石田秀郷, 石田秀郷, 石塚光, 内田智久, 内田智久, 大谷知行, 小栗秀悟, 唐津謙一, 木内健司, 沓間弘樹, 小峯順太, 古谷野凌, 末野慶徳, 鈴木惇也, 関本裕太郎, 田井野徹, 田島治, 田中智永, 辻悠汰, 辻悠汰, 富田望, 永井誠, 長崎岳人, 成瀬雅人, 羽澄昌史, 羽澄昌史, 服部誠, 本多俊介, 美馬覚, 吉田光宏, 吉田光宏, CHOI Jihoon, GENOVA-SANTOS Ricardo Tanausu, JO Yonggil, LEE Kyungmin, PEEL Michael, REBOLO Rafael, RUBINO-MARTIN Jose Alberto, WON Eunil
    日本天文学会年会講演予稿集, 2023, 2023  
  • 末野慶徳, 池満拓司, 石田秀郷, 石田秀郷, 石塚光, 内田智久, 内田智久, 大谷知行, 小栗秀悟, 唐津謙一, 唐津謙一, 木内健司, 沓間弘樹, 沓間弘樹, 小峯順太, 古谷野凌, 鈴木惇也, 関本裕太郎, 田井野徹, 田島治, 田中智永, 辻悠汰, 辻悠汰, 辻井未来, 富田望, 永井誠, 長崎岳人, 成瀬雅人, 羽澄昌史, 羽澄昌史, 服部誠, 本多俊介, 美馬覚, 吉田光宏, 吉田光宏, CHOI Jihoon, GENOVA-SANTOS Ricardo Tanausu, JO Yonggil, LEE Kyungmin, PEEL Michael, REBOLO Rafael, RUBINO-MARTIN Jose Alberto, WON Eunil
    日本物理学会講演概要集(CD-ROM), 78(2), 2023  

Major Presentations

 79

Professional Memberships

 2

Research Projects

 10

Industrial Property Rights

 2