X-ray pumping of the 229Th nuclear clock isomer

Takahiko Masuda; Akihiro Yoshimi; Akira Fujieda; Hiroyuki Fujimoto; Hiromitsu Haba; Hideaki Hara; Takahiro Hiraki; Hiroyuki Kaino; Yoshitaka Kasamatsu; Shinji Kitao; Kenji Konashi; Yuki Miyamoto; Koichi Okai; Sho Okubo; Noboru Sasao; Makoto Seto; Thorsten Schumm; Yudai Shigekawa; Kenta Suzuki; Simon Stellmer; Kenji Tamasaku; Satoshi Uetake; Makoto Watanabe; Tsukasa Watanabe; Yuki Yasuda; Atsushi Yamaguchi; Yoshitaka Yoda; Takuya Yokokita; Motohiko Yoshimura; Koji Yoshimura

doi:10.1038/s41586-019-1542-3

X-ray pumping of the ²²⁹Th nuclear clock isomer

Takahiko Masuda, Akihiro Yoshimi, Akira Fujieda, Hiroyuki Fujimoto, Hiromitsu Haba, Hideaki Hara, Takahiro Hiraki, Hiroyuki Kaino, Yoshitaka Kasamatsu, Shinji Kitao, Kenji Konashi, Yuki Miyamoto, Koichi Okai, Sho Okubo, Noboru Sasao, Makoto Seto, Thorsten Schumm, Yudai Shigekawa, Kenta Suzuki, Simon StellmerKenji Tamasaku, Satoshi Uetake, Makoto Watanabe, Tsukasa Watanabe, Yuki Yasuda, Atsushi Yamaguchi, Yoshitaka Yoda, Takuya Yokokita, Motohiko Yoshimura, Koji Yoshimura

金属材料研究所・附属量子エネルギー材料科学国際研究センター

研究成果: Article › 査読

46 被引用数 (Scopus)

抄録

The metastable first excited state of thorium-229, ^229mTh, is just a few electronvolts above the nuclear ground state^1–4 and is accessible by vacuum ultraviolet lasers. The ability to manipulate the ²²⁹Th nuclear states with the precision of atomic laser spectroscopy⁵ opens up several prospects⁶, from studies of fundamental interactions in physics^7,8 to applications such as a compact and robust nuclear clock^5,9,10. However, direct optical excitation of the isomer and its radiative decay to the ground state have not yet been observed, and several key nuclear structure parameters—such as the exact energies and half-lives of the low-lying nuclear levels of ²²⁹Th—remain unknown¹¹. Here we present active optical pumping into ^229mTh, achieved using narrow-band 29-kiloelectronvolt synchrotron radiation to resonantly excite the second excited state of ²²⁹Th, which then decays predominantly into the isomer. We determine the resonance energy with an accuracy of 0.07 electronvolts, measure a half-life of 82.2 picoseconds and an excitation linewidth of 1.70 nanoelectronvolts, and extract the branching ratio of the second excited state into the ground and isomeric state. These measurements allow us to constrain the ^229mTh isomer energy by combining them with γ-spectroscopy data collected over the past 40 years.

本文言語	English
ページ（範囲）	238-242
ページ数	5
ジャーナル	Nature
巻	573
号	7773
DOI	https://doi.org/10.1038/s41586-019-1542-3
出版ステータス	Published - 2019 9月 12

ASJC Scopus subject areas

一般

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10.1038/s41586-019-1542-3

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引用スタイル

Masuda, T., Yoshimi, A., Fujieda, A., Fujimoto, H., Haba, H., Hara, H., Hiraki, T., Kaino, H., Kasamatsu, Y., Kitao, S., Konashi, K., Miyamoto, Y., Okai, K., Okubo, S., Sasao, N., Seto, M., Schumm, T., Shigekawa, Y., Suzuki, K., ... Yoshimura, K. (2019). X-ray pumping of the ²²⁹Th nuclear clock isomer. Nature, 573(7773), 238-242. https://doi.org/10.1038/s41586-019-1542-3

Masuda, T, Yoshimi, A, Fujieda, A, Fujimoto, H, Haba, H, Hara, H, Hiraki, T, Kaino, H, Kasamatsu, Y, Kitao, S, Konashi, K, Miyamoto, Y, Okai, K, Okubo, S, Sasao, N, Seto, M, Schumm, T, Shigekawa, Y, Suzuki, K, Stellmer, S, Tamasaku, K, Uetake, S, Watanabe, M, Watanabe, T, Yasuda, Y, Yamaguchi, A, Yoda, Y, Yokokita, T, Yoshimura, M & Yoshimura, K 2019, 'X-ray pumping of the ²²⁹Th nuclear clock isomer', Nature, vol. 573, no. 7773, pp. 238-242. https://doi.org/10.1038/s41586-019-1542-3

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title = "X-ray pumping of the 229Th nuclear clock isomer",

abstract = "The metastable first excited state of thorium-229, 229mTh, is just a few electronvolts above the nuclear ground state1–4 and is accessible by vacuum ultraviolet lasers. The ability to manipulate the 229Th nuclear states with the precision of atomic laser spectroscopy5 opens up several prospects6, from studies of fundamental interactions in physics7,8 to applications such as a compact and robust nuclear clock5,9,10. However, direct optical excitation of the isomer and its radiative decay to the ground state have not yet been observed, and several key nuclear structure parameters—such as the exact energies and half-lives of the low-lying nuclear levels of 229Th—remain unknown11. Here we present active optical pumping into 229mTh, achieved using narrow-band 29-kiloelectronvolt synchrotron radiation to resonantly excite the second excited state of 229Th, which then decays predominantly into the isomer. We determine the resonance energy with an accuracy of 0.07 electronvolts, measure a half-life of 82.2 picoseconds and an excitation linewidth of 1.70 nanoelectronvolts, and extract the branching ratio of the second excited state into the ground and isomeric state. These measurements allow us to constrain the 229mTh isomer energy by combining them with γ-spectroscopy data collected over the past 40 years.",

author = "Takahiko Masuda and Akihiro Yoshimi and Akira Fujieda and Hiroyuki Fujimoto and Hiromitsu Haba and Hideaki Hara and Takahiro Hiraki and Hiroyuki Kaino and Yoshitaka Kasamatsu and Shinji Kitao and Kenji Konashi and Yuki Miyamoto and Koichi Okai and Sho Okubo and Noboru Sasao and Makoto Seto and Thorsten Schumm and Yudai Shigekawa and Kenta Suzuki and Simon Stellmer and Kenji Tamasaku and Satoshi Uetake and Makoto Watanabe and Tsukasa Watanabe and Yuki Yasuda and Atsushi Yamaguchi and Yoshitaka Yoda and Takuya Yokokita and Motohiko Yoshimura and Koji Yoshimura",

note = "Funding Information: Acknowledgements The synchrotron radiation experiments were performed at the BL09XU and BL19LXU lines of SPring-8 with the approval of the Japan Synchrotron Radiation Research Institute (JASRI) (proposals 2016B1232, 2017B1335, 2018A1326 and 2018B1436) and RIKEN (proposal number 20180045). We thank all members of the SPring-8 operation and supporting teams. The experiment received support from the KEK Photon Factory (proposal number 2017G085) and the Institute for Materials Research, Tohoku University (18F0014), where indispensable detector tests and target preparation were performed. We especially thank S. Kishimoto for support at KEK, T. Kobayashi for technical assistance at SPring-8 and K. Beeks for discussion during the preparation of the manuscript. This work was supported by JSPS KAKENHI grants JP15H03661, JP17K14291, JP18H01230 and JP18H04353. T.S. and S.S. gratefully acknowledge funding by the EU FET-Open project, grant number 664732 (nuClock). A. Yoshimi and A. Yamaguchi acknowledge the MATSUO foundation and Technology Pioneering Projects in RIKEN, respectively. Publisher Copyright: {\textcopyright} 2019, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2019",

month = sep,

day = "12",

doi = "10.1038/s41586-019-1542-3",

language = "English",

volume = "573",

pages = "238--242",

journal = "Nature",

issn = "0028-0836",

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TY - JOUR

T1 - X-ray pumping of the 229Th nuclear clock isomer

AU - Masuda, Takahiko

AU - Yoshimi, Akihiro

AU - Fujieda, Akira

AU - Fujimoto, Hiroyuki

AU - Haba, Hiromitsu

AU - Hara, Hideaki

AU - Hiraki, Takahiro

AU - Kaino, Hiroyuki

AU - Kasamatsu, Yoshitaka

AU - Kitao, Shinji

AU - Konashi, Kenji

AU - Miyamoto, Yuki

AU - Okai, Koichi

AU - Okubo, Sho

AU - Sasao, Noboru

AU - Seto, Makoto

AU - Schumm, Thorsten

AU - Shigekawa, Yudai

AU - Suzuki, Kenta

AU - Stellmer, Simon

AU - Tamasaku, Kenji

AU - Uetake, Satoshi

AU - Watanabe, Makoto

AU - Watanabe, Tsukasa

AU - Yasuda, Yuki

AU - Yamaguchi, Atsushi

AU - Yoda, Yoshitaka

AU - Yokokita, Takuya

AU - Yoshimura, Motohiko

AU - Yoshimura, Koji

N1 - Funding Information: Acknowledgements The synchrotron radiation experiments were performed at the BL09XU and BL19LXU lines of SPring-8 with the approval of the Japan Synchrotron Radiation Research Institute (JASRI) (proposals 2016B1232, 2017B1335, 2018A1326 and 2018B1436) and RIKEN (proposal number 20180045). We thank all members of the SPring-8 operation and supporting teams. The experiment received support from the KEK Photon Factory (proposal number 2017G085) and the Institute for Materials Research, Tohoku University (18F0014), where indispensable detector tests and target preparation were performed. We especially thank S. Kishimoto for support at KEK, T. Kobayashi for technical assistance at SPring-8 and K. Beeks for discussion during the preparation of the manuscript. This work was supported by JSPS KAKENHI grants JP15H03661, JP17K14291, JP18H01230 and JP18H04353. T.S. and S.S. gratefully acknowledge funding by the EU FET-Open project, grant number 664732 (nuClock). A. Yoshimi and A. Yamaguchi acknowledge the MATSUO foundation and Technology Pioneering Projects in RIKEN, respectively. Publisher Copyright: © 2019, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2019/9/12

Y1 - 2019/9/12

N2 - The metastable first excited state of thorium-229, 229mTh, is just a few electronvolts above the nuclear ground state1–4 and is accessible by vacuum ultraviolet lasers. The ability to manipulate the 229Th nuclear states with the precision of atomic laser spectroscopy5 opens up several prospects6, from studies of fundamental interactions in physics7,8 to applications such as a compact and robust nuclear clock5,9,10. However, direct optical excitation of the isomer and its radiative decay to the ground state have not yet been observed, and several key nuclear structure parameters—such as the exact energies and half-lives of the low-lying nuclear levels of 229Th—remain unknown11. Here we present active optical pumping into 229mTh, achieved using narrow-band 29-kiloelectronvolt synchrotron radiation to resonantly excite the second excited state of 229Th, which then decays predominantly into the isomer. We determine the resonance energy with an accuracy of 0.07 electronvolts, measure a half-life of 82.2 picoseconds and an excitation linewidth of 1.70 nanoelectronvolts, and extract the branching ratio of the second excited state into the ground and isomeric state. These measurements allow us to constrain the 229mTh isomer energy by combining them with γ-spectroscopy data collected over the past 40 years.

AB - The metastable first excited state of thorium-229, 229mTh, is just a few electronvolts above the nuclear ground state1–4 and is accessible by vacuum ultraviolet lasers. The ability to manipulate the 229Th nuclear states with the precision of atomic laser spectroscopy5 opens up several prospects6, from studies of fundamental interactions in physics7,8 to applications such as a compact and robust nuclear clock5,9,10. However, direct optical excitation of the isomer and its radiative decay to the ground state have not yet been observed, and several key nuclear structure parameters—such as the exact energies and half-lives of the low-lying nuclear levels of 229Th—remain unknown11. Here we present active optical pumping into 229mTh, achieved using narrow-band 29-kiloelectronvolt synchrotron radiation to resonantly excite the second excited state of 229Th, which then decays predominantly into the isomer. We determine the resonance energy with an accuracy of 0.07 electronvolts, measure a half-life of 82.2 picoseconds and an excitation linewidth of 1.70 nanoelectronvolts, and extract the branching ratio of the second excited state into the ground and isomeric state. These measurements allow us to constrain the 229mTh isomer energy by combining them with γ-spectroscopy data collected over the past 40 years.

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