78                         Ni revealed as a doubly magic stronghold against nuclear deformation

R. Taniuchi; C. Santamaria; P. Doornenbal; A. Obertelli; K. Yoneda; G. Authelet; H. Baba; D. Calvet; F. Château; A. Corsi; A. Delbart; J. M. Gheller; A. Gillibert; J. D. Holt; T. Isobe; V. Lapoux; M. Matsushita; J. Menéndez; S. Momiyama; T. Motobayashi; M. Niikura; F. Nowacki; K. Ogata; H. Otsu; T. Otsuka; C. Péron; S. Péru; A. Peyaud; E. C. Pollacco; A. Poves; J. Y. Roussé; H. Sakurai; A. Schwenk; Y. Shiga; J. Simonis; S. R. Stroberg; S. Takeuchi; Y. Tsunoda; T. Uesaka; H. Wang; F. Browne; L. X. Chung; Z. Dombradi; S. Franchoo; F. Giacoppo; A. Gottardo; K. Hadyńska-Klęk; Z. Korkulu; S. Koyama; Y. Kubota; J. Lee; M. Lettmann; C. Louchart; R. Lozeva; K. Matsui; T. Miyazaki; S. Nishimura; L. Olivier; S. Ota; Z. Patel; E. Şahin; C. Shand; P. A. Söderström; I. Stefan; D. Steppenbeck; T. Sumikama; D. Suzuki; Z. Vajta; V. Werner; J. Wu; Z. Y. Xu

doi:10.1038/s41586-019-1155-x

⁷⁸ Ni revealed as a doubly magic stronghold against nuclear deformation

R. Taniuchi, C. Santamaria, P. Doornenbal, A. Obertelli, K. Yoneda, G. Authelet, H. Baba, D. Calvet, F. Château, A. Corsi, A. Delbart, J. M. Gheller, A. Gillibert, J. D. Holt, T. Isobe, V. Lapoux, M. Matsushita, J. Menéndez, S. Momiyama, T. MotobayashiM. Niikura, F. Nowacki, K. Ogata, H. Otsu, T. Otsuka, C. Péron, S. Péru, A. Peyaud, E. C. Pollacco, A. Poves, J. Y. Roussé, H. Sakurai, A. Schwenk, Y. Shiga, J. Simonis, S. R. Stroberg, S. Takeuchi, Y. Tsunoda, T. Uesaka, H. Wang, F. Browne, L. X. Chung, Z. Dombradi, S. Franchoo, F. Giacoppo, A. Gottardo, K. Hadyńska-Klęk, Z. Korkulu, S. Koyama, Y. Kubota, J. Lee, M. Lettmann, C. Louchart, R. Lozeva, K. Matsui, T. Miyazaki, S. Nishimura, L. Olivier, S. Ota, Z. Patel, E. Şahin, C. Shand, P. A. Söderström, I. Stefan, D. Steppenbeck, T. Sumikama, D. Suzuki, Z. Vajta, V. Werner, J. Wu, Z. Y. Xu

研究成果: ジャーナルへの寄稿 › 学術誌 › 査読

88 被引用数 (Scopus)

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Nuclear magic numbers correspond to fully occupied energy shells of protons or neutrons inside atomic nuclei. Doubly magic nuclei, with magic numbers for both protons and neutrons, are spherical and extremely rare across the nuclear landscape. Although the sequence of magic numbers is well established for stable nuclei, experimental evidence has revealed modifications for nuclei with a large asymmetry between proton and neutron numbers. Here we provide a spectroscopic study of the doubly magic nucleus ⁷⁸ Ni, which contains fourteen neutrons more than the heaviest stable nickel isotope. We provide direct evidence of its doubly magic nature, which is also predicted by ab initio calculations based on chiral effective-field theory interactions and the quasi-particle random-phase approximation. Our results also indicate the breakdown of the neutron magic number 50 and proton magic number 28 beyond this stronghold, caused by a competing deformed structure. State-of-the-art phenomenological shell-model calculations reproduce this shape coexistence, predicting a rapid transition from spherical to deformed ground states, with ⁷⁸ Ni as the turning point.

本文言語	英語
ページ（範囲）	53-58
ページ数	6
ジャーナル	Nature
巻	569
号	7754
DOI	https://doi.org/10.1038/s41586-019-1155-x
出版ステータス	出版済み - 5月 2 2019
外部発表	はい

!!!All Science Journal Classification (ASJC) codes

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10.1038/s41586-019-1155-x

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Taniuchi, R., Santamaria, C., Doornenbal, P., Obertelli, A., Yoneda, K., Authelet, G., Baba, H., Calvet, D., Château, F., Corsi, A., Delbart, A., Gheller, J. M., Gillibert, A., Holt, J. D., Isobe, T., Lapoux, V., Matsushita, M., Menéndez, J., Momiyama, S., ... Xu, Z. Y. (2019). ⁷⁸ Ni revealed as a doubly magic stronghold against nuclear deformation Nature, 569(7754), 53-58. https://doi.org/10.1038/s41586-019-1155-x

Taniuchi, R, Santamaria, C, Doornenbal, P, Obertelli, A, Yoneda, K, Authelet, G, Baba, H, Calvet, D, Château, F, Corsi, A, Delbart, A, Gheller, JM, Gillibert, A, Holt, JD, Isobe, T, Lapoux, V, Matsushita, M, Menéndez, J, Momiyama, S, Motobayashi, T, Niikura, M, Nowacki, F, Ogata, K, Otsu, H, Otsuka, T, Péron, C, Péru, S, Peyaud, A, Pollacco, EC, Poves, A, Roussé, JY, Sakurai, H, Schwenk, A, Shiga, Y, Simonis, J, Stroberg, SR, Takeuchi, S, Tsunoda, Y, Uesaka, T, Wang, H, Browne, F, Chung, LX, Dombradi, Z, Franchoo, S, Giacoppo, F, Gottardo, A, Hadyńska-Klęk, K, Korkulu, Z, Koyama, S, Kubota, Y, Lee, J, Lettmann, M, Louchart, C, Lozeva, R, Matsui, K, Miyazaki, T, Nishimura, S, Olivier, L, Ota, S, Patel, Z, Şahin, E, Shand, C, Söderström, PA, Stefan, I, Steppenbeck, D, Sumikama, T, Suzuki, D, Vajta, Z, Werner, V, Wu, J & Xu, ZY 2019, '⁷⁸ Ni revealed as a doubly magic stronghold against nuclear deformation ', Nature, vol. 569, no. 7754, pp. 53-58. https://doi.org/10.1038/s41586-019-1155-x

@article{8feb682294eb412ea8db39ffaf0dccf7,

title = "78 Ni revealed as a doubly magic stronghold against nuclear deformation ",

abstract = " Nuclear magic numbers correspond to fully occupied energy shells of protons or neutrons inside atomic nuclei. Doubly magic nuclei, with magic numbers for both protons and neutrons, are spherical and extremely rare across the nuclear landscape. Although the sequence of magic numbers is well established for stable nuclei, experimental evidence has revealed modifications for nuclei with a large asymmetry between proton and neutron numbers. Here we provide a spectroscopic study of the doubly magic nucleus 78 Ni, which contains fourteen neutrons more than the heaviest stable nickel isotope. We provide direct evidence of its doubly magic nature, which is also predicted by ab initio calculations based on chiral effective-field theory interactions and the quasi-particle random-phase approximation. Our results also indicate the breakdown of the neutron magic number 50 and proton magic number 28 beyond this stronghold, caused by a competing deformed structure. State-of-the-art phenomenological shell-model calculations reproduce this shape coexistence, predicting a rapid transition from spherical to deformed ground states, with 78 Ni as the turning point.",

author = "R. Taniuchi and C. Santamaria and P. Doornenbal and A. Obertelli and K. Yoneda and G. Authelet and H. Baba and D. Calvet and F. Ch{\^a}teau and A. Corsi and A. Delbart and Gheller, {J. M.} and A. Gillibert and Holt, {J. D.} and T. Isobe and V. Lapoux and M. Matsushita and J. Men{\'e}ndez and S. Momiyama and T. Motobayashi and M. Niikura and F. Nowacki and K. Ogata and H. Otsu and T. Otsuka and C. P{\'e}ron and S. P{\'e}ru and A. Peyaud and Pollacco, {E. C.} and A. Poves and Rouss{\'e}, {J. Y.} and H. Sakurai and A. Schwenk and Y. Shiga and J. Simonis and Stroberg, {S. R.} and S. Takeuchi and Y. Tsunoda and T. Uesaka and H. Wang and F. Browne and Chung, {L. X.} and Z. Dombradi and S. Franchoo and F. Giacoppo and A. Gottardo and K. Hady{\'n}ska-Kl{\c e}k and Z. Korkulu and S. Koyama and Y. Kubota and J. Lee and M. Lettmann and C. Louchart and R. Lozeva and K. Matsui and T. Miyazaki and S. Nishimura and L. Olivier and S. Ota and Z. Patel and E. {\c S}ahin and C. Shand and S{\"o}derstr{\"o}m, {P. A.} and I. Stefan and D. Steppenbeck and T. Sumikama and D. Suzuki and Z. Vajta and V. Werner and J. Wu and Xu, {Z. Y.}",

note = "Funding Information: Acknowledgements We thank the staff of the RIKEN Nishina Center accelerator complex for providing a stable and high-intensity uranium beam and the BigRIPS team for the smooth operation of the secondary beams. We also thank N. Miyauchi for 3D schematic of the RIBF facility shown in Fig. 2a. The development of MINOS and the core MINOS team have been supported by the European Research Council through ERC grant number MINOS-258567. R.T. was supported by JSPS Grant-in-Aid for JSPS Research Fellows JP14J08717. A.O. was supported by JSPS long-term fellowship L-13520 at the RIKEN Nishina Center. C. Santamaria was supported by the IPA programme at the RIKEN Nishina Center. J.D.H. acknowledges support by the National Research Council of Canada and NSERC. This work was supported in part by the ERC through grant number 307986 STRONGINT, the DFG under grant SFB 1245 and the BMBF under contract number 05P18RDFN1. The MCSM calculations were performed on the K computer at RIKEN AICS (hp160211, hp170230, hp180179). J.M., T.O. and Y.T. acknowledge support from MEXT as {\textquoteleft}Priority Issue on post-K computer{\textquoteright} (Elucidation of the Fundamental Laws and Evolution of the Universe) and JICFuS. J.M. and K.O. were supported by Grant-in-Aid for Scientific Research JP18K03639 (J.M.) and JP16K05352 (K.O.). A. Poves acknowledges support by Mineco (Spain) grants FPA2014-57916 and Severo Ochoa Program SEV-2016-0597. This work was supported in part by the DFG through the Cluster of Excellence PRISMA. L.X.C. was supported by Vietnam MOST through the Physics Development Program grant TLCN.25/18. Z.D., Z.K. and Z.V. acknowledge support from the GINOP-2.3.3-15-2016-00034 project. M.L, C.L and V.W. acknowledge support from the German BMBF through grants 05P15RDNF1 and 05P12RDNF8. Publisher Copyright: {\textcopyright} 2019, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2019",

month = may,

day = "2",

doi = "10.1038/s41586-019-1155-x",

language = "English",

volume = "569",

pages = "53--58",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Publishing Group",

number = "7754",

}

TY - JOUR

T1 - 78 Ni revealed as a doubly magic stronghold against nuclear deformation

AU - Taniuchi, R.

AU - Santamaria, C.

AU - Doornenbal, P.

AU - Obertelli, A.

AU - Yoneda, K.

AU - Authelet, G.

AU - Baba, H.

AU - Calvet, D.

AU - Château, F.

AU - Corsi, A.

AU - Delbart, A.

AU - Gheller, J. M.

AU - Gillibert, A.

AU - Holt, J. D.

AU - Isobe, T.

AU - Lapoux, V.

AU - Matsushita, M.

AU - Menéndez, J.

AU - Momiyama, S.

AU - Motobayashi, T.

AU - Niikura, M.

AU - Nowacki, F.

AU - Ogata, K.

AU - Otsu, H.

AU - Otsuka, T.

AU - Péron, C.

AU - Péru, S.

AU - Peyaud, A.

AU - Pollacco, E. C.

AU - Poves, A.

AU - Roussé, J. Y.

AU - Sakurai, H.

AU - Schwenk, A.

AU - Shiga, Y.

AU - Simonis, J.

AU - Stroberg, S. R.

AU - Takeuchi, S.

AU - Tsunoda, Y.

AU - Uesaka, T.

AU - Wang, H.

AU - Browne, F.

AU - Chung, L. X.

AU - Dombradi, Z.

AU - Franchoo, S.

AU - Giacoppo, F.

AU - Gottardo, A.

AU - Hadyńska-Klęk, K.

AU - Korkulu, Z.

AU - Koyama, S.

AU - Kubota, Y.

AU - Lee, J.

AU - Lettmann, M.

AU - Louchart, C.

AU - Lozeva, R.

AU - Matsui, K.

AU - Miyazaki, T.

AU - Nishimura, S.

AU - Olivier, L.

AU - Ota, S.

AU - Patel, Z.

AU - Şahin, E.

AU - Shand, C.

AU - Söderström, P. A.

AU - Stefan, I.

AU - Steppenbeck, D.

AU - Sumikama, T.

AU - Suzuki, D.

AU - Vajta, Z.

AU - Werner, V.

AU - Wu, J.

AU - Xu, Z. Y.

N1 - Funding Information: Acknowledgements We thank the staff of the RIKEN Nishina Center accelerator complex for providing a stable and high-intensity uranium beam and the BigRIPS team for the smooth operation of the secondary beams. We also thank N. Miyauchi for 3D schematic of the RIBF facility shown in Fig. 2a. The development of MINOS and the core MINOS team have been supported by the European Research Council through ERC grant number MINOS-258567. R.T. was supported by JSPS Grant-in-Aid for JSPS Research Fellows JP14J08717. A.O. was supported by JSPS long-term fellowship L-13520 at the RIKEN Nishina Center. C. Santamaria was supported by the IPA programme at the RIKEN Nishina Center. J.D.H. acknowledges support by the National Research Council of Canada and NSERC. This work was supported in part by the ERC through grant number 307986 STRONGINT, the DFG under grant SFB 1245 and the BMBF under contract number 05P18RDFN1. The MCSM calculations were performed on the K computer at RIKEN AICS (hp160211, hp170230, hp180179). J.M., T.O. and Y.T. acknowledge support from MEXT as ‘Priority Issue on post-K computer’ (Elucidation of the Fundamental Laws and Evolution of the Universe) and JICFuS. J.M. and K.O. were supported by Grant-in-Aid for Scientific Research JP18K03639 (J.M.) and JP16K05352 (K.O.). A. Poves acknowledges support by Mineco (Spain) grants FPA2014-57916 and Severo Ochoa Program SEV-2016-0597. This work was supported in part by the DFG through the Cluster of Excellence PRISMA. L.X.C. was supported by Vietnam MOST through the Physics Development Program grant TLCN.25/18. Z.D., Z.K. and Z.V. acknowledge support from the GINOP-2.3.3-15-2016-00034 project. M.L, C.L and V.W. acknowledge support from the German BMBF through grants 05P15RDNF1 and 05P12RDNF8. Publisher Copyright: © 2019, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2019/5/2

Y1 - 2019/5/2

N2 - Nuclear magic numbers correspond to fully occupied energy shells of protons or neutrons inside atomic nuclei. Doubly magic nuclei, with magic numbers for both protons and neutrons, are spherical and extremely rare across the nuclear landscape. Although the sequence of magic numbers is well established for stable nuclei, experimental evidence has revealed modifications for nuclei with a large asymmetry between proton and neutron numbers. Here we provide a spectroscopic study of the doubly magic nucleus 78 Ni, which contains fourteen neutrons more than the heaviest stable nickel isotope. We provide direct evidence of its doubly magic nature, which is also predicted by ab initio calculations based on chiral effective-field theory interactions and the quasi-particle random-phase approximation. Our results also indicate the breakdown of the neutron magic number 50 and proton magic number 28 beyond this stronghold, caused by a competing deformed structure. State-of-the-art phenomenological shell-model calculations reproduce this shape coexistence, predicting a rapid transition from spherical to deformed ground states, with 78 Ni as the turning point.

AB - Nuclear magic numbers correspond to fully occupied energy shells of protons or neutrons inside atomic nuclei. Doubly magic nuclei, with magic numbers for both protons and neutrons, are spherical and extremely rare across the nuclear landscape. Although the sequence of magic numbers is well established for stable nuclei, experimental evidence has revealed modifications for nuclei with a large asymmetry between proton and neutron numbers. Here we provide a spectroscopic study of the doubly magic nucleus 78 Ni, which contains fourteen neutrons more than the heaviest stable nickel isotope. We provide direct evidence of its doubly magic nature, which is also predicted by ab initio calculations based on chiral effective-field theory interactions and the quasi-particle random-phase approximation. Our results also indicate the breakdown of the neutron magic number 50 and proton magic number 28 beyond this stronghold, caused by a competing deformed structure. State-of-the-art phenomenological shell-model calculations reproduce this shape coexistence, predicting a rapid transition from spherical to deformed ground states, with 78 Ni as the turning point.

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U2 - 10.1038/s41586-019-1155-x

DO - 10.1038/s41586-019-1155-x

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SP - 53

EP - 58

JO - Nature

JF - Nature

IS - 7754

ER -

78 Ni revealed as a doubly magic stronghold against nuclear deformation

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⁷⁸ Ni revealed as a doubly magic stronghold against nuclear deformation