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Autori principali: Takacs, Endre, Staiger, Hunter, Blundell, Steven A., Kimura, Naoki, Sakaue, Hiroyuki A., Ruiz, Ronald F. Garcia, Nazarewicz, Witold, Reinhard, Paul-Gerhard, Faiyaz, Chowdhury A., Suzuki, Chihiro, Dipti, Angeli, István, Ralchenko, Yuri, Murakami, Izumi, Kato, Daiji, Nagai, Yuki, Takaoka, Ryuji, Miya, Yoshiki, Nakamura, Nobuyuki
Natura: Preprint
Pubblicazione: 2025
Soggetti:
Accesso online:https://arxiv.org/abs/2511.19395
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author Takacs, Endre
Staiger, Hunter
Blundell, Steven A.
Kimura, Naoki
Sakaue, Hiroyuki A.
Ruiz, Ronald F. Garcia
Nazarewicz, Witold
Reinhard, Paul-Gerhard
Faiyaz, Chowdhury A.
Suzuki, Chihiro
Dipti
Angeli, István
Ralchenko, Yuri
Murakami, Izumi
Kato, Daiji
Nagai, Yuki
Takaoka, Ryuji
Miya, Yoshiki
Nakamura, Nobuyuki
author_facet Takacs, Endre
Staiger, Hunter
Blundell, Steven A.
Kimura, Naoki
Sakaue, Hiroyuki A.
Ruiz, Ronald F. Garcia
Nazarewicz, Witold
Reinhard, Paul-Gerhard
Faiyaz, Chowdhury A.
Suzuki, Chihiro
Dipti
Angeli, István
Ralchenko, Yuri
Murakami, Izumi
Kato, Daiji
Nagai, Yuki
Takaoka, Ryuji
Miya, Yoshiki
Nakamura, Nobuyuki
contents The nuclear charge radius is a fundamental observable that encodes key aspects of nuclear structure, deformation, and pairing. Isotonic (constant neutron number) systematics in the deformed rare-earth region have long suggested that odd-$Z$ nuclei are more compact than their even-$Z$ neighbors - except for Lu, whose recommended radius appeared anomalously large relative to Yb and Hf. We report a high-precision determination of the natural-abundance-averaged Lu-Yb charge-radius difference using extreme-ultraviolet spectroscopy of highly charged Na-like and Mg-like ions, supported by high-accuracy relativistic atomic-structure calculations - a recently introduced method with the unique ability to measure inter-element charge radius differences. Combined with muonic-atom and optical isotope-shift data, our result resolves the longstanding Lu inversion anomaly and reestablishes a pronounced odd-even staggering along the $N=94$ isotonic chain. The magnitude of this staggering is unexpectedly large, far exceeding that observed in semi-magic nuclei and in deformed isotopic sequences. State-of-the-art nuclear density functional theory calculations, including quantified uncertainties, fail to reproduce this enhancement, possibly indicating missing structural effects in current models. Our work demonstrates the power of highly charged ions for precise, element-crossing charge-radius measurements and provides stringent new constraints for future theoretical and experimental studies of nuclear-size systematics.
format Preprint
id arxiv_https___arxiv_org_abs_2511_19395
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Puzzling Isotonic Odd-Even Staggering of Charge Radii in Deformed Rare Earth Nuclei
Takacs, Endre
Staiger, Hunter
Blundell, Steven A.
Kimura, Naoki
Sakaue, Hiroyuki A.
Ruiz, Ronald F. Garcia
Nazarewicz, Witold
Reinhard, Paul-Gerhard
Faiyaz, Chowdhury A.
Suzuki, Chihiro
Dipti
Angeli, István
Ralchenko, Yuri
Murakami, Izumi
Kato, Daiji
Nagai, Yuki
Takaoka, Ryuji
Miya, Yoshiki
Nakamura, Nobuyuki
Atomic Physics
Nuclear Experiment
The nuclear charge radius is a fundamental observable that encodes key aspects of nuclear structure, deformation, and pairing. Isotonic (constant neutron number) systematics in the deformed rare-earth region have long suggested that odd-$Z$ nuclei are more compact than their even-$Z$ neighbors - except for Lu, whose recommended radius appeared anomalously large relative to Yb and Hf. We report a high-precision determination of the natural-abundance-averaged Lu-Yb charge-radius difference using extreme-ultraviolet spectroscopy of highly charged Na-like and Mg-like ions, supported by high-accuracy relativistic atomic-structure calculations - a recently introduced method with the unique ability to measure inter-element charge radius differences. Combined with muonic-atom and optical isotope-shift data, our result resolves the longstanding Lu inversion anomaly and reestablishes a pronounced odd-even staggering along the $N=94$ isotonic chain. The magnitude of this staggering is unexpectedly large, far exceeding that observed in semi-magic nuclei and in deformed isotopic sequences. State-of-the-art nuclear density functional theory calculations, including quantified uncertainties, fail to reproduce this enhancement, possibly indicating missing structural effects in current models. Our work demonstrates the power of highly charged ions for precise, element-crossing charge-radius measurements and provides stringent new constraints for future theoretical and experimental studies of nuclear-size systematics.
title Puzzling Isotonic Odd-Even Staggering of Charge Radii in Deformed Rare Earth Nuclei
topic Atomic Physics
Nuclear Experiment
url https://arxiv.org/abs/2511.19395