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Ben Roy Mottelson
Ben Roy Mottelson
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Ben Roy Mottelson (9 July 1926 – 13 May 2022) was an American-Danish nuclear physicist. He won the 1975 Nobel Prize in Physics for his work on the non-spherical geometry of atomic nuclei.

Key Information

Early life

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Mottelson was born in Chicago, Illinois, on 9 July 1926, the son of Georgia (Blum) and Goodman Mottelson, an engineer.[1] His family was Jewish.[2] After graduating from Lyons Township High School in La Grange, Illinois, he joined the United States Navy and was sent to attend officers training at Purdue University, where he received a bachelor's degree in 1947. He then earned a PhD in nuclear physics from Harvard University in 1950. His thesis adviser was Julian Schwinger, the theoretical physicist who later won the Nobel Prize in 1965 for his work on quantum electrodynamics.[1]

Career

[edit]

He moved to Institute for Theoretical Physics (later the Niels Bohr Institute) at the University of Copenhagen on the Sheldon Traveling Fellowship from Harvard, and remained in Denmark. In 1953 he was appointed staff member in CERN's Theoretical Study Group, which was based in Copenhagen,[3] a position he held until he became professor at the newly formed Nordic Institute for Theoretical Physics (Nordita) in 1957. He was a visiting professor at the University of California, Berkeley in Spring 1959.[4] In 1971 he became a naturalized Danish citizen.[5]

In 1950–1951, James Rainwater and Aage Bohr had developed models of the atomic nucleus which began to take into account the behaviour of the individual nucleons. These models, which moved beyond the simpler liquid drop treatment of the nucleus as having effectively no internal structure, were the first models which could explain a number of nuclear properties, including the non-spherical distribution of charge in certain nuclei. Mottelson worked with Aage Bohr to compare the theoretical models with experimental data. In 1952–1953, Bohr and Mottelson published a series of papers demonstrating close agreement between theory and experiment, for example showing that the energy levels of certain nuclei could be described by a rotation spectrum.[6][7][8][9] This work stimulated new theoretical and experimental studies.

In the summer of 1957, David Pines visited Copenhagen, and introduced Bohr and Mottelson to the pairing effect developed in theories of superconductivity, which inspired them to introduce a similar pairing effect to explain the differences in the energy levels between even and odd atomic nuclei.[10]

Nobel Prize (1975)

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Rainwater, Bohr and Mottelson were jointly awarded the 1975 Nobel Prize in Physics "for the discovery of the connection between collective motion and particle motion in atomic nuclei and the development of the theory of the structure of the atomic nucleus based on this connection".[11]

Post–Nobel Prize work

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Bohr and Mottelson continued to work together, publishing a two-volume monograph, Nuclear Structure. The first volume, Single-Particle Motion, appeared in 1969,[12][13] and the second volume, Nuclear Deformations, in 1975.[14][15]

Professor Mottelson was a member of the board of sponsors of the Bulletin of the Atomic Scientists.[16]

He was an honorary member of the Finnish Society of Sciences and Letters, a member of the American Philosophical Society,[17] and a foreign fellow of Bangladesh Academy of Sciences[18] and the Norwegian Academy of Science and Letters.[19] In 1969, he received the Atoms for Peace Award.[20] He acted as director of ECT* (Trento, Italy) from 1993 to 1997.[21]

Personal life

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Mottelson was a dual citizen, as he held both Danish and American passports. He lived in Copenhagen. Mottelson was married to Nancy Jane Reno from 1948 until her death in 1975, and they had two sons and one daughter. Mottelson then married Britta Marger Siegumfeldt in 1983.[22]

He died on 13 May 2022, in Copenhagen at the age of 95.[23][24][1]

See also

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References

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Ben Roy Mottelson

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Ben Roy Mottelson (July 9, 1926 – May 13, 2022) was an American-born Danish nuclear physicist who shared the 1975 Nobel Prize in Physics with Aage Bohr and James Rainwater for "the discovery of the connection between collective motion and particle motion in atomic nuclei and the development of the theory of the structure of the atomic nucleus based on this connection." Their collaborative work revolutionized the understanding of nuclear structure by integrating particle and collective motion models, challenging earlier assumptions of spherical nuclei and incorporating distortions caused by nucleon interactions. Born in , , to parents Goodman and Georgia Mottelson, he was the second of three children and grew up in , in a household emphasizing scientific, political, and moral discussions. Mottelson graduated from high school during and enrolled at through the , earning a degree in 1947. He then pursued graduate studies at , completing a PhD in in 1950 under the supervision of . Following his doctorate, Mottelson received a postdoctoral fellowship at the Institute for Theoretical Physics () in , , where he arrived in 1950 and began a long-term collaboration with that would define his career. In 1953, he briefly joined CERN's Theoretical Study Group in before becoming a staff member and, in 1957, a professor at the Nordic Institute for Theoretical Atomic Physics (Nordita), a position he held until 1994. He also served as a visiting professor at the , in 1959. Mottelson naturalized as a Danish citizen in 1971, reflecting his deep integration into the Danish scientific community.

Early life and education

Early life

Ben Roy Mottelson was born on July 9, 1926, in , , to a Jewish family. He was the second of three children born to Goodman Mottelson, an with a university degree, and Georgia Mottelson (née Blum). Mottelson grew up in La Grange, a western suburb of Chicago, where his childhood home was a stimulating environment that encouraged open discussions on scientific, political, and moral topics. These family conversations, influenced by his father's engineering background, sparked his early curiosity in and physics. He attended local primary schools and in La Grange, graduating in 1944 amid . The school's rigorous academic setting further nurtured his interest in scientific pursuits. Following high school, Mottelson enlisted in the U.S. Navy and was selected for the V-12 officer training program, which sent him to . This wartime service marked a pivotal transition toward his higher education in physics.

Education

Mottelson enrolled at through the U.S. Navy's V-12 officer training program during , which provided accelerated education in technical fields to prepare personnel for service. After the war, he completed his studies there and received a degree in physics in 1947. He continued his graduate education at , earning a PhD in physics in 1950 under the supervision of , a leading theoretical physicist known for his work in . Mottelson's doctoral thesis, titled "The Ground States of Lithium 6 and Lithium 7," examined the nuclear structure of these light isotopes through theoretical methods. The work involved single-configuration calculations to determine properties, such as binding energies, quadrupole moments, and energy levels, by adjusting two-body potential parameters to match experimental data on these nuclei.

Scientific career

Early research

Following his PhD from in 1950, which was on the ground states of lithium-6 and lithium-7 under the supervision of , Mottelson secured a Sheldon Traveling Fellowship that enabled him to join the Institute for Theoretical Physics in for the 1950–1951 academic year, at the personal invitation of . This move marked his transition to international research in . Mottelson extended his stay at the institute with a two-year fellowship from the U.S. Atomic Energy Commission, spanning 1951 to 1953, where he shifted focus toward theoretical aspects of nuclear structure. His initial studies emphasized the , particularly its implications for understanding nuclear reactions and decay processes. In early publications during this period, Mottelson contributed to understanding the , including the role of collective motions in modifying transition rates within the shell model framework, providing foundational insights into nuclear systematics. In 1953, Mottelson took on a role as a researcher with CERN's Theoretical Study Group, temporarily based in Copenhagen, which facilitated his engagement with emerging European collaborations in high-energy and nuclear theory until 1957. This position underscored his growing involvement in the broader international nuclear physics community during the early postwar era.

Development of nuclear structure theory

In 1951, Ben Roy Mottelson joined at the Institute in , where they initiated a collaboration to develop a collective model of the , addressing the observed deviations from spherical symmetry in nuclear shapes and the coordinated motion of nucleons. This work built on emerging experimental evidence of low-lying excited states in even-even nuclei, suggesting collective excitations beyond the independent-particle . Their efforts emphasized the nucleus as a deformable liquid drop capable of surface vibrations and rotations, providing a framework to explain enhanced electromagnetic transition rates and systematic patterns in nuclear spectra. By 1952, Mottelson extended this collaboration through discussions with James Rainwater at , leading to the formulation of the unified nuclear model that reconciled the shell model's description of individual orbits with rotational and vibrational . This partnership integrated Rainwater's earlier proposal of spheroidal nuclear shapes with Bohr and Mottelson's dynamics, enabling a consistent interpretation of nuclear properties across regions of deformation. The model posits that nuclei can exhibit static deformations, particularly shapes, where the nuclear surface deviates from (with deformation parameters β typically around 0.1–0.3), influencing single-particle levels and overall stability. Central to the unified model are the concepts of rotational states and vibrational modes, which account for the excitation spectra in deformed and transitional nuclei, respectively. In strongly deformed nuclei, such as those in the rare-earth region, rotational states form characteristic bands where energy levels follow a rigid-rotor spectrum, E ∝ I(I+1) with I the total angular momentum, arising from the collective rotation of the entire nuclear core around axes perpendicular to the symmetry axis; these bands exhibit enhanced E2 transitions and moments of inertia scaling with the square of the nuclear radius. Vibrational modes, prominent in near-spherical nuclei like those near magic numbers, describe quadrupole oscillations of the nuclear surface, leading to a harmonic spectrum with equally spaced levels (e.g., 0+, 2+, 0+, 4+ multiplets) and transition strengths proportional to the deformation amplitude. This duality allows the model to interpolate between vibrational and rotational limits, capturing phenomena like β-vibrations (shape oscillations along the deformation axis) and γ-vibrations (perpendicular distortions). Key publications from this period include joint papers by Bohr and Mottelson in Physica (1952) on preliminary aspects of nuclear motion, Physical Review 89, 316 (1953) detailing rotational spectra in deformed nuclei, and Physical Review 90, 717 (1953) exploring symmetry properties and transition probabilities. Their seminal review, "Collective and Individual-Particle Aspects of Nuclear " (Matematisk-fysiske Meddelelser 27, no. 16, 1953), synthesized these ideas, providing a comprehensive theoretical foundation with detailed comparisons to experimental data on quadrupole moments and level spacings. These works established the unified model as a cornerstone of nuclear structure theory, emphasizing the interplay between microscopic interactions and macroscopic nuclear shapes.

Professional positions

Following his earlier invitation to the in in 1950, Mottelson secured a permanent staff position there in 1957, which he maintained throughout the rest of his career alongside affiliations at other institutions. In the same year, Mottelson played a key role in the founding of the Nordic Institute for (Nordita) in , where he was appointed as a professor and became a tenured faculty member. He later served as Nordita's director from 1981 to 1983. From 1993 to 1997, Mottelson held the position of founding director at the European Center for Theoretical Studies in Nuclear Physics and Related Areas (ECT*) in , , where he helped establish the institution as a hub for theoretical research.

Recognition and awards

Nobel Prize in Physics

In 1975, Ben Roy Mottelson shared the with Aage Niels Bohr and Leo James Rainwater for their pioneering contributions to understanding the structure of atomic nuclei. The Royal Swedish Academy of Sciences specifically recognized them "for the discovery of the connection between collective motion and particle motion in atomic nuclei and the development of the theory of the structure of the based on this connection." This work built on the unified model of nuclear structure, which Mottelson and Bohr had developed in the to reconcile shell-model and collective behaviors in nuclei. The ceremony took place on December 10, 1975, at the , where King presented the awards to the laureates. The following day, December 11, Mottelson delivered his Nobel lecture titled "Elementary Modes of Excitation in the Nucleus," in which he discussed the implications of nuclear deformations and rotational states, emphasizing how these concepts explained observed patterns in heavy nuclei. The award had an immediate and profound impact on , validating the unified model and spurring a wave of experimental efforts to measure nuclear shapes and deformations, such as through Coulomb excitation and gamma-ray spectroscopy, which confirmed theoretical predictions for deformed nuclei. These validations solidified the model's role as a for interpreting nuclear spectra and dynamics.

Other honors

In addition to his Nobel Prize, Mottelson received the Atoms for Peace Award in 1969 for his contributions to the peaceful applications of nuclear science. This recognition underscored his role in advancing theoretical understanding that supported non-military uses of atomic energy. Mottelson was awarded the John Price Wetherill Medal by the Franklin Institute in 1974, honoring his pioneering investigations in the structure of atomic nuclei. The medal highlighted his collaborative efforts in developing models that bridged experimental observations with theoretical frameworks in nuclear physics. In 1976, he received the Medal from the Royal Danish Academy of Sciences and Letters for his contributions to science. In 1980, the Polish Physical Society bestowed upon him the Medal, its highest honor for achievements in physical sciences, acknowledging his international influence on nuclear theory. This award reflected the global reach of his work, particularly through his long tenure at the Nordic Institute for (Nordita), which fostered collaborations across Europe. In 1973, Mottelson was elected a foreign associate of the (USA). Mottelson's contributions earned him election to prestigious academies worldwide. He became a member of the in 2011, joining an elite group recognizing excellence in the humanities and sciences. He was also an honorary member of the Finnish Society of Sciences and Letters since 1973, celebrating his interdisciplinary impact on physics. Additionally, he held foreign fellowships in the as a foundation fellow and the Norwegian Academy of Science and Letters since 1980, affirming his stature in promoting scientific exchange in developing and Nordic regions.

Later work and legacy

Post-Nobel contributions

Following his in 1975, Mottelson co-authored the second volume of Nuclear Structure with , titled Nuclear Deformations and published in 1975, which provided a comprehensive exposition of advanced nuclear models incorporating rotational and vibrational in deformed nuclei. This volume built upon the unified model developed earlier, extending its application to describe the of nucleons in non-spherical configurations. Mottelson continued his investigations into deformed nuclei throughout the late 1970s and 1980s, focusing on extensions of the unified model to high-spin states, where nuclear shapes undergo phase transitions under rapid , and to correlations that influence superconducting-like behavior in . These studies emphasized the interplay between single-particle motion and collective , providing theoretical frameworks for interpreting experimental observations of rotational bands in heavy nuclei. In the 1980s and 1990s, Mottelson shifted his research toward mesoscopic physics and broader quantum many-body problems, exploring shell structure phenomena beyond atomic nuclei. He contributed to analyses of supershell effects in metal clusters, such as those formed in sodium vapor with over 1,000 particles, revealing periodicities analogous to nuclear magic numbers. Additionally, his work extended to ultracold atomic Bose gases, where he examined vortices in rotating condensates and their connections to superfluidity, bridging nuclear and condensed matter systems. Beyond research, Mottelson served on the Board of Sponsors of the Bulletin of the Atomic Scientists, contributing to efforts aimed at and ethical applications of physics from the 1970s until his later years.

Influence on nuclear physics

Ben Roy Mottelson's development of the unified model of nuclear structure, in collaboration with , fundamentally reshaped modern by integrating single-particle and collective degrees of freedom, providing a comprehensive framework for understanding nuclear deformations and excitations. This model explained phenomena such as rotational bands and quadrupole vibrations, enabling precise predictions of nuclear spectra that aligned with experimental observations from Coulomb excitation experiments in the mid-20th century. Its influence extended to experimental validations, where microscopic derivations of the Bohr-Mottelson collective Hamiltonian confirmed the model's applicability to diverse nuclear systems. In heavy-ion physics, the unified model informed studies of superdeformation and rotation in warm nuclei, guiding interpretations of high-spin states observed in heavy-ion reactions at facilities like the National Superconducting Cyclotron Laboratory (NSCL) and (FRIB). Through his long tenure at the Nordic Institute for Theoretical Physics (Nordita) as professor from 1957 and director from 1981 to 1983, and at the Institute (NBI), Mottelson mentored numerous students and collaborators, establishing these institutions as global hubs for nuclear research. His guidance fostered interdisciplinary collaborations, notably with Ikuko Hamamoto on foundational texts like Nuclear Structure, and inspired a generation of physicists working on nuclear collectivity and . By directing the European Centre for Theoretical Studies in Nuclear and Related Areas (ECT*) from 1993 to 1997, Mottelson promoted international exchanges, enhancing theoretical advancements in across Europe and beyond. These efforts cultivated a vibrant community that bridged experimental and theoretical approaches, sustaining Nordita and NBI's leadership in the field. Mottelson's contributions to theoretical frameworks for nuclear collectivity included predictions of phase transitions in deformed nuclei as a function of , which anticipated behaviors like shape coexistence and were verified through high-precision in subsequent decades. The model's incorporation of superfluid pairing explained reduced moments of inertia in deformed nuclei, linking nuclear dynamics to broader quantum phenomena and influencing studies of excitations. Post-Nobel publications extended these frameworks, applying them to mesoscopic systems and reinforcing their relevance to ongoing research. Mottelson's legacy in deformed nuclei studies persisted into the , where the unified model provided the theoretical basis for exploring exotic shapes and coexistence in heavy and elements, as evidenced by systematic investigations using advanced mean-field theories and experimental data from beams. His work on nuclear deformations informed post-2000 into high-spin isomers and triaxiality, filling gaps in understanding multiphase nuclear structures observed at modern accelerators. This enduring influence is reflected in thousands of citations and focus issues dedicated to the model's 40th anniversary, underscoring its role in driving contemporary nuclear structure explorations.

Personal life

Family and citizenship

Mottelson married Nancy Jane Reno in 1948, and the couple had three children: two sons, Malcolm Graham (born 1950) and Daniel John (born 1953), and a , Martha (born 1954). Their marriage lasted until Reno's death in 1975. In 1983, Mottelson married Britta Marger Siegumfeldt. Mottelson acquired Danish citizenship in 1971 while retaining his citizenship, becoming a dual national. This followed his relocation to , where he integrated professionally at the Institute and Nordita, though he maintained strong ties to his American roots.

Death

Ben Roy Mottelson died on May 13, 2022, in , , at the age of 95. His death was announced by Nordita, the Institute, and the Niels Bohr International Academy, where he had been a longtime affiliate, prompting obituaries in major international outlets including , , and Danish media such as Uniavisen. Initial tributes from the physics community emphasized Mottelson's foundational in nuclear structure theory and his collaborative spirit, with colleagues at describing him as an "outstanding physicist who played a decisive in the understanding of atomic nuclei," while contributors to Physics Today and the Proceedings of the highlighted his enduring influence on the field.

References

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