Your search keyword '"E. Lunderberg"' showing total 19 results

1. Mirror nucleon removal reactions in p -shell nuclei

Author

A. N. Kuchera, D. Bazin, T. Phan, J. A. Tostevin, M. Babo, T. Baumann, P. C. Bender, M. Bowry, J. Bradt, J. Brown, P. A. DeYoung, B. Elman, J. E. Finck, A. Gade, G. F. Grinyer, M. D. Jones, B. Longfellow, E. Lunderberg, T. H. Redpath, W. F. Rogers, K. Stiefel, M. Thoennessen, D. Votaw, D. Weisshaar, K. Whitmore, R. B. Wiringa, Grand Accélérateur National d'Ions Lourds (GANIL), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS.NUCL]Physics [physics]/Nuclear Theory [nucl-th], Nuclear Theory, Nuclear Experiment

Abstract

International audience; Nucleon removal reactions have been shown to be an effective tool for studying the single particle structure of nuclei. This work continues efforts to experimentally probe and benchmark the reaction and structure models used to calculate the removal reaction cross sections when using microscopic nuclear structure inputs. Three different single nucleon removal reactions were performed, from p-shell nuclei with masses A = 7, 9, and 10.The residual nuclei from the reactions were detected in coincidence with γ rays to determine partial cross sections to individual final states. The eikonal direct-reaction model is combined with overlap functions and residual nucleus densities from microscopic, variational Monte Carlo calculations to provide consistent nuclear structure input to the partial cross section calculations. Comparisons of measured and calculated cross sections, including for mirror reactions, are presented. The analysis of the partial cross sections leading to the ground states shows a similar behavior to the one observed from analyses of inclusive cross sections using shell model nuclear structure input: the theoretical description of the removal process is in better agreement with the data when removing weakly bound nucleons, than when removing well-bound ones. The two mirror reaction pairs presented here show consistent results between the respective members of the pairs. The results obtained for the population of the excited states, however, show a systematically different trend that appears connected to the structure part of the calculation. Additional cases are needed to better understand the respective roles of structureand dynamical effects in the deviations.

Published

2022

2. Spectroscopy of the T = 2 mirror nuclei 48Fe/48Ti using mirrored knockout reactions

Author

F. Recchia, H. Iwasaki, Edward Simpson, D. Bazin, T. Haylett, E. Lunderberg, D. Kahl, R. Yajzey, P. C. Bender, P. J. Davies, X. Pereira-Lopez, R. Wadsworth, Brandon Elman, S. M. Lenzi, Brenden Longfellow, D. R. Napoli, N. Kobayashi, S. J. Lonsdale, Alexandra Gade, J. Belarge, M. A. Bentley, J. A. Tostevin, D. Weisshaar, L. Morris, and S. Uthayakumaar

Subjects

Physics, Nuclear and High Energy Physics, QC1-999, SHELL model, Nuclear Theory, Shell (structure), Context (language use), medicine.anatomical_structure, Excited state, medicine, Mirror nuclei, Atomic physics, Spectroscopy, Nuclear Experiment, Nucleus

Abstract

A sequence of excited states has been established for the first time in the proton-rich nucleus 48Fe (Z=26, N=22). The technique of mirrored (i.e. analogue) one-nucleon knockout reactions was applied, in which the T z = ±2 mirror pair, 48Fe/48Ti were populated via one-neutron/one-proton knockout from the secondary beams 49Fe/49V, respectively. The analogue properties of the reactions were used to help establish the new level scheme of 48Fe. The inclusive and exclusive cross sections were determined for the populated states. Large differences between the cross sections for the two mirrored reactions were observed and have been interpreted in terms of different degrees of binding of the mirror nuclei and in the context of the recent observations of suppression of spectroscopic strength as a function of nuclear binding, for knockout reactions on light solid targets. Mirror energy differences (MED) have been determined between the analogue T = 2 states and compared with the shell model predictions. MED for this mirror pair, due to their location in the shell, are especially sensitive to excitations out of the f 7 / 2 shell, and present a stringent test of the shell-model prescription.

Published

2021

3. Electromagnetic properties of 21O for benchmarking nuclear Hamiltonians

Author

B. A. Brown, E. Lunderberg, P. C. Bender, J. Simonis, Robert Roth, C. Loelius, Stefanos Paschalis, D. Bazin, Sebastian Heil, Brenden Longfellow, Brandon Elman, Alexandra Gade, M. Mathy, Klaus Vobig, Marina Petri, T. Hüther, A. Hufnagel, Achim Schwenk, K. Whitmore, Jason D. Holt, J. Belarge, R. Elder, I. Syndikus, Javier Fernandez Menendez, D. Weisshaar, T. Haylett, N. Kobayashi, and Haruna Iwasaki

Subjects

Nuclear and High Energy Physics, Lifetime measurement, Nuclear Theory, FOS: Physical sciences, 01 natural sciences, 7. Clean energy, Nuclear Theory (nucl-th), Ab initio quantum chemistry methods, Simulació per ordinador, 0103 physical sciences, Effective field theory, Nuclear force, ddc:530, Química quàntica, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Physics, 010308 nuclear & particles physics, Branching fraction, Starke Wechselwirkung und exotische Kerne – Abteilung Blaum, Observable, Computer simulation, lcsh:QC1-999, Excited state, Quadrupole, Ab initio calculations, Effective charges, Atomic physics, Quantum chemistry, Exotic nuclei, lcsh:Physics, Excitation

Abstract

The structure of exotic nuclei provides valuable tests for state-of-the-art nuclear theory. In particular electromagnetic transition rates are more sensitive to aspects of nuclear forces and many-body physics than excitation energies alone. We report the first lifetime measurement of excited states in $^{21}$O, finding $\tau_{1/2^+}=420^{+35}_{-32}\text{(stat)}^{+34}_{-12}\text{(sys)}$\,ps. This result together with the deduced level scheme and branching ratio of several $\gamma$-ray decays are compared to both phenomenological shell-model and ab initio calculations based on two- and three-nucleon forces derived from chiral effective field theory. We find that the electric quadrupole reduced transition probability of $\rm B(E2;1/2^+ \rightarrow 5/2^+_{g.s.}) = 0.71^{+0.07\ +0.02}_{-0.06\ -0.06}$~e$^2$fm$^4$, derived from the lifetime of the $1/2^+$ state, is smaller than the phenomenological result where standard effective charges are employed, suggesting the need for modifications of the latter in neutron-rich oxygen isotopes. We compare this result to both large-space and valence-space ab initio calculations, and by using multiple input interactions we explore the sensitivity of this observable to underlying details of nuclear forces., Comment: 23 pages, 3 figures

Published

2020

4. Shell structure of S43 and collapse of the N=28 shell closure

Author

Shuichi Ota, Brenden Longfellow, E. Lunderberg, P. Schrock, N. Kitamura, D. Weisshaar, Megumi Niikura, J. A. Tostevin, Brandon Elman, P. C. Bender, Kathrin Wimmer, J. Belarge, K. W. Kemper, Alexandra Gade, D. Bazin, and Satoru Momiyama

Subjects

Physics, education.field_of_study, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, SHELL model, Population, Shell (structure), Parity (physics), 01 natural sciences, Molecular physics, 0103 physical sciences, Level structure, Neutron, Nuclear Experiment, 010306 general physics, education, Spectroscopy

Abstract

The single-particle structure of the N = 27 isotones provides insights into the shell evolution of neutron-rich nuclei from the doubly-magic 48Ca toward the drip line. 43S was studied employing the one-neutron knockout reaction from a radioactive 44S beam. Using a combination of prompt and delayed γ-ray spectroscopy the level structure of 43S was clarified. Momentum distributions were analyzed and allowed for spin and parity assignments. The deduced spectroscopic factors show that the 44S ground-state configuration has a strong intruder component. The results were confronted with shell model calculations using two effective interactions. General agreement was found between the calculations, but strong population of states originating from the removal of neutrons from the 2p3/2 orbital in the experiment indicates that the breakdown of the N = 28 magic number is more rapid than the theoretical calculations suggest.

Published

2020

5. Constraints for stellar electron-capture rates on Kr86 via the Kr86(t,He3+γ)Br86 reaction and the implications for core-collapse supernovae

Author

B. A. Brown, J. C. Zamora, J. Schmitt, Brandon Elman, Shumpei Noji, C. Sullivan, E. Lunderberg, Brenden Longfellow, T. Mijatović, R. G. T. Zegers, C. M. Campbell, D. Weisshaar, J. Pereira, J. Belarge, Jonathan Engel, D. Bazin, E. Kwan, P. C. Bender, S. Lipschutz, Bingshui Gao, R. Titus, Alexandra Gade, and E. M. Ney

Subjects

Physics, 010308 nuclear & particles physics, Electron capture, Gravitational wave, Nuclear Theory, 01 natural sciences, Nuclear physics, Supernova, Neutron number, 0103 physical sciences, Quasiparticle, Atomic number, Neutrino, 010306 general physics, Stellar density

Abstract

Author(s): Titus, R; Ney, EM; Zegers, RGT; Bazin, D; Belarge, J; Bender, PC; Brown, BA; Campbell, CM; Elman, B; Engel, J; Gade, A; Gao, B; Kwan, E; Lipschutz, S; Longfellow, B; Lunderberg, E; Mijatovic, T; Noji, S; Pereira, J; Schmitt, J; Sullivan, C; Weisshaar, D; Zamora, JC | Abstract: Background: In the late stages of stellar core collapse just prior to core bounce, electron captures on medium-heavy nuclei drive deleptonization. Therefore, simulations require the use of accurate reaction rates. Nuclei with neutron number near N=50 above atomic number Z=28 play an important role. Rates presently used in astrophysical simulations rely primarily on a relatively simple single-state approximation. In order to improve the accuracy of the astrophysical simulations, experimental data are needed to test the electron-capture rates and to guide the development of better theoretical models and astrophysical simulations. Purpose: The purpose of the present work was to measure the Gamow-Teller transition strength from Kr86 to Br86, to derive the stellar electron-capture rates based on the extracted strengths, and to compare the derived rates with rates based on shell-model and quasiparticle random-phase approximation (QRPA) Gamow-Teller strengths calculations, as well as the single-state approximation. An additional purpose was to test the impact of using improved electron-capture rates on the late evolution of core-collapse supernovae. Method: The Gamow-Teller strengths from Kr86 were extracted from the Kr86(t,He3+γ) charge-exchange reaction at 115MeV/u. The electron-capture rates were calculated as a function of stellar density and temperature. Besides the case of Kr86, the electron-capture rates based on the QRPA calculations were calculated for 78 additional isotopes near N=50 above Z=28. The impact of using these rates instead of those based on the single-state approximation is studied in a spherically symmetrical simulation of core collapse just prior to bounce. Results: The derived electron-capture rates on Kr86 from the experimental Gamow-Teller strength distribution are much smaller than the rates estimated based on the single-state approximation. Rates based on Gamow-Teller strengths estimated in shell-model and QRPA calculations are more accurate. The core-collapse supernova simulation with electron-capture rates based on the QRPA calculations indicate a significant reduction in the deleptonization during the collapse phase. Conclusions: It is important to utilize microscopic theoretical models that are tested by experimental data to constrain and estimate Gamow-Teller strengths and derived electron-capture rates for nuclei near N=50 that are inputs for astrophysical simulations of core-collapse supernovae and their multimessenger signals, such as the emission of neutrinos and gravitational waves.

Published

2019

6. Single-particle shell strengths near the doubly magic nucleus 56Ni and the 56Ni(p,γ)57Cu reaction rate in explosive astrophysical burning

Author

A. Estrade, W.-J. Ong, E. Lunderberg, Philip Woods, D. Bazin, R. G. T. Zegers, Alexandra Gade, D. Kahl, D. Weisshaar, Claudia Lederer-Woods, Brenden Longfellow, T. Poxon-Pearson, J. Pereira, Hendrik Schatz, Fernando Montes, P. C. Bender, Brandon Elman, S. Lipschutz, S. J. Lonsdale, Thomas Baumann, R. Taverner, Anu Kankainen, C. Sullivan, Filomena Nunes, G. Perdikakis, B. A. Brown, and J. Belarge

Subjects

Nuclear and High Energy Physics, astro-ph.SR, Nuclear Theory, Explosive material, nucl-th, Strong interaction, nucl-ex, 01 natural sciences, Ion, Reaction rate, symbols.namesake, 0103 physical sciences, Coulomb, Mirror nuclei, 010306 general physics, Nuclear Experiment, Physics, radioactive beams, 010308 nuclear & particles physics, shell model, lcsh:QC1-999, Astrophysics - Solar and Stellar Astrophysics, Excited state, symbols, X-ray bursts, transfer reactions, Atomic physics, Hamiltonian (quantum mechanics), ydinfysiikka, lcsh:Physics

Abstract

Angle-integrated cross-section measurements of the $^{56}$Ni(d,n) and (d,p) stripping reactions have been performed to determine the single-particle strengths of low-lying excited states in the mirror nuclei pair $^{57}$Cu-$^{57}$Ni situated adjacent to the doubly magic nucleus $^{56}$Ni. The reactions were studied in inverse kinematics utilizing a beam of radioactive $^{56}$Ni ions in conjunction with the GRETINA $\gamma$-array. Spectroscopic factors are compared with new shell-model calculations using a full $pf$ model space with the GPFX1A Hamiltonian for the isospin-conserving strong interaction plus Coulomb and charge-dependent Hamiltonians. These results were used to set new constraints on the $^{56}$Ni(p,$\gamma$)$^{57}$Cu reaction rate for explosive burning conditions in x-ray bursts, where $^{56}$Ni represents a key waiting point in the astrophysical rp-process., Comment: Final version accepted and published. 5 pages, 2 figures

Published

2019

7. Is the Structure of Si42 Understood?

Author

P. C. Bender, E. Lunderberg, D. Bazin, J. A. Tostevin, C. M. Campbell, K. W. Kemper, B. A. Brown, H. L. Crawford, Alexandra Gade, D. Rhodes, D. Weisshaar, Brenden Longfellow, and Brandon Elman

Subjects

Physics, education.field_of_study, Nuclear Theory, Population, Nuclear structure, General Physics and Astronomy, Observable, 01 natural sciences, Reaction dynamics, Excited state, 0103 physical sciences, Nuclear force, Atomic physics, Nuclear Experiment, 010306 general physics, education, Nucleon, Energy (signal processing)

Abstract

A more detailed test of the implementation of nuclear forces that drive shell evolution in the pivotal nucleus ^{42}Si-going beyond earlier comparisons of excited-state energies-is important. The two leading shell-model effective interactions, SDPF-MU and SDPF-U-Si, both of which reproduce the low-lying ^{42}Si(2_{1}^{+}) energy, but whose predictions for other observables differ significantly, are interrogated by the population of states in neutron-rich ^{42}Si with a one-proton removal reaction from ^{43}P projectiles at 81 MeV/nucleon. The measured cross sections to the individual ^{42}Si final states are compared to calculations that combine eikonal reaction dynamics with these shell-model nuclear structure overlaps. The differences in the two shell-model descriptions are examined and linked to predicted low-lying excited 0^{+} states and shape coexistence. Based on the present data, which are in better agreement with the SDPF-MU calculations, the state observed at 2150(13) keV in ^{42}Si is proposed to be the (0_{2}^{+}) level.

Published

2019

8. Spectroscopy of proton-rich 79Zr: Mirror energy differences in the highly-deformed fpg shell

Author

Bo Cederwall, M. A. Bentley, Alexandra Gade, Jacek Dobaczewski, D. Rhodes, Scott Milne, M. Doncel, H. Iwasaki, D. Bazin, R. D. O. Llewellyn, Brenden Longfellow, D. Weisshaar, G. de Angelis, J. Ash, I. Y. Lee, R. Wadsworth, P. C. Bender, T. Mijatović, E. Lunderberg, Brandon Elman, T. Haylett, D. G. Jenkins, R. Elder, M. Grinder, Benjamin P. Crider, and W. Satuła

Subjects

Physics, Nuclear and High Energy Physics, education.field_of_study, Proton, 010308 nuclear & particles physics, Nuclear Theory, Population, Shell (structure), 7. Clean energy, 01 natural sciences, Molecular physics, lcsh:QC1-999, nuclear structure, 0103 physical sciences, Coulomb, Isobaric process, Nuclear Experiment, 010306 general physics, Spectroscopy, education, lcsh:Physics, Energy (signal processing), Mixing (physics)

Abstract

Energy differences between isobaric analogue states have been extracted for the A = 79 , 79Zr/79Y mirror pair following their population via nucleon-knockout reactions from intermediate-energy rare-isotope beams. These are the heaviest nuclei where such measurements have been made to date. The deduced mirror energy differences (MED) are compared with predictions from a new density-functional based approach, incorporating isospin-breaking effects of both Coulomb and nuclear charge-symmetry breaking and configuration mixing.

Published

2020

9. Quadrupole collectivity beyond N=50 in neutron-rich Se and Kr isotopes

Author

E. Lunderberg, W. B. Walters, Kathrin Wimmer, N. Terpstra, K. W. Kemper, Brandon Elman, P. C. Bender, D. Weisshaar, N. Sachmpazidi, Daniel Bazin, Alexandra Gade, S. Lipschutz, M. Bowry, A. Westerberg, S. J. Williams, D. Barofsky, and M. Hjorth-Jensen

Subjects

Physics, Isotope, 010308 nuclear & particles physics, Nuclear Theory, Coulomb excitation, 01 natural sciences, 0103 physical sciences, Quadrupole, Effective field theory, Neutron, Atomic physics, Nuclear Experiment, 010306 general physics, Excitation

Abstract

We report $B(E2;{0}_{1}^{+}\ensuremath{\rightarrow}{2}_{n}^{+})$ strengths for the neutron-rich $^{88,90}\mathrm{Kr}$ and $^{86}\mathrm{Se}$ isotopes from intermediate-energy Coulomb excitation. The electric quadrupole transition strengths to the first ${2}^{+}$ states complete, with considerably improved uncertainties, the evolution of quadrupole collectivity in the Kr and Se isotopes approaching $N=60$, for which $^{90}\mathrm{Kr}$ and $^{86}\mathrm{Se}$ had previously been the most uncertain. We also report significant excitation strength to several higher-lying ${2}^{+}$ states in the krypton isotopes. This fragmentation of $B(E2)$ strength in $^{88,90}\mathrm{Kr}$ confirms shell-model calculations in the $\ensuremath{\pi}(fpg)\text{\ensuremath{-}}\ensuremath{\nu}(sdgh)$ shell with an only minimally tuned shell-model setup that is based on a nucleon-nucleon interaction derived from effective field theory and effective charges adjusted to $^{86}\mathrm{Kr}$.

Published

2017

10. Neutron knockout from $^{68,70}$Ni ground and isomeric states

Author

C. M. Campbell, Jie Chen, F. G. Kondev, A. Korichi, C. J. Prokop, M. P. Carpenter, T. Lauritsen, M. Albers, C. J. Chiara, Shumpei Noji, Calem Hoffman, E. Lunderberg, S. Zhu, S. Suchyta, R. V. F. Janssens, C. Langer, J. S. Berryman, D. Weisshaar, H. L. Crawford, Alexandra Gade, V. M. Bader, F. Recchia, Kathrin Wimmer, D. Bazin, Sean Liddick, B. A. Brown, S. R. Stroberg, J. A. Tostevin, T.R. Baugher, Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), and Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)

Subjects

Physics, History, 010308 nuclear & particles physics, Nuclear Theory, Gamma ray, Fermi surface, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, Computer Science Applications, Education, Physics and Astronomy (all), Atomic orbital, Excited state, Neutron number, 0103 physical sciences, Neutron, Atomic physics, 010306 general physics, Nuclear Experiment, Harmonic oscillator, Excitation

Abstract

International audience; Neutron-rich isotopes are an important source of new information on nuclear physics. Specifically, the spin-isospin components in the nucleon-nucleon (NN) interaction, e.g., the proton-neutron tensor force, are expected to modify shell structure in exotic nuclei. These potential changes in the intrinsic shell structure are of fundamental interest. The study of the excitation energy of states corresponding to specific configurations in even-even isotopes, together with the single-particle character of the first excited states of odd-A, neutron-rich Ni isotopes, probes the evolution of the neutron orbitals around the Fermi surface as a function of the neutron number a step forward in the understanding of the region and the nature of the NN interaction at large N/Z ratios. In an experiment carried out at the National Superconducting Cyclotron Laboratory [1], new spectroscopic information was obtained for 68Ni and the distribution of single-particle strengths in 67,69Ni was characterized by means of single-neutron knockout from 68,70Ni secondary beams. The spectroscopic strengths, deduced from the measured partial cross sections to the individual states tagged by their de-exciting gamma rays, is used to identify and quantify configurations that involve neutron excitations across the N = 40 harmonic oscillator shell closure. The de-excitation γ rays were measured with the GRETINA tracking array [2]. The results challenge the validity of the most current shell-model Hamiltonians and effective interactions, highlighting shortcomings that cannot yet be explained. These results suggest that our understanding of the low-energy states in such nuclei is not complete and requires further investigation.

Published

2017

11. Observation of the Isovector Giant Monopole Resonance via the Si28(Be10,B*10[1.74 MeV]) Reaction at 100 AMeV

Author

Sam M. Austin, C. M. Campbell, Shumpei Noji, C. Morse, C. Loelius, U. Garg, M. Bowry, S. Lipschutz, B. A. Brown, Remco Zegers, C. Sullivan, D. Weisshaar, E. Lunderberg, T. Redpath, C. Robin, Yoshiko Sasamoto, E. Kwan, M.N. Harakeh, Hideyuki Sakai, C. Langer, Masaki Sasano, G. Perdikakis, S. Gales, Elena Litvinova, M. Scott, J. A. Tostevin, Daniel Bazin, Alexandra Gade, Tomohiro Uesaka, and R.M. Almus

Subjects

Physics, Isovector, 010308 nuclear & particles physics, Nuclear Theory, Cyclotron, Magnetic monopole, General Physics and Astronomy, Resonance, Nuclear matter, 01 natural sciences, 7. Clean energy, law.invention, Nuclear physics, Dipole, law, 0103 physical sciences, Atomic physics, Born approximation, Nuclear Experiment, 010306 general physics, Excitation

Abstract

The (10Be,10B [1.74 MeV]) charge-exchange reaction at 100 AMeV is presented as a new probe for isolating the isovector (ΔT = 1) non-spin-transfer (ΔS = 0) response of nuclei, with 28Si being the rst nucleus studied. By using a secondary 10Be beam produced by fast fragmentation of 18O nuclei at the NSCL Coupled Cyclotron Facility, applying the dispersion-matching technique with the S800 magnetic spectrometer to determine the excitation energy in 28Al, and performing high- resolution -ray tracking with the Gamma-Ray Energy Tracking Array (GRETINA) to identify the 1022-keV ray associated with the decay from the 1.74-MeV T = 1 isobaric analog state in 10B, a ΔS = 0 excitation-energy spectrum in 28Al was extracted. Monopole and dipole contributions were determined through a multipole-decomposition analysis, and the isovector giant dipole (IVGDR) and monopole (IVGMR) resonances were identi ed. The results show that this probe is a powerful tool for studying the elusive IVGMR, which is of interest for performing stringent tests of modern density functional theories at high excitation energies and for constraining the bulk properties of nuclei and nuclear matter. The extracted distributions were compared with theoretical calculations based on the normal-modes formalism and the proton-neutron relativistic time-blocking approximation. Calculated cross sections based on these strengths underestimate the data by about a factor of two, which likely indicates de ciencies in the reaction calculations based on the distorted wave Born approximation.

Published

2017

12. In-beam γ -ray spectroscopy of S38–42

Author

E. Lunderberg, S. R. Stroberg, D. J. Hartley, F. Recchia, Kathrin Wimmer, B. A. Brown, J. S. Berryman, Daniel Bazin, T.R. Baugher, V. M. Bader, D. Weisshaar, and Alexandra Gade

Subjects

Physics, education.field_of_study, 010308 nuclear & particles physics, Yrast, Nuclear Theory, Population, 01 natural sciences, symbols.namesake, Excited state, 0103 physical sciences, symbols, Atomic physics, Nuclear Experiment, 010306 general physics, Spectroscopy, education, Hamiltonian (quantum mechanics), Projectile fragmentation, Excitation

Abstract

The low-energy excitation level schemes of the neutron-rich $^{38--42}\mathrm{S}$ isotopes are investigated via in-beam $\ensuremath{\gamma}$-ray spectroscopy following the fragmentation of $^{48}\mathrm{Ca}$ and $^{46}\mathrm{Ar}$ projectiles on a $^{12}\mathrm{C}$ target at intermediate beam energies. Information on $\ensuremath{\gamma}\ensuremath{\gamma}$ coincidences complemented by comparisons to shell-model calculations were used to construct level schemes for these neutron-rich nuclei. The experimental data are discussed in the context of large-scale shell-model calculations with the SDPF-MU effective interaction in the $sd\text{\ensuremath{-}}pf$ shell. For the even-mass S isotopes, the evolution of the yrast sequence is explored as well as a peculiar change in decay pattern of the second ${2}^{+}$ states at $N=26$. For the odd-mass $^{41}\mathrm{S}$, a level scheme is presented that seems complete below 2.2 MeV and consistent with the predictions by the SDPF-MU shell-model Hamiltonian; this is a remarkable benchmark given the rapid shell and shape evolution at play in the S isotopes as the broken-down $N=28$ magic number is approached. Furthermore, the population of excited final states in projectile fragmentation is discussed.

Published

2016

13. Octupole strength in the neutron-rich calcium isotopes

Author

Shumpei Noji, S. D. Gregory, F. G. DeVone, Daniel Bazin, F. Recchia, D. M. McPherson, L. A. Riley, Michael L. Agiorgousis, E. Lunderberg, Remco Zegers, M. Scott, B. V. Sadler, D. Weisshaar, Alexandra Gade, P. D. Cottle, M. T. Glowacki, M. Bowry, K. W. Kemper, T.R. Baugher, and E. B. Haldeman

Subjects

Physics, Nuclear and High Energy Physics, Isotope, Proton, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, FOS: Physical sciences, 01 natural sciences, 7. Clean energy, Isotopes of calcium, Excited state, Proton scattering, 0103 physical sciences, Neutron, Physics::Atomic Physics, Nuclear Experiment (nucl-ex), Atomic physics, Nuclear Experiment, 010306 general physics, Spectroscopy

Abstract

Low-lying excited states of the neutron-rich calcium isotopes $^{48-52}$Ca have been studied via $\gamma$-ray spectroscopy following inverse-kinematics proton scattering on a liquid hydrogen target using the GRETINA $\gamma$-ray tracking array. The energies and strengths of the octupole states in these isotopes are remarkably constant, indicating that these states are dominated by proton excitations., Comment: 15 pages, 3 figures

Published

2016

14. One-neutron pickup intoCa49: Bound neutrong9/2spectroscopic strength atN=29

Author

Kathrin Wimmer, D. J. Hartley, B. A. Brown, V. M. Bader, J. S. Berryman, Alexandra Gade, D. Weisshaar, S. R. Stroberg, J. A. Tostevin, F. Recchia, T.R. Baugher, D. Bazin, E. Lunderberg, and Yutaka Utsuno

Subjects

Physics, 010308 nuclear & particles physics, Projectile, Nuclear Theory, Ab initio, Shell (structure), Inelastic scattering, Quantum number, 01 natural sciences, Atomic orbital, 0103 physical sciences, Neutron, Atomic physics, Nuclear Experiment, 010306 general physics, Spectroscopy

Abstract

The highly selective, intermediate-energy heavy-ion-induced neutron-pickup reaction, in combination with γ-ray spectroscopy using the γ-ray energy-tracking in-beam nuclear array (GRETINA), is shown to provide reliable relative spectroscopic strengths for high-l orbitals in nuclei more neutron rich than the projectile. The reaction mechanism gives a significant final-state-spin alignment that is validated through γ-ray angular-distribution measurements enabled by the position sensitivity of GRETINA. This is the first time that γ-ray angular distributions could be extracted from a high-luminosity, fast-beam reaction other than inelastic scattering. This holds great promise for the restriction and assignment of Jπ quantum numbers in exotic nuclei. We advance this approach to study the crucial N=28 shell closure and extract the ratio g9/2:f5/2 of bound neutron single-particle strengths in Ca49, a benchmark for emerging multi-shell ab initio and configuration-interaction theories that are applicable along the Ca isotopic chain.

Published

2016

15. Gamow-Teller transitions toCa45via theSc45(t,He3+γ)reaction at115 MeV/uand its application to stellar electron-capture rates

Author

Sam M. Austin, C. Sullivan, G. W. Hitt, M. Scott, C. M. Campbell, Shumpei Noji, S. Lipschutz, C. Walz, R. G. T. Zegers, H. J. Doster, D. Weisshaar, E. Lunderberg, J. Pereira, B. A. Brown, Z. Meisel, R. Meharchand, Kathrin Wimmer, C. Langer, G. Perdikakis, T.R. Baugher, Alexandra Gade, S. J. Williams, L. Valdez, A. L. Cole, S. Gupta, F. Recchia, D. Bazin, S. R. Stroberg, Hendrik Schatz, and C. J. Guess

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Neutron star, Electron capture, Excited state, Nuclear Theory, Quasiparticle, Nuclear Experiment, Random phase approximation, Energy (signal processing), Excitation, Spectral line

Abstract

Background: Stellar electron-capture reactions on medium-heavy nuclei are important for many astrophysical phenomena, including core-collapse and thermonuclear supernov\ae{} and neutron stars. Estimates of electron-capture rates rely on accurate estimates of Gamow-Teller strength distributions, which can be extracted from charge-exchange reactions at intermediate beam energies. Measured Gamow-Teller transition strength distributions for stable pf-shell nuclei are reasonably well reproduced by theoretical calculations in the shell model, except for lower mass nuclei where admixtures from the sd shell can become important.Purpose: This paper presents a ${\ensuremath{\beta}}^{+}$ charge-exchange experiment on $^{45}\mathrm{Sc}$, one of the lightest pf-shell nuclei. The focus was on Gamow-Teller transitions to final states at low excitation energies, which are particularly important for accurate estimations of electron-capture rates at relatively low stellar densities. The experimental results are compared with various theoretical models.Method: The double-differential cross section for the $^{45}\mathrm{Sc}(t,^{3}\mathrm{He}+\ensuremath{\gamma})$ reaction was measured using the NSCL Coupled-Cyclotron Facility at $115\phantom{\rule{4pt}{0ex}}\mathrm{MeV}/u$. Gamow-Teller contributions to the excitation-energy spectra were extracted by means of a multipole-decomposition analysis. $\ensuremath{\gamma}$ rays emitted due to the deexcitation of $^{45}\mathrm{Ca}$ were measured using GRETINA to allow for the extraction of Gamow-Teller strengths from very weak transitions at low excitation energies.Results: Gamow-Teller transition strengths to $^{45}\mathrm{Ca}$ were extracted up to an excitation energy of 20 MeV, and that to the first excited state in $^{45}\mathrm{Ca}$ at 174 keV was extracted from the $\ensuremath{\gamma}$-ray measurement, which, even though weak, is important for the astrophysical applications and dominates under certain stellar conditions. Shell-model calculations performed in the pf shell-model space with the GXPF1A, KB3G, and FPD6 interactions did not reproduce the experimental Gamow-Teller strength distribution, and a calculation using the quasiparticle random phase approximation that is often used in astrophysical simulations also could not reproduce the experimental strength distribution.Conclusions: Theoretical models aimed at describing Gamow-Teller transition strengths from nuclei in the lower pf shell for the purpose of estimating electron-capture rates for astrophysical simulations require further development. The likely cause for the relatively poor performance of the shell-model theory is the influence of intruder configurations from the sd shell. The combination of charge-exchange experiments at intermediate beam energy and high-resolution $\ensuremath{\gamma}$-ray detection provides a powerful technique to identify weak transitions to low-lying final states that are nearly impossible to identify without the coincidences. Identification of these weak low-lying transitions is important for providing accurate electron-capture rates for astrophysical simulations.

Published

2015

16. Neutron single-particle strength in silicon isotopes: Constraining the driving forces of shell evolution

Author

C. Langer, Shumpei Noji, Alexandra Gade, S. J. Williams, C. M. Campbell, E. Lunderberg, A. Lemasson, C. Walz, D. Weisshaar, S. R. Stroberg, V. M. Bader, J. A. Tostevin, J. S. Berryman, K. W. Kemper, F. Recchia, D. Bazin, B. A. Brown, Takaharu Otsuka, and T.R. Baugher

Subjects

Physics, Collective behavior, Nuclear and High Energy Physics, Isotope, Nuclear Theory, SHELL model, Shell (structure), FOS: Physical sciences, Nuclear Theory (nucl-th), Particle, Neutron, Tensor, Isotopes of silicon, Atomic physics, Nuclear Experiment (nucl-ex), Nuclear Experiment

Abstract

Shell evolution is studied in the neutron-rich silicon isotopes 36,38,40 Si using neutron single-particle strengths deduced from one-neutron knockout reactions. Configurations involving neutron excita- tions across the N = 20 and N = 28 shell gaps are quantified experimentally in these rare isotopes. Comparisons with shell model calculations show that the tensor force, understood to drive the col- lective behavior in 42 Si with N = 28, is already important in determining the structure of 40 Si with N = 26. New data relating to cross-shell excitations provide the first quantitative support for repulsive contributions to the cross-shell T = 1 interaction arising from three-nucleon forces.

Published

2015

17. Single-particle structure of silicon isotopes approaching 42Si

Author

E. Lunderberg, C. Walz, Shumpei Noji, C. Langer, T.R. Baugher, D. Weisshaar, V. M. Bader, A. Lemasson, Alexandra Gade, S. J. Williams, J. S. Berryman, C. M. Campbell, F. Recchia, B. A. Brown, K. W. Kemper, D. Bazin, J. A. Tostevin, and S. R. Stroberg

Subjects

Momentum, Physics, Nuclear and High Energy Physics, Eikonal equation, SHELL model, Nuclear Theory, Structure (category theory), Particle, Isotopes of silicon, Atomic physics, Nuclear Experiment, Beam (structure)

Abstract

The structure of the neutron-rich silicon isotopes Si36,38,40 was studied by one-neutron and one-proton knockout reactions at intermediate beam energies. We construct level schemes for the knockout residues Si35,37,39 and Al35,37,39 and compare knockout cross sections to the predictions of an eikonal model in conjunction with large-scale shell-model calculations. The agreement of these calculations with the present experiment lends support to the microscopic explanation of the enhanced collectivity in the region of Si42. We also present an empirical method for reproducing the observed low-momentum tails in the parallel momentum distributions of knockout residues.

Published

2014

18. Inverse-kinematics proton scattering onCa50: Determining effective charges using complementary probes

Author

Shumpei Noji, Michael L. Agiorgousis, E. Lunderberg, M. Bowry, B. V. Sadler, L. A. Riley, D. M. McPherson, F. G. DeVone, R. G. T. Zegers, D. Weisshaar, K. W. Kemper, M. Scott, F. Recchia, D. Bazin, M. T. Glowacki, Alexandra Gade, T.R. Baugher, and P. D. Cottle

Subjects

Physics, Nuclear and High Energy Physics, Astrophysics::High Energy Astrophysical Phenomena, Proton scattering, Nuclear Theory, SHELL model, Neutron, Atomic physics, Nuclear Experiment, 7. Clean energy

Abstract

We have performed measurements of the ${0}_{\mathrm{g}.\mathrm{s}.}^{+}\ensuremath{\rightarrow}{2}_{1}^{+}$ excitations in the neutron-rich isotopes $^{48,50}\mathrm{Ca}$ via inelastic proton scattering on a liquid hydrogen target, using the GRETINA $\ensuremath{\gamma}$-ray tracking array. A comparison of the present results with those from previous measurements of the lifetimes of the ${2}_{1}^{+}$ states provides the ratio of the neutron and proton matrix elements for the ${0}_{\mathrm{g}.\mathrm{s}.}^{+}\ensuremath{\rightarrow}{2}_{1}^{+}$ transitions. These results allow the determination of the ratio of the proton and neutron effective charges to be used in shell model calculations of neutron-rich isotopes in the vicinity of $^{48}\mathrm{Ca}$.

Published

2014

19. β+Gamow-Teller Transition Strengths fromTi46and Stellar Electron-Capture Rates

Author

Alexandra Gade, G. Perdikakis, Shumpei Noji, Zach Meisel, E. Lunderberg, C. Sullivan, S. J. Williams, C. J. Guess, R. G. T. Zegers, C. Langer, C. M. Campbell, A. L. Cole, C. Walz, G. W. Hitt, M. Scott, H. J. Doster, B. A. Brown, D. Weisshaar, Sam M. Austin, T.R. Baugher, S. Gupta, Kathrin Wimmer, S. Lipschutz, J. Pereira, S. R. Stroberg, L. Valdez, F. Recchia, D. Bazin, R. Meharchand, and Hendrik Schatz

Subjects

Physics, Nuclear physics, Reaction rate, Electron capture, Double beta decay, Nuclear Theory, Quasiparticle, General Physics and Astronomy, Nuclear Experiment, Space (mathematics), Random phase approximation, Measure (mathematics), Stellar evolution

Abstract

The Gamow-Teller strength in the β(+) direction to (46)Sc was extracted via the (46)Ti(t,(3)He + γ) reaction at 115 MeV/u. The γ-ray coincidences served to precisely measure the very weak Gamow-Teller transition to a final state at 991 keV. Although this transition is weak, it is crucial for accurately estimating electron-capture rates in astrophysical scenarios with relatively low stellar densities and temperatures, such as presupernova stellar evolution. Shell-model calculations with different effective interactions in the pf shell-model space do not reproduce the experimental Gamow-Teller strengths, which is likely due to sd-shell admixtures. Calculations in the quasiparticle random phase approximation that are often used in astrophysical simulations also fail to reproduce the experimental Gamow-Teller strength distribution, leading to strongly overestimated electron-capture rates. Because reliable theoretical predictions of Gamow-Teller strengths are important for providing astrophysical electron-capture reaction rates for a broad set of nuclei in the lower pf shell, we conclude that further theoretical improvements are required to match astrophysical needs.

Published

2014