Your search keyword '"P.E. Garrett"' showing total 7 results

1. Corrigendum to 'Benchmarking 136Xe neutrinoless ββ decay matrix element calculations with the 138Ba(p,t) reaction' [Phys. Lett. B 809 (2020) 135702]

Author

B.M. Rebeiro, S. Triambak, P.E. Garrett, B.A. Brown, G.C. Ball, R. Lindsay, P. Adsley, V. Bildstein, C. Burbadge, A. Diaz Varela, T. Faestermann, D.L. Fang, R. Hertenberger, M. Horoi, B. Jigmeddorj, M. Kamil, K.G. Leach, P.Z. Mabika, J.C. Nzobadila Ondze, J.N. Orce, and H.-F. Wirth

Subjects

Physics, QC1-999

Published

2021

2. Structure of high-lying levels populated in the 96Y →96Zr β decay

Author

K.R. Mashtakov, V.Yu. Ponomarev, M. Scheck, S.W. Finch, J. Isaak, M. Zweidinger, O. Agar, C. Bathia, T. Beck, J. Beller, M. Bowry, R. Chapman, M.M.R. Chishti, U. Friman-Gayer, L.P. Gaffney, P.E. Garrett, E.T. Gregor, J.M. Keatings, U. Köster, B. Löher, A.D. MacLean, D. O'Donnell, H. Pai, N. Pietralla, G. Rainovski, M. Ramdhane, C. Romig, G. Rusev, D. Savran, G.S. Simpson, J. Sinclair, K. Sonnabend, P. Spagnoletti, A.P. Tonchev, and W. Tornow

Subjects

High resolution gamma-ray spectroscopy, Pygmy dipole resonance, Reactor antineutrino anomaly, Quasi-particle phonon model, Physics, QC1-999

Abstract

The nature of the high-lying final levels of the 96Ygs β decay, one of the three most important contributors to the high-energy reactor antineutrino spectrum, has been investigated in high-resolution γ-ray spectroscopy following the β decay as well as in a campaign of inelastic photon scattering experiments. The comprehensive approach establishes 1− levels associated with the Pygmy Dipole Resonance as high-lying final levels in the β decay. Branching ratios extracted from β decay complement photon scattering and allow the absolute E1 excitation strength to be determined for levels populated in both reactions. The combined data represents a comprehensive approach to the wavefunction of the 1− levels below the Qβ value, which are investigated in the Quasiparticle Phonon Model. The calculations reveal that the components populated in β decay contribute only with small amplitudes to the complex wavefunction of these 1− levels. A comparison of the β decay results to data from total absorption γ-ray spectroscopy demonstrates a good agreement between both measurements.

Published

2021

3. Benchmarking 136Xe neutrinoless ββ decay matrix element calculations with the 138Ba(p,t) reaction

Author

B.M. Rebeiro, S. Triambak, P.E. Garrett, B.A. Brown, G.C. Ball, R. Lindsay, P. Adsley, V. Bildstein, C. Burbadge, A. Diaz Varela, T. Faestermann, D.L. Fang, R. Hertenberger, M. Horoi, B. Jigmeddorj, M. Kamil, K.G. Leach, P.Z. Mabika, J.C. Nzobadila Ondze, J.N. Orce, and H.-F. Wirth

Subjects

Neutrinoless double beta decay, Nuclear matrix elements, Transfer reactions, Shell model, QRPA, Physics, QC1-999

Abstract

We used a high-resolution magnetic spectrograph to study neutron pair-correlated 0+ states in 136Ba, produced via the Ba138(p,t) reaction. In conjunction with state-of-the-art shell model calculations, these data benchmark part of the dominant Gamow-Teller component of the nuclear matrix element (NME) for 136Xe neutrinoless double beta (0νββ) decay. We demonstrate for the first time an evaluation of part of a 0νββ decay NME by use of an experimental observable, presenting a new avenue of approach for more accurate calculations of 0νββ decay matrix elements.

Published

2020

4. Observation of the 02+ and γ bands in 98Ru, and shape coexistence in the Ru isotopes

Author

P.E. Garrett, L. Makhathini, R.A. Bark, T.R. Rodríguez, S. Valbuena, V. Bildstein, T.D. Bucher, C. Burbadge, R. Dubey, T. Faestermann, R. Hertenberger, M. Kamil, E.A. Lawrie, K.G. Leach, A.D. MacLean, C. Mehl, S.H. Mthembu, N.J. Mukwevho, C. Ngwetsheni, S.S. Ntshangase, J.C. Nzobadila Ondze, J.N. Orce, B. Rebeiro, B. Singh, S. Triambak, E.C. Vyfers, and H.-F. Wirth

Subjects

Physics, QC1-999

Abstract

Excited states in 98Ru were investigated using γ-ray spectroscopy following the β-decay of 98Rh, and via the 100Ru(p,t) reaction. Combining the results from the two experiments, two states were revised to have spin-parity of 4+ and subsequently assigned to the 02+ and “γ” bands, respectively. The observed structures in 98Ru are suggested to be deformed and rotational, rather than spherical and vibrational, and fit well into the systematics of these excitations in the Ru isotopes. The 02+ excitation is suggested as a shape coexisting configuration. This observation eliminates some of the last remaining candidates for nearly harmonic vibrational nuclei in the Z≈50 region. Beyond-mean-field calculations are presented that support shape coexistence throughout the Ru isotopes with N=52–62, and suggest a smooth evolution of the shapes.

Published

2020

5. Testing microscopically derived descriptions of nuclear collectivity: Coulomb excitation of 22Mg

Author

J. Henderson, G. Hackman, P. Ruotsalainen, S.R. Stroberg, K.D. Launey, J.D. Holt, F.A. Ali, N. Bernier, M.A. Bentley, M. Bowry, R. Caballero-Folch, L.J. Evitts, R. Frederick, A.B. Garnsworthy, P.E. Garrett, B. Jigmeddorj, A.I. Kilic, J. Lassen, J. Measures, D. Muecher, B. Olaizola, E. O'Sullivan, O. Paetkau, J. Park, J. Smallcombe, C.E. Svensson, R. Wadsworth, and C.Y. Wu

Subjects

Physics, QC1-999

Abstract

Many-body nuclear theory utilizing microscopic or chiral potentials has developed to the point that collectivity might be studied within a microscopic or ab initio framework without the use of effective charges; for example with the proper evolution of the E2 operator, or alternatively, through the use of an appropriate and manageable subset of particle–hole excitations. We present a precise determination of E2 strength in 22Mg and its mirror 22Ne by Coulomb excitation, allowing for rigorous comparisons with theory. No-core symplectic shell-model calculations were performed and agree with the new B(E2) values while in-medium similarity-renormalization-group calculations consistently underpredict the absolute strength, with the missing strength found to have both isoscalar and isovector components. The discrepancy between two microscopic models demonstrates the sensitivity of E2 strength to the choice of many-body approximation employed. Keywords: 22Mg, 22Ne, Ab initio, Collectivity, Coulomb excitation

Published

2018

6. Reorientation-effect measurement of the first 2+ state in 12C: Confirmation of oblate deformation

Author

M. Kumar Raju, J.N. Orce, P. Navrátil, G.C. Ball, T.E. Drake, S. Triambak, G. Hackman, C.J. Pearson, K.J. Abrahams, E.H. Akakpo, H. Al Falou, R. Churchman, D.S. Cross, M.K. Djongolov, N. Erasmus, P. Finlay, A.B. Garnsworthy, P.E. Garrett, D.G. Jenkins, R. Kshetri, K.G. Leach, S. Masango, D.L. Mavela, C.V. Mehl, M.J. Mokgolobotho, C. Ngwetsheni, G.G. O'Neill, E.T. Rand, S.K.L. Sjue, C.S. Sumithrarachchi, C.E. Svensson, E.R. Tardiff, S.J. Williams, and J. Wong

Subjects

Physics, QC1-999

Abstract

A Coulomb-excitation reorientation-effect measurement using the TIGRESS γ−ray spectrometer at the TRIUMF/ISAC II facility has permitted the determination of the 〈21+‖E2ˆ‖21+〉 diagonal matrix element in 12C from particle−γ coincidence data and state-of-the-art no-core shell model calculations of the nuclear polarizability. The nuclear polarizability for the ground and first-excited (21+) states in 12C have been calculated using chiral NN N4LO500 and NN+3NF350 interactions, which show convergence and agreement with photo-absorption cross-section data. Predictions show a change in the nuclear polarizability with a substantial increase between the ground state and first excited 21+ state at 4.439 MeV. The polarizability of the 21+ state is introduced into the current and previous Coulomb-excitation reorientation-effect analyses of 12C. Spectroscopic quadrupole moments of QS(21+)=+0.053(44) eb and QS(21+)=+0.08(3) eb are determined, respectively, yielding a weighted average of QS(21+)=+0.071(25) eb, in agreement with recent ab initio calculations. The present measurement confirms that the 21+ state of 12C is oblate and emphasizes the important role played by the nuclear polarizability in Coulomb-excitation studies of light nuclei. Keywords: Reorientation effect, Spectroscopic quadrupole moment, Ab initio calculations, Nuclear polarizability

Published

2018

7. Investigation of the role of 10Li resonances in the halo structure of 11Li through the Li11(p,d)Li10 transfer reaction

Author

A. Sanetullaev, R. Kanungo, J. Tanaka, M. Alcorta, C. Andreoiu, P. Bender, A.A. Chen, G. Christian, B. Davids, J. Fallis, J.P. Fortin, N. Galinski, A.T. Gallant, P.E. Garrett, G. Hackman, B. Hadinia, S. Ishimoto, M. Keefe, R. Krücken, J. Lighthall, E. McNeice, D. Miller, J. Purcell, J.S. Randhawa, T. Roger, A. Rojas, H. Savajols, A. Shotter, I. Tanihata, I.J. Thompson, C. Unsworth, P. Voss, and Z. Wang

Subjects

Physics, QC1-999

Abstract

The first measurement of the one-neutron transfer reaction 11Li(p,d)10Li performed using the IRIS facility at TRIUMF with a 5.7A MeV 11Li beam interacting with a solid H2 target is reported. The 10Li residue was populated strongly as a resonance peak with energy Er=0.62±0.04 MeV having a total width Γ=0.33±0.07 MeV. The angular distribution of this resonance is characterized by neutron occupying the 1p1/2 orbital. A DWBA analysis yields a spectroscopic factor of 0.67±0.12 for p1/2 removal strength from the ground state of 11Li to the region of the peak. Keywords: Halo nucleus, Li10,11, Transfer reaction, Inverse kinematics, DWBA, Spectroscopic factor

Published

2016