Your search keyword '"nuclear-state lifetimes"' showing total 6 results

1. A time-of-flight correction procedure for fast-timing data of recoils with varying implantation positions at a spectrometer focal plane.

Author

Mallaburn, M.J., Nara Singh, B.S., Cullen, D.M., Hodge, D., Taylor, M.J., Giles, M.M., Barber, L., Niţă, C.R., Mihai, R.E., Mihai, C., Mărginean, R., Mărginean, N., Nobs, C.R., Gamba, E.R., Bruce, A.M., Scholey, C., Rahkila, P., Greenlees, P.T., Badran, H., and Grahn, T.

Subjects

*PHOTOMULTIPLIERS, *FOCAL planes, *MASS spectrometers, *SPECTROMETERS, *STANDARD deviations, *TIME measurements, *DETECTORS

Abstract

Fast-timing measurements at the focal plane of a separator can suffer from poor timing resolution. This is due to the variations in time-of-flight (ToF) for photons travelling to a given detector, which arise from the changes in the implantation positions of the recoil nuclei emitting the γ rays of interest. In order to minimise these effects on timing measurements, a procedure is presented that improves fast-timing data by performing ToF corrections on an event-by-event basis. This method was used to correct data collected with an array of eight LaBr 3 detectors, which detected γ rays from spatially distributed 138Gd recoil-implants at the focal plane of the Recoil-Ion-Transport-Unit (RITU) spectrometer. The Generalised Centroid Difference (GCD) method was used to extract a lifetime from data in conjunction with a new procedure to calibrate the time walk. The lifetime of the first 2 + state in 138Gd, populated by the decay of the K π = 8 − isomeric state, was measured to be 229(24) ps using the ToF-corrected data, which is consistent within three standard deviations to the literature value. The results together with Monte-Carlo simulations show that the ToF correction procedure reduced the uncertainty in the measured lifetimes by 3 % in the case of the spatially distributed nuclei at the focal plane of RITU. However, ∼ 12 % has been estimated for a similar experiment when using a larger focal plane i.e. the Super-FRS at the FAIR facility. [ABSTRACT FROM AUTHOR]

Published

2019

2. A time-of-flight correction procedure for fast-timing data of recoils with varying implantation positions at a spectrometer focal plane

Author

L. Barber, M. Smolen, Joonas Konki, J. F. Smith, M. M. Giles, Mikael Sandzelius, C. Scholey, Michael Taylor, B. S. Nara Singh, Rauno Julin, Panu Rahkila, E.R. Gamba, Paul Greenlees, S. Lalkovski, R. Mărginean, F. Bisso, Jan Sarén, O. Neuvonen, Kalle Auranen, Zs. Podolyák, Philippos Papadakis, C. R. Nobs, H. Badran, P. H. Regan, N. Marginean, M. J. Mallaburn, Jari Partanen, Janne Pakarinen, C. Mihai, A. Herzáň, Alison Bruce, D. M. Cullen, A. Lightfoot, D. Hodge, Juha Sorri, C. R. Niţă, Sanna Stolze, Tuomas Grahn, Juha Uusitalo, Daniel Cox, and R. E. Mihai

Subjects

Nuclear and High Energy Physics, Photon, Generalised-centroid-difference method, tutkimuslaitteet, spektrometrit, Standard deviation, 138Gd, Recoil, generalised-centroid-difference method, Distributed source, Nuclear Experiment, Nuclear-state lifetimes, Instrumentation, detectors, Physics, nuclear-state lifetimes, ta114, Spectrometer, fast-timing, Detector, Centroid, Fast-timing, LaBr3, Computational physics, Time of flight, Cardinal point, distributed source, ydinfysiikka

Abstract

Fast-timing measurements at the focal plane of a separator can suffer from poor timing resolution. This is due to the variations in time-of-flight (ToF) for photons travelling to a given detector, which arise from the changes in the implantation positions of the recoil nuclei emitting the γ rays of interest. In order to minimise these effects on timing measurements, a procedure is presented that improves fast-timing data by performing ToF corrections on an event-by-event basis. This method was used to correct data collected with an array of eight LaBr 3 detectors, which detected γ rays from spatially distributed 138Gd recoil-implants at the focal plane of the Recoil-Ion-Transport-Unit (RITU) spectrometer. The Generalised Centroid Difference (GCD) method was used to extract a lifetime from data in conjunction with a new procedure to calibrate the time walk. The lifetime of the first 2 + state in 138Gd, populated by the decay of the K π = 8 − isomeric state, was measured to be 229(24) ps using the ToF-corrected data, which is consistent within three standard deviations to the literature value. The results together with Monte-Carlo simulations show that the ToF correction procedure reduced the uncertainty in the measured lifetimes by 3 % in the case of the spatially distributed nuclei at the focal plane of RITU. However, ∼ 12 % has been estimated for a similar experiment when using a larger focal plane i.e. the Super-FRS at the FAIR facility.

Published

2019

3. A charge plunger device to measure the lifetimes of excited nuclear states where transitions are dominated by internal conversion

Author

Barber, L. (L.), Heery, J. (J.), Cullen, D. M. (D. M.), Singh, B. S. (B. S. Nara), Herzberg, R.-D. (R.-D.), Müller-Gatermann, C. (C.), Beeton, G. (G.), Bowry, M. (M.), Dewald, A. (A.), Grahn, T. (T.), Greenlees, P. T. (P. T.), Illana, A. (A.), Julin, R. (R.), Juutinen, S. (S.), Keatings, J. M. (J. M.), Luoma, M. (M.), O’Donnell, D. (D.), Ojala, J. (J.), Pakarinen, J. (J.), Rahkila, P. (P.), Ruotsalainen, P. (P.), Sandzelius, M. (M.), Sarén, J. (J.), Sinclair, J. (J.), Smith, J. F. (J. F.), Sorri, J. (J.), Spagnoletti, P. (P.), Tann, H. (H.), Uusitalo, J. (J.), Vilhena, J. (J.), Zimba, G. (G.), Barber, L. (L.), Heery, J. (J.), Cullen, D. M. (D. M.), Singh, B. S. (B. S. Nara), Herzberg, R.-D. (R.-D.), Müller-Gatermann, C. (C.), Beeton, G. (G.), Bowry, M. (M.), Dewald, A. (A.), Grahn, T. (T.), Greenlees, P. T. (P. T.), Illana, A. (A.), Julin, R. (R.), Juutinen, S. (S.), Keatings, J. M. (J. M.), Luoma, M. (M.), O’Donnell, D. (D.), Ojala, J. (J.), Pakarinen, J. (J.), Rahkila, P. (P.), Ruotsalainen, P. (P.), Sandzelius, M. (M.), Sarén, J. (J.), Sinclair, J. (J.), Smith, J. F. (J. F.), Sorri, J. (J.), Spagnoletti, P. (P.), Tann, H. (H.), Uusitalo, J. (J.), Vilhena, J. (J.), and Zimba, G. (G.)

Abstract

A charge plunger device has been commissioned based on the DPUNS plunger (Taylor et al., 2013) using the in-flight mass separator MARA at the University of Jyväskylä. The ¹⁵²Sm(³²S,4n)¹⁸⁰ reaction was used to populate excited states in ¹⁸⁰. A lifetime measurement of the state \(2_1^+\) was performed by applying the charge plunger technique, which relies on the detection of the charge state-distribution of recoils rather than the detection of the emitted γ rays. This state was a good candidate to test the charge plunger technique as it has a known lifetime and depopulates through a converted transition that competes strongly with γ-ray emission. The lifetime of the \(2_1^+\) state was measured to be 480(10)ps, which is consistent with previously reported lifetimes that relied on the standard γ-ray techniques. The charge plunger technique is a complementary approach to lifetime measurements of excited states that depopulate through both γ-ray emission and internal conversion. In cases where it is not possible to detect Doppler-shifted γ rays, for example, in heavy nuclei where internal conversion dominates, it may well be the only feasible lifetime analysis approach.

Published

2020

4. A charge plunger device to measure the lifetimes of excited nuclear states where transitions are dominated by internal conversion

Author

Barber, L., Heery, J., Cullen, D.M., Singh, B.S. Nara, Herzberg, R.D., Müller-Gatermann, C., Beeton, G., Bowry, M., Dewald, A., Grahn, T., Greenlees, P.T., Illana, A., Julin, R., Juutinen, S., Keatings, J.M., Luoma, M., O’Donnell, D., Ojala, J., Pakarinen, J., Rahkila, P., Ruotsalainen, P., Sandzelius, M., Sarén, J., Sinclair, J., Smith, J.F., Sorri, J., Tann, H., Uusitalo, J., Vilhena, J., and Zimba, G.

Subjects

RDDSDDCM, nuclear-state lifetimes, charge plunger, ydinfysiikka, plunger

Abstract

A charge plunger device has been commissioned based on the DPUNS plunger (Taylor et al., 2013) using the in-flight mass separator MARA at the University of Jyväskylä. The 152Sm(32S,4n)180Pt reaction was used to populate excited states in 180Pt. A lifetime measurement of the 21+ state was performed by applying the charge plunger technique, which relies on the detection of the charge state-distribution of recoils rather than the detection of the emitted γ rays. This state was a good candidate to test the charge plunger technique as it has a known lifetime and depopulates through a converted transition that competes strongly with γ-ray emission. The lifetime of the 21+ state was measured to be 480(10)ps, which is consistent with previously reported lifetimes that relied on the standard γ-ray techniques. The charge plunger technique is a complementary approach to lifetime measurements of excited states that depopulate through both γ-ray emission and internal conversion. In cases where it is not possible to detect Doppler-shifted γ rays, for example, in heavy nuclei where internal conversion dominates, it may well be the only feasible lifetime analysis approach. peerReviewed

Published

2020

5. Performing the differential decay curve method on γ-ray transitions with unresolved Doppler-shifted components

Author

M. Beckers, Michael Giles, J. Jolie, Alfred Dewald, C. Müller-Gatermann, C. Fransen, F. Mammes, Michael Mallaburn, Liam Barber, Nara Singh, A. Blazhev, K. O. Zell, Thomas Braunroth, D. M. Cullen, A. Goldkuhle, and D. Wölk

Subjects

Physics, Unresolved Doppler-shifted components, Nuclear and High Energy Physics, Work (thermodynamics), DDCM, Plunger, 010308 nuclear & particles physics, Yrast, 01 natural sciences, Measure (mathematics), Decay curve, symbols.namesake, Recoil, RDDS, 0103 physical sciences, symbols, Atomic physics, Differential (infinitesimal), UDCM, 010306 general physics, Instrumentation, Doppler effect, Nuclear-state lifetimes, Energy (signal processing)

Abstract

A new method of extracting the γ -ray intensities necessary to perform lifetime measurements using the differential decay curve method (DDCM) is presented in this work, the unresolved Doppler-shifted components method (UDCM). The UDCM allows for a DDCM analysis to be performed using a γ -ray transition for which the fully Doppler-shifted and degraded components are unresolvable in energy and so are detected as a single peak. This technique was used to measure the known lifetime of the yrast 2 1 + state in 50 Mn with a depopulating transition that does not have resolvable fully Doppler-shifted and degraded components. The lifetime measured through applying the UDCM was consistent with the standard DDCM measurement of the 2 1 + state. Use of the UDCM allows for DDCM lifetime measurements to be made using transitions of smaller γ -ray energies, smaller recoil velocities and, in some cases, with a smaller uncertainty. In contrast to a standard DDCM analysis, a UDCM analysis is also independent of the widths of the fully Doppler-shifted and degraded components and as a result they do not need to be determined.

Published

2019

6. Performing the differential decay curve method on [formula omitted]-ray transitions with unresolved Doppler-shifted components.

Author

Barber, L., Cullen, D.M., Giles, M.M., Nara Singh, B.S., Mallaburn, M.J., Beckers, M., Blazhev, A., Braunroth, T., Dewald, A., Fransen, C., Goldkuhle, A., Jolie, J., Mammes, F., Müller-Gatermann, C., Wölk, D., and Zell, K.O.

Subjects

*UNITS of measurement, *CURVES

Abstract

A new method of extracting the γ -ray intensities necessary to perform lifetime measurements using the differential decay curve method (DDCM) is presented in this work, the unresolved Doppler-shifted components method (UDCM). The UDCM allows for a DDCM analysis to be performed using a γ -ray transition for which the fully Doppler-shifted and degraded components are unresolvable in energy and so are detected as a single peak. This technique was used to measure the known lifetime of the yrast 2 1 + state in 50 Mn with a depopulating transition that does not have resolvable fully Doppler-shifted and degraded components. The lifetime measured through applying the UDCM was consistent with the standard DDCM measurement of the 2 1 + state. Use of the UDCM allows for DDCM lifetime measurements to be made using transitions of smaller γ -ray energies, smaller recoil velocities and, in some cases, with a smaller uncertainty. In contrast to a standard DDCM analysis, a UDCM analysis is also independent of the widths of the fully Doppler-shifted and degraded components and as a result they do not need to be determined. [ABSTRACT FROM AUTHOR]

Published

2020