Presentation is loading. Please wait.

Presentation is loading. Please wait.

Decay Spectroscopy Working Group Nuclear Structure Theory Morten Hjorth-Jensen – Shell Structure and Interactions Ivan Borzov – Theory of  Decay Applications.

Published byBarnaby Berry Modified over 8 years ago

Similar presentations

Presentation on theme: "Decay Spectroscopy Working Group Nuclear Structure Theory Morten Hjorth-Jensen – Shell Structure and Interactions Ivan Borzov – Theory of  Decay Applications."— Presentation transcript:

1 Decay Spectroscopy Working Group Nuclear Structure Theory Morten Hjorth-Jensen – Shell Structure and Interactions Ivan Borzov – Theory of  Decay Applications of Nuclear Decay Data Hendrik Schatz – Nuclear Astrophysics (r-process) Ian Gauld – Nuclear Reactors, Safeguards, and National Security Key Nuclear Structure Experiments and Equipment at Upgraded HRIBF 78 Ni Region: Chiara Mazzocchi 132 Sn Region: Agnieszka Korgul and Jon Batchelder Nuclear Level Lifetimes: Volker Werner and Henryk Mach Proton drip-line and SHE studies with SIBs and RIBs – Robert Page Neutron Detection: Miguel Madurga Electron Counting: Ed Zganjar Total Absorption Gamma Spectroscopy: Marek Karny High Resolution and Efficiency Gamma Counting: Sean Liddick High Resolution Isobar/Isomer Separator: Andreas Piechaczek Storage Ring: Robert Grzywacz

2 Nuclear Shell Structure and Interactions – M. Hjorth-Jensen 48 Ni – 56 Ni – 68 Ni – 78 Ni 100 Sn – 114 Sn – 116 Sn – 132 Sn – 140 Sn Experimental Benchmark for many-body forces Deformation: Density Functional Theory

3 Theory of  Decay – I. Borzov I.N. Borzov, PRC 71(2005)065801 C70 Reach I.N. Borzov, NPA777(2006)645 J.A. Winger et al., PRL 102 (2009) 142502

4 Nuclear Astrophysics – H. Schatz “… our current simulation is far from reproducing the solar r-process signature. […] One reason for this could well be the uncertainties in the  -decay rates.” (Fryer et al. 2006) --> Great opportunities at upgraded ORNL ISOL facility for a major step in probing (and understanding) the r-process Reach the point where the models can no longer blame nuclear physics for the inability to get the correct result.

5 Nuclear Reactors, Nuclear Safeguards, and National Security – I. Gauld OECD/NEA WPEC 25 Decay Heat Analysis International Working Party on Evaluation Co-operation of the NEA Nuclear Science Committee NEA/WPEC-25 VOLUME 25 - Assessment of Fission Product Decay Data for Decay Heat Calculations http://www.nea.fr/html/science/wpec/volume25/volume25.pdf Important to – – Reactor LOCA analysis – Delayed gamma analysis from active neutron interrogation Known issues with evaluations WPEC-25 developed a priority list of isotopes for re-measurement Electromagnetic decay heat following thermal fission burst of 239 Pu

6 Decay studies of neutron-rich nuclei at Range out experiment LeRIBSS experiment +/-40 keV +/-160 keV Isobar separator M/  M ~ 10000 Mass separator M/ΔM ~ 1000 54 MeV protons ~ 10  A 2-3 MeV/u 200 keV charge exchange cell (removes Zn, Cd) ~ 5% efficiency Positive ions Positive or negative ions Tandem accelerator (negative ions only) ~ 10% efficiency IRIS-1 ORIC : ~6 g 238 U fission fragments ~10 11 /s         ~20%   ~60% gas cell Energy loss Total ion energy 76 Cu 76 Ga 76 Ge no 76 Zn !!! Range out exp gas cell spectra C.J.Gross et al., EPJ A25,115,2005 C70-like cyclotron ~100-200  A, 70 MeV ~10 13 /s 50-100 g 238 U MCP

7 HRIBF HDU Experiments R. Page V. Werner J.C. Batchelder C. Mazzocchi A. Korgul

8 Decay studies : HRIBF as a world-unique ISOL facility very high rates + isobaric separation + ion “ranging-out” and tagging + powerful detectors and digital data acquisition and the collaborations of contributing users ! photo-peak efficiency total  -efficiency MTAS M. Karny  Detector E. Zganjar 3Hen LSU/MS State/ UTK/ORNL ORISS (  M/M 1:400,000) A.Piechaczek ekta-BESCA E. Zganjar VANDLE M. Madurga CERDA S.N. Liddick

9 Summary There are important issues in nuclear structure, nuclear astrophysics, nuclear reactors and safety, and national security which require information from  decay. The HRIBF has a unique ability to provide highly purified radioactive beams with event-by-event measured intensity. The HRIBF currently has a powerful array of detector systems in place for this research A number of new detector systems are being built which will further enhance the HRIBF research ORISS will add to the ability to provide pure beams The HRIBF Hadron Driver Upgrade will provide a significant increase in the range and number of key decay experiments which can be performed. The HRIBF HUD will bridge the gap in high-power ISOL research in the US until CD4 FRIB. The results from the upgraded HRIBF will create a database for the discussion of ISOL vs. second fragmentation target options at FRIB.

Download ppt "Decay Spectroscopy Working Group Nuclear Structure Theory Morten Hjorth-Jensen – Shell Structure and Interactions Ivan Borzov – Theory of  Decay Applications."

Similar presentations

ISAC Physics Working Group Convenors Malcolm Butler and Barry Davids.

ISAC Physics Working Group Convenors Malcolm Butler and Barry Davids.
1 ORISS Isomer and Isobar Spectrometer and Separator for Study of Exotic Decays A. Piechaczek for the.

1 ORISS Isomer and Isobar Spectrometer and Separator for Study of Exotic Decays A. Piechaczek for the.
GEANT4 Simulations of TIGRESS

GEANT4 Simulations of TIGRESS
Unstable vs. stable nuclei: neutron-rich and proton-rich systems

Unstable vs. stable nuclei: neutron-rich and proton-rich systems
Slid 1 Brad Sherrill, HRIBF Workshop 2009, Slide 1 Facility For Rare Isotope Beams Bradley M. Sherrill FRIB Michigan State University.

Slid 1 Brad Sherrill, HRIBF Workshop 2009, Slide 1 Facility For Rare Isotope Beams Bradley M. Sherrill FRIB Michigan State University.
Γ spectroscopy of neutron-rich 95,96 Rb nuclei by the incomplete fusion reaction of 94 Kr on 7 Li Simone Bottoni University of Milan Mini Workshop 1°-

Γ spectroscopy of neutron-rich 95,96 Rb nuclei by the incomplete fusion reaction of 94 Kr on 7 Li Simone Bottoni University of Milan Mini Workshop 1°-
Prospects for STEFF at EAR2 A.G.Smith, J.Billowes, R.Frost, E.Murray, J.Ryan, S.Warren,T.Wright The University of Manchester A. Pollitt ILL Grenoble I.

Prospects for STEFF at EAR2 A.G.Smith, J.Billowes, R.Frost, E.Murray, J.Ryan, S.Warren,T.Wright The University of Manchester A. Pollitt ILL Grenoble I.
High precision study of the  decay of 42 Ti  V ud matrix element and nuclear physics  Experimental and theoretical precisions  New cases: goals and.

High precision study of the  decay of 42 Ti  V ud matrix element and nuclear physics  Experimental and theoretical precisions  New cases: goals and.
Radioactive Ion Beams: where are we now experimentally? M. Huyse K.U. Leuven Moriond, March 2003 Opening page.

Radioactive Ion Beams: where are we now experimentally? M. Huyse K.U. Leuven Moriond, March 2003 Opening page.
Multinucleon Transfer Reactions – a New Way to Exotic Nuclei? Sophie Heinz GSI Helmholtzzentrum and Justus-Liebig Universität Gießen Trento, May 26 - 30,

Multinucleon Transfer Reactions – a New Way to Exotic Nuclei? Sophie Heinz GSI Helmholtzzentrum and Justus-Liebig Universität Gießen Trento, May ,
Beta decay and Structure of Exotic Nuclei near 78 Ni Alexander Lisetskiy NSCL,JINA,MSU.

Beta decay and Structure of Exotic Nuclei near 78 Ni Alexander Lisetskiy NSCL,JINA,MSU.
Reaction rates in the Laboratory Example I: 14 N(p,  ) 15 O stable target  can be measured directly: slowest reaction in the CNO cycle  Controls duration.

Reaction rates in the Laboratory Example I: 14 N(p,  ) 15 O stable target  can be measured directly: slowest reaction in the CNO cycle  Controls duration.
Coulomb excitation and  -decay studies at (REX-)ISOLDE around Z = 28 J. Van de Walle – KVI - Groningen 1. ISOLDE and REX-ISOLDE ; 2. Results around Z=28.

Coulomb excitation and  -decay studies at (REX-)ISOLDE around Z = 28 J. Van de Walle – KVI - Groningen 1. ISOLDE and REX-ISOLDE ; 2. Results around Z=28.
Status of TACTIC: A detector for nuclear astrophysics Alison Laird University of York.

Status of TACTIC: A detector for nuclear astrophysics Alison Laird University of York.
Reaction rates in the Laboratory Example I: 14 N(p,  ) 15 O stable target  can be measured directly: slowest reaction in the CNO cycle  Controls duration.

Reaction rates in the Laboratory Example I: 14 N(p,  ) 15 O stable target  can be measured directly: slowest reaction in the CNO cycle  Controls duration.
Reaction rates in the Laboratory Example I: 14 N(p,  ) 15 O stable target  can be measured directly: slowest reaction in the CNO cycle  Controls duration.

Reaction rates in the Laboratory Example I: 14 N(p,  ) 15 O stable target  can be measured directly: slowest reaction in the CNO cycle  Controls duration.
Measurements of cross-sections of neutron threshold reactions and their usage in high energy neutron measurements Ondřej Svoboda Nuclear Physics Institute,

Measurements of cross-sections of neutron threshold reactions and their usage in high energy neutron measurements Ondřej Svoboda Nuclear Physics Institute,
1Managed by UT-Battelle for the U.S. Department of Energy Simulation of βn Emission From Fission Using Evaluated Nuclear Decay Data Ian Gauld Marco Pigni.

1Managed by UT-Battelle for the U.S. Department of Energy Simulation of βn Emission From Fission Using Evaluated Nuclear Decay Data Ian Gauld Marco Pigni.
Update on relevant proposals on beta-delayed neutron emission, recent experiments and evaluated data K.P. Rykaczewski Physics Division, ORNL Oak Ridge.

Update on relevant proposals on beta-delayed neutron emission, recent experiments and evaluated data K.P. Rykaczewski Physics Division, ORNL Oak Ridge.
Beta and particle decay spectroscopy at the Super FRS Zenon Janas Nuclear Spectroscopy Division Warsaw University.

Beta and particle decay spectroscopy at the Super FRS Zenon Janas Nuclear Spectroscopy Division Warsaw University.

Similar presentations

Ads by Google