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How can one produce rare isotopes? Question Slid 3 Hendrik Schatz NNPSS 2012, Slide 3 Rare Isotope Production Techniques: Uniqueness of FRIB Target spallation.

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Presentation on theme: "How can one produce rare isotopes? Question Slid 3 Hendrik Schatz NNPSS 2012, Slide 3 Rare Isotope Production Techniques: Uniqueness of FRIB Target spallation."— Presentation transcript:

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2 How can one produce rare isotopes? Question

3 Slid 3 Hendrik Schatz NNPSS 2012, Slide 3 Rare Isotope Production Techniques: Uniqueness of FRIB Target spallation and fragmentation by light ions ( ISOLDE/HRIBF/TRIUMF ) Neutron induced fission (2-step target) ( SPIRAL2/TRIUMF ) In-flight Separation following projectile fragmentation/fission ( RIKEN,FAIR,FRIB ) beam target beam target Target/Ion Source Accelerator Neutrons/Photons Accelerator Fragment Separator Beam Gas cell catcher/ion source Beams used without stopping Accelerator

4 Hendrik Schatz, NNPSS 2012 Slide 4 Photo fission yields

5 Slid 5 Hendrik Schatz NNPSS 2012, Slide 5 Rare Isotope Facilities Around the World NSCL/FRIB Notre Dame ATLAS TEXAS A&M TRIUMF Sao Paulo HRIBF Catania GANIL ISOLDE GSI/FAIR Jyvaeskyla Louvain Kolkata Lanzhou Dubna Tokyo RIKEN/RIBF Legnaro KORIA

6 Hendrik Schatz, NNPSS 2012 Slide 6 Timelines for major facilities Rare Isotope Assessment Committee, NRC/NAS study 2006

7 Final Civil Design A. Presenter, FRIB Project Overview, Date, Slide 7

8 Rendered Perspective Southeast View Sherrill NN2012, Slide 8

9 Civil Construction Moving Forward Civil construction began 3 March 2014 A. Presenter, FRIB Project Overview, Date, Slide 9 Web cams at frib.msu.edu FRIB CONSTRUCTION SITE – JANUARY 2015

10 FRIB Layout example: nuclear astrophysics experiment, Slide 10 Sherrill NN2012 Target Folding Segment 2 Linac Segment 3 Linac Segment 1 Beam Delivery System Front End Reaccelerator Linac Segment 2 Fast Beam AreaGas StoppingStopped Beam AreaReaccelerated Beam Area Fragment Separator Folding Segment 1 LINAC Target Fragment separator Isotope harvesting Gas Stopping Gas stopped beams: Mass measurements Laser spectroscopy Fast beams: Charge exchange Drip line Knockout, Coulex TOF masses Decay studies ReA3 Reaccelerator ReA3 reaccelerated beams: Astrophysical rates Lighter nuclei transfer Coulex ReA6,9,12 Reaccelerator ReA6-12 reaccelerated beams: High spin Transfer reactions  -spectroscopy

11 FRIB is estimated to produce more than 1000 NEW isotopes at useful rates (4500 available for study; compared to 1900 now) Exciting prospects for study of nuclei along the drip line to A=120(compared to A=24) Production of most of the key nuclei for astrophysical modeling Theory is key to making the right measurements and interpreting them The Reach of FRIB Rates are available at http://groups.nscl.msu.edu/frib/rates/ Sherrill NN2012, Slide 11

12 Fast beams (>100 MeV/u) –Farthest reach from stability, knockout, Coulomb exictation, nuclear structure, limits of existence, EOS of nuclear matter Stopped beams (0-100 keV) –Precision experiments – masses, moments, atomic structure, symmetries Reaccelerated beams (0.2-20 MeV/u) –Detailed nuclear structure studies, high-spin studies –Astrophysical reaction rates Fast, Stopped, and Reaccelerated Beams for Broad Science Opportunities Sherrill NN2012, Slide 12

13 The Reach of FRIB Sherrill NN2012, Slide 13 Estimated Possible: Erler, Birge, Kortelainen, Nazarewicz, Olsen, Stoitsov, to be published Based on a study of EDF parameters Known – isotopes with at least one excited state known Up to Z=90 FRIB will be able to make >80% of all possible isotopes

14 Why is it called FRIB ??? 1. frib 17 up, 6 down birf spelled backwards 2. frib 4 up, 12 down A word that can be used to describe happiness, joy etc. Commonly replaces 'wow', 'cool' or 'great'.

15 Coupled Cyclotron Facility since 2001

16 Fragmentation production of rare isotopes

17 B  selection separates m/q so for production at fixed velocity v B  ~ m/q

18 Fragment yield after Br selection

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20 A1900 Fragment Separator

21 Event by event particle identification Ion Source: 86 Kr beam 86 Kr beam 140 MeV/u Tracking Implant beam in detector and observe decay Time of flight measurement Measure p/q by tracking at dispersive focus Combine with TOF velocity measurement get m/q Energy loss measurement Measure energy loss in Si detector get Z

22 r-process nuclei Time of flight (m/q) Energy loss in Si (Z) 77Ni 78Ni 75Co 74Co 73Co 78 Ni Doubly Magic ! (  ~20 fb) 11 per week FRIB: 50 per second! 78 Ni Doubly Magic ! (  ~20 fb) 11 per week FRIB: 50 per second! Fast RIB from fragmentation: no decay losses any beam can be produced multiple measurements in one high sensitivity 1:10 14 Fast RIB from fragmentation: no decay losses any beam can be produced multiple measurements in one high sensitivity 1:10 14 Particle Identification

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