Challenges%20for%20EURISOL%20and%20the%20EURISOL%20Design%20Study - PowerPoint PPT Presentation

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Title: Challenges%20for%20EURISOL%20and%20the%20EURISOL%20Design%20Study


1
Challenges for EURISOL and the EURISOL Design
Study
  • Yorick Blumenfeld

2
OUTLINE
  • The  Standard  scientific case
  • The EURISOL concept and performances
  • Technical Challenges and the Design Study
  • Task 10 Physics and Instrumentation
  • Goals of the Workshop

3
The Nuclear Chart and Challenges
4
ab initio calculations for light nuclei
  • Systematic study of light nuclei (Alt12) shows the
    necessity of including a 3-body force

R.B. Wiringa and S.C. Pieper, Phys. Rev. Lett.
89 (2002) 182501
5
Modification of magic numbers far from stability
E (MeV)
Lowest 2 state
6
Effect of shell closures on element abundances
7
46Ar(d,p) 10 MeV/A _at_ SPIRAL with MUST
L. Gaudefroy, thèse
8
Neutron-proton pairing
  • n-p pairing can occur in 2 different states T0
    and T1. The former is unique to n-p. It can be
    best studied in NZ nuclei through spectroscopy
    and 2-nucleon transfer reactions.

9
Collective Modes
Atomic nuclei display a variety of collective
modes in which an assembly of neutrons moves
coherently e.g Low-lying vibrations and
rotations. ChallengeWill new types of
collective mode be observed in neutron-rich
nuclei in particular?
Will the nucleus become a three- fluid
system-made up of a proton and neutron core
plus a skin of neutrons? We will then get
collective modes in which the skin moves
relative to the core.
From W. Gelletly
10
Two-proton radioactivity near the proton drip-line
Proton energy and angle correlations ? di-proton
emission?
J. Giovinazzo et al., PRL89 (2002) 102501
11
Super heavy elements discovery and spectroscopy
294118
GSI Z?112 RIKEN Z113 DUBNA Z to 118?
  • Synthesis of new elements/isotopes (Z ? 120)
  • Spectroscopy of Transfermium elements (Z ?
    108)
  • Shell structure of superheavy nuclei

12
Studying the liquid-gas phase transition far from
stability
Muller Serot PRC 1995
Neutron rich nuclei
isospin distillation
pressure
Bonche Vautherin NPA 1984
asymmetry rp/rn
Proton rich nuclei vanishing limiting
temperatures
From Ph. Chomaz and F. Gulminelli
13
Radioactive beam production Two complementary
methods
GANIL/SISSI, GSI, RIKEN, NSCL/MSU
High energy, large variety of species, Poor
optical qualities, lack of energy flexibility
GANIL/SPIRAL, REX/ISOLDE, ISAAC/TRIUMF
good beam qualities, flexibility, intensity Low
energy, chemistry is difficult
14
The NuPECC Recommendation
NuPECC recommends the construction of 2 next
generation RIB infrastructures in Europe, i.e.
one ISOL and one in-flight facility. The
in-flight machine would arise from a major
upgrade of the current GSI facility, while
EURISOL would constitute the new ISOL facility
15
The EURISOL Road Map
  • Vigorous scientific exploitation of current ISOL
    facilities EXCYT, Louvain, REX/ISOLDE, SPIRAL
  • Construction of intermediate generation
    facilities MAFF, REX upgrade, SPES, SPIRAL2
  • Design and prototyping of the most specific and
    challenging parts of EURISOL in the framework of
    EURISOL_DS.

16
SPIRAL2
17
The EURISOL Concept
18
The EURISOL Concept
Total cost 613 M
19
Some beam intensities
Calculations for EURISOL Helge Ravn
6He 5X1013 pps 18Ne 5X1012 pps
20
Yields after acceleration Comparison between
facilities
a)
Kr isotopes
a)
Yield for in-flight production of fission
fragments at relativistic energy
21
Experimental Areas
Astrophysics
Structure
Low Energy
Reactions
22
The Major Technological Challenges for EURISOL
  • 5 MW proton accelerator also capable of
    accelerating A/Q 2.
  • Target(s) sustaining this power and allowing fast
    release of nuclei
  • Efficient and selective ion sources producing
    multi-charged ions
  • Multi charge state acceleration of radioactive
    beams with minimal losses
  • Radioprotection and safety issues

23
The EURISOL_DS in the 6th framework
  • Detailed engineering oriented studies and
    technical prototyping work
  • 21 participants from 14 countries
  • 21 contributors from Europe, Asia and North
    America
  • Total Cost 33 M
  • Contribution from EU 9.16 M

24
11 Tasks
  • Physics, beams and safety
  • Physics and instrumentation (Liverpool)
  • Beam intensity calculations (GSI)
  • Safety and radioprotection (Saclay)
  • Accelerators Synergies with HIPPI (CARE)
  • Proton accelerator design (INFN Legnaro)
  • Heavy ion accelerator design (GANIL)
  • SC cavity development (IPN Orsay) SC cavity
    prototypes and multipurpose cryomodule
  • Targets and ion sources Synergies with
    spallation sources
  • Multi-MW target station (CERN) mercury
    converter
  • Direct target (CERN) Several target-ion source
    prototypes
  • Fission target (INFN Legnaro) UCx target
  • BB Synergies with BENE
  • Beam preparation (Jyväskylä) 60 GHz ECR source
  • Beta-beam aspects (CERN)

25
TASK 10 Physics Instrumentation
  • Robert Page, Angela Bonaccorso, Nigel Orr
  • Expected Deliverables
  • Broad scientific goals selected
  • Key experiments selected
  • Evaluation of feasibility
  • Conceptual design of apparatus
  • Costing of instrumentation
  • Definition of beam properties

26
Goals of the Workshop
  • Update the Physics Case new ideas and new
    concepts.
  • What are the key experiments which will test
    these concepts?
  • What are the requirements of the facility
    species, energy, .
  • How do we carry forward the involvement of
    theoreticians in the Design Study, and more
    generally in the EURISOL road map.

27
Combination of beta beam with low energy super
beam
Unique to CERN- based scenario combines CP and
T violation tests ?e ? ?m (?) (T)
?m ? ?e (p) (CP) ?e ? ?m (?-) (T)
?m ? ?e (p-)
28
CERN-SPL-based Neutrino SUPERBEAM
300 MeV n m Neutrinos small contamination from
ne (no K at 2 GeV!)
Fréjus underground lab.
A large underground water Cerenkov (400 kton)
UNO/HyperK or/and a large L.Arg detector. also
proton decay search, supernovae events solar and
atmospheric neutrinos. Performance similar to
J-PARC II There is a window of opportunity for
digging the cavern starting in 2008 (safety
tunnel in Frejus or TGV test gallery)
29
CERN b-beam baseline scenario
30
Time scales
2005 2007 2010 2012
2016
FAIR
Project definition Construction Exploitation
31
AGATA(Advanced GAmma Tracking Array) 4p ?-array
for Nuclear Physics Experiments at European
accelerators providing radioactive and
high-intensity stable beams
Main features of AGATA Efficiency
40 (M? 1) 25 (M? 30) todays arrays 10
(gain 4) 5 (gain 1000) Peak/Total 55
(M?1) 45 (M?30) today 55
40 Angular Resolution 1º ? FWHM (1 MeV,
v/c50) 6 keV !!! today 40 keV Rates 3 MHz
(M?1) 300 kHz (M? 30) today 1 MHz
20 kHz
180 or 120 large volume 36-fold segmented Ge
crystals in 60 or 40 triple-clusters Digital
electronics and sophisticated Pulse Shape
Analysis algorithms allow Operation of Ge
detectors in position sensitive mode ? ?-ray
tracking Demonstrator ready by 2007
Construction of full array from 2008 ??
J. Simpson
32
The Rare Isotope Accelerator(USA)
33
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