Title: Accelerator based Neutrino beams
1Accelerator based Neutrino beams
2Outline
- Existing facilities
- CNGS
- The super beam
- The neutrino factory
- The beta beam
- Conclusions
3Acknowledgments
- CNGS
- Konrad Elsener, CERN
- The Superbeam
- Helmut Haseroth, Konrad Elsener, Tsuyoshi Nakaya
- The Neutrino Factory
- The nufact study group
- The beta beam
- The beta beam working group
4CNGS
In Dec. 1999, CERN council approved the CNGS
project ? build an intense nm beam at
CERN-SPS ? search for nt appearance at
Gran Sasso laboratory (730 km from CERN)
long base-line nm -- nt oscillation experiment
note K2K (Japan) running NuMI/MINOS (US) under
construction
5CERN to CNGS
6The Gran Sasso laboratory
7The CERN part
Polarity change foreseen! but the intensity will
go down and the contamination goes up
8p / K profile at entrance to decay tunnel
9CNGS muon beam profiles
first muon pit
second muon pit
10Radial distribution of the nm- beam at Gran
Sasso
note 1 mm -gt 1 km
11Number of particles expected per year
For 1 year of CNGS operation, we
expect (4.8x1013 protons in SPS, 55 efficiency
-- 1997) protons on target 4.5 x 1019
pions / kaons at entrance to decay tunnel
5.8 x 1019 muons in first / second
muon pit 3.6 x 1018 / 1.1 x 1017
nm in 100 m2 at Gran Sasso 3.5 x
1012 Upgrade with a factor of 1.5 feasible but
requires investment in CERN injector complex
12Unwanted neutrino species
- Relative to the main nm component
- ne / nm 0.8
- anti-nm / nm 2.1
- anti-ne / nm 0.07
13CERN underground
14CNGS target station
15CNGS target
-gt 10 cm long graphite rods, Ø 5mm and/or
4mm
proton beam
Note - target rods interspaced to let the
pions out - target is helium cooled
(remove heat deposited by the particles)
16CNGS focusing devices
Magnetic Horn (S. v.der Meer, CERN)
length 6.5 m diameter 70 cm weight 1500
kg Pulsed devices 150kA / 180 kA, 1
ms water-cooled distributed nozzles
17Principle of focusing with a Magnetic Horn
Magnetic volume given by one turn at high
current ? specially shaped inner conductor -
end plates ? cylindrical outer conductor
18CNGS Horn test
19CNGS decay tube hadron stop
- dimensions of decay tube ? 2.45 m diameter
steel tubes, 6 m long pieces, 1 km total ?
welded together in-situ ? vacuum 1 mbar ?
tube embedded in concrete
- hadron stop ? 3.2 m graphite ? 15 m iron
blocks ? upstream end water cooled
20What is the Super Neutrino Beam?
- No Clear definition, but it is a very intense
neutrino beam produced by a high power (gt1MW )
accelerator. - A conventional method.
- Still technically challenging due to the high
power and the high radiation environment, but not
impossible. - Multiple targets
21Target stack?
22Neutrino factoryCERN
- Superconducting proton linac as driver
- Proton bunch train not longer than decay ring
- Bunch to bucket philosophy
- Longitudinal cooling using bunch rotation
- Transversal cooling using ionization cooling
- Recirculating linear accelerators
- Decay ring
23Neutrino factoryJapan
3 GeV and 50 GeV rings are part of JAERI-KEK
Joint Project
24American Study II
25Target and pion captureliquid jetHorn
26Pion Capture Solenoid
20T
1.25T
27Liquid jet
28Jet test at BNL
29Targetry
Many difficulties enormous power density ?
lifetime problems pion capture
Stationary target
Replace target between bunches Liquid mercury
jet or rotating solid target
Proposed rotating tantalum target ring
Sievers
Densham
30Ionization cooling
IN
Liquid H2 dE/dx
sol
H2
rf
Beam
sol
RF restores only P// E constant
OUT
31Cooling experiment
32Cooling - rings
Main advantages shorter longitudinal cooling
Balbekov
Palmer
33Comparison of General Layout
34b-beam baseline scenario
SPS
PS
35Objectives for CERN study
- Present a coherent and realistic scenario for
acceleration of radioactive ions - Use known technology (or reasonable
extrapolations of known technology) - Use innovations to increase the performance
- Re-use a maximum of the existing CERN
accelerators - Use the production limit for ions of interest as
starting point
36Low-energy stage
- Fast acceleration of ions and injection into
storage ring - Preference for cyclotrons
- Known price and technology
- Acceleration of 16 batches of 1.02x1012 or 2 1013
ions/s 6He(1) from 20 MeV/u to 300 MeV/u - Comment
- Bunching in cyclotron?
37Storage ring
SPL
ISOL Target ECR
Storage ring
Cyclotrons or FFAG
Fast cycling synchrotron
PS
SPS
Decay ring
- Charge exchange injection into storage ring
- Technology developed and in use at the Celsius
ring in Uppsala - Accumulation, bunching (h1) and injection into
PS of 1.02x1012 6He(2) ions - Question marks
- High radioactive activation of ring
- Efficiency and maximum acceptable time for charge
exchange injection - Electron cooling or transverse feedback system to
counteract beam blow-up
38Overview Accumulation
- Sequential filling of 16 buckets in the PS from
the storage ring
39PS
SPL
ISOL Target ECR
Storage ring
Cyclotrons or FFAG
Fast cycling synchrotron
PS
SPS
Decay ring
- Accumulation of 16 bunches at 300 MeV/u each
consisting of 2.5x1012 6He(2) ions - Acceleration to g9.2, merging to 8 bunches and
injection into the SPS - Question marks
- Very high radioactive activation of ring
- Space charge bottleneck at SPS injection will
require a transverse emittance blow-up
40SPS
SPL
ISOL Target ECR
Storage ring
Cyclotrons or FFAG
Fast cycling synchrotron
PS
SPS
Decay ring
- Acceleration of 8 bunches of 6He(2) to g150
- Acceleration to near transition with a new 40 MHz
RF system - Transfer of particles to the existing 200 MHz RF
system - Acceleration to top energy with the 200 MHz RF
system - Ejection in batches of four to the decay ring
41Decay ring
SPL
ISOL Target ECR
Storage ring
Cyclotrons or FFAG
Fast cycling synchrotron
PS
SPS
Decay ring
- Injection and accumulation will be described in
talk on Thursday - Major challenge to construct radiation hard and
high field magnets
42Intensities 18Ne
- From ECR source 0.8x1011 ions per second
- Storage ring 4.1 x1010 ions per bunch
- Fast cycling synch 4.1 x1010 ion per bunch
- PS after acceleration 5.2 x1011 ions per batch
- SPS after acceleration 4.9 x1011 ions per batch
- Decay ring 9.1x1012 ions in four 10 ns
long bunch - Only b-decay losses accounted for, efficiency lt50
43Intensities 6He
- From ECR source 2.0x1013 ions per second
- Storage ring 1.0 x1012 ions per bunch
- Fast cycling synch 1.0 x1012 ion per bunch
- PS after acceleration 1.0 x1013 ions per batch
- SPS after acceleration 0.9x1013 ions per batch
- Decay ring 2.0x1014 ions in four 10 ns
long bunch - Only b-decay losses accounted for, efficiency lt50
44Result of CERN study
- A baseline scenario for the beta-beam at CERN
exists - While, possible solutions have been proposed for
all identified bottlenecks we still have problems
to overcome and - it is certainly possible to make major
improvements! - Which could result in higher intensity in the
decay ring! - First results are so encouraging that the
beta-beam option should be fully explored - Investigate sites at other existing accelerator
laboratories - Study a Green field scenario
45Higher energy in the decay ring?
- LHC top rigidity (23270 Tm)
- 6He has a g2488.08
- 18Ne has a g 4158.19
- With a futuristic radiation hard
superconducting dipole design for the decay ring
with a field of 5 Tesla the radius of the arcs
will be r4654 m! - Bigger than LHC arcs!
- Lower intensities as LHC only can handle
transversally small bunches
46Neutron beams?
- As for a neutrino beam and neutron beam can be
created if a beta-delayed neutron emitter is
stored in the decay ring - High energy
- Physics case?
- Low energy
- Medical use neutron therapy
- Waste transmutation at neutron resonances
- Intensity?
47Comments
- The super beam can be available soon (when the
necessary high power drivers are completed) - The beta-beam is largely based on existing
technology but requires costly civil engineering
for the decay ring - Moderate extrapolations on target technology
- Strong synergies with projects in nuclear physics
- EURISOL
- GSI upgrade
- SPIRAL-2
- SPES in Legnaro
- Ion programme in LHC and low energy ion
(accelerator and) storage rings in Europe - The RD for a full scale muon based neutrino
factory is fascinating but very challenging - Target issues still requires major RD
- Ionization cooling has to be experimentally tested
48What I can see in the crystal ball
As any Harry Potter reader knows that the art of
crystal ball viewing is both very difficult and
often prone to errors!
- High power proton drivers become available
- Next generation ISOL RNB facilities
- Super beams
- Low energy electron neutrino beams available
- Physics case?
- The beta-beam is taken to higher energies
- Muon based neutrino factory starts delivering
beam
49Conclusion
- Beta-beam at CERN
- Low energy part will benefit nuclear physics
- Acceleration to high energy is likely to benefit
heavy ion programme - LHC beam brightness?
- Find a way of benefiting ion programme in LHC
with our decay ring and our luck might be made! - Having said that
- GSI is world leading on high energy ions
- Should open new possibilities at GSI for ions
- Having said that
- Italy is the only European country that seems
willing to invest in high energy physics
inclduing neutrinos and underground detectors - Low energy neutrino beams?
- Having said that
- GANIL is one of the centers for accelerated
radioactive ions - Low energy neutrino beams?
- I hope I have set out a promising future for the
research in to different aspects of the
beta-beam!