Solid Target Options NuFACT’00 S. Childress Solid Target Options The choice of a primary beam target for the neutrino factory, with beam power of 1 - 4.

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Presentation transcript:

Solid Target Options NuFACT’00 S. Childress Solid Target Options The choice of a primary beam target for the neutrino factory, with beam power of MW, is challenging - with target integrity a serious concern. Much of the recent focus has been toward a liquid heavy metal jet target - a ‘disposable” target for long-term viability with intense radiation, and using Hg for high pion yield. However, a new set of issues must now be addressed. Concerns with a liquid metal jet target include –viability in 20- T solenoid field – jet integrity with pressure wave effect induced by proton beam – potential severe contamination problems –complexity of target system design in a very difficult radiation environment Perhaps most important –requirement for costly, lengthy and challenging R & D program to demonstrate basic feasibility

Solid Target Options NuFACT’00 S. Childress Case for a Solid Target A neutrino source can provide substantial physics capability with MW beams. This level of beam power is higher than for existing solid target designs - but not by a large factor. NuMI graphite target design (400 kW beam) has similar energy deposition density as a 1 MW neutrino source. Recent successful beam testing. A great deal of experience exists with solid targets of different materials exposed for long duration to high beam power. Includes –CERN & FNAL p-Bar production –RAL: Spallation neutron source Simpler system design Readily compatible with high magnetic field environment Easier replacement capability –several months is a viable target lifetime R & D questions more readily addressable

Solid Target Options NuFACT’00 S. Childress Case for Solid Target (cont) Perhaps the most important point in favor of an approach toward initial MW operation using a solid target: substantial physics capability & target feasibility issues can be credibly addressed with modest resources in a short time. This type of approach is very important (and may be crucial) in progress toward a real facility How to proceed: Design target facility and support services for full 4 MW capability. Upgrade here is very difficult. (P. Spampinato - ORNL) Timely pursuit of R & D - both modeling and beam studies - to understand solid target limits and design optimization.

Solid Target Options NuFACT’00 S. Childress Target Material Choice Particle yields improve with higher z targets – N. Mokhov - FNAL (MARS) At 16 GeV, flux yield for Hg / C ~ 1.7 / 1. However, For low z target, much less power is deposited in the target for the same pion yield –power deposited in target = 5 / 1 for Hg / C. Only ~ 37 kW in C target with 1.5 MW beam A factor of 3 net gain to C in target power deposition for the same yield (but higher beam power) High beam power solid targets frequently use higher z materials for increased yield plus other techniques to compensate for high power deposition –FNAL p-Bar: rotating disks (CuNi) –CERN: Ti target encased in graphite New proposed concepts also –B. King - BNL considers a rotating band target geometry to spread energy deposition over a large target area

Solid Target Options NuFACT’00 S. Childress Target Material Choice (cont) For neutrino source ( GeV) and given target material in a solenoid capture field, yield is optimized using a simple bare suspended target –figure shows J. Chesser -ORNL concept for a graphite target Most promising solid target material considering combined effects of yield, survivability and initial design simplicity is carbon (graphite).

Solid Target Options NuFACT’00 S. Childress NuMI Graphite Target NuMI Beam: –4  GeV protons / 1.9 sec (400 kW) 8 μs spill –1 mm beam size (  ) at target, max. deposition density ~ 0.11 GeV/cc/p –Similar beam energy deposition density as a 1 MW Neutrino Source but with different time structure Target design criteria include: –Maximal neutrino yield –Reliability for > ten million pulses ( 1 year, with peak deposition about 5 dpa / year) –Module replacement capability Target design by IHEP, Protvino (V. Garkusha Group) –water cooled graphite – numi/beam/beam.html Graphite 3.2 mm width, 0.96 m length Fin design with slots to form ‘teeth’ Successful initial beam test –FNAL p-Bar facility, 1  per pulse, 0.25 mm sigma beam to reach > 1 dpa.

Solid Target Options NuFACT’00 S. Childress Challenge of nsec Beam Spill One of the most challenging parameters for target survival is intense energy deposition in a few nsec beam spill –A. Hassanein - ANL calculation of pressure wave dependence on energy deposition time (HEIGHTS code)

Solid Target Options NuFACT’00 S. Childress Pressure Wave Modeling Neutrino source parameters –graphite target with 7.5 mm radius, 80 cm length –16 GeV proton beam with  (x,y) of 3 mm. RMS bunch length 3 nsec. 1.5 MW incident beam power. 15 Hz

Solid Target Options NuFACT’00 S. Childress Target Cooling Radiative cooling for graphite target appears feasible –J. Haines - ORNL calculations –Surface temp ave. ~1850 deg. C Water cooling complicates flux optimization & must also be aware of survival for cooling tubes

Solid Target Options NuFACT’00 S. Childress Graphite Target R & D Priorities: –Detailed understanding of shock effects vs. target shape, material configuration - Model comparison and cross-checks –Single pulse high intensity beam testing in new BNL A-3 beam – Measurement of radiation degradation effects - High power short spill beam - Los Alamos –Optimize cooling approach & target design based on model & beam test feedback Near term R & D efforts (during the upcoming year) can give strong evidence toward a viable graphite target design for a Neutrino Source See how far we can go with the most simple type of target design - it may well be a very long way.