overview of the project x rd&d plan sergei nagaitsev aac meeting february 3, 2009
TRANSCRIPT
Overview of the Project X RD&D Plan
Sergei NagaitsevAAC Meeting
February 3, 2009
Page 2AAC, February 3, 2009 – Sergei Nagaitsev
What’s in this talk?
• RD&D plan scope– In May 2008 the AAC reviewed the RD&D plan:
http://projectx.fnal.gov/RnDplan/index.html
– Refined the Project X scope (eliminated target, Recycler slow spill);
– Disconnected from the ILC beam parameters and cavity gradient only;
– In Oct 2008 we released the ICD v1.0 and started the cost range estimate in preparation for CD0 (almost done).
– We are now adjusting the RD&D plan to match the ICD
• Changes to ICD– We already found inconsistencies in ICD v1.0; will update before Mar 09
• Alternative configurations– Moving with ACD in parallel with the ICD; ACD cost range will follow
– Part of the RD&D plan
Page 3AAC, February 3, 2009 – Sergei Nagaitsev
RD&D Program Goals
• The goal of the Project X RD&D program is to provide support for a CD-2/3a approval in 2012. Spans 4 FY’s.– Design and technical component development;
– Development of all project documentation mandated by DOE 413.3;
– Formation of a multi-institutional collaboration capable of executing both the R&D plan and the provisional construction project.
• The primary technical goal is completion of a Conceptual Design Report, followed by a fully developed baseline cost estimate and schedule, and supported by a technology development program.– Capability of delivering in at least 2 MW of beam power over the
range 60 – 120 GeV, simultaneous with at least 150 kW of beam power at 8 GeV.
Page 4AAC, February 3, 2009 – Sergei Nagaitsev
RD&D Technical Goals
• Complete conceptual design and cost estimate for Project X:– technical and conventional construction elements,– systems integration, and– installation and commissioning plan.
• Supporting technology development program targeting key accelerator physics and engineering challenges
– incorporating simulations, experiments, and prototype construction as appropriate.
• Alignment with the SRF/ILC program:– Primary goal is to develop a set of technologies applicable to both ILC
and Project X Common cavity/cryomodule design, rf sources and distribution
– Project X linac designed to accommodate accelerating gradients in the range 23.6 – 31.5 MV/m (XFEL – ILC)
Final design gradient determined prior to CD-2.
Page 5AAC, February 3, 2009 – Sergei Nagaitsev
Steps in Developing the RD&D Plan
• Design Criteria – high-level criteria for selection between designs– Guidance from P5, directorate, experiments, AAC (May 2008)
• Project Requirements - Receive the general requirements that support the desired physics
– Derived from the Nov. 2007 & Jan 2008 Physics workshops– Director’s Guidance
• Scope - Determine the scope of the project that meets the project requirements
• System Requirements - develop major system requirements– 10 systems (level-2 WBS elements)– 17 base requirements– 68 derived requirements
Page 6AAC, February 3, 2009 – Sergei Nagaitsev
Steps in Developing the RD&D Plan
• Issues - discuss issues arising from the requirements
• Elements - define the level-3 elements of an RD&D plan that– Addresses the issues arising from the requirements– Are directed towards a completion of Conceptual Design Report
• Resources and Schedule - estimate:– The resources required to complete the R&D plan– The schedule required to complete the R&D plan
• The RD&D plan was previously reviewed by the AAC (May 2008)– made modifications to ICD v1.0 following AAC recommendations– today we will review the entire plan but will concentrate on modifications
Page 7AAC, February 3, 2009 – Sergei Nagaitsev
Related Programs & Deliverables
• High Intensity Neutrino Source (HINS)– Bob Webber (APC)– Project X related deliverable: Prototype a 30 MeV Linac operating at
325 MHz providing 30mA of beam with a 1 ms pulse length
• Superconducting RF Infrastructure– Kephart (Directorate), Mishra (TD/Dir), Nagaitsev (AD/Dir)– Project X related deliverables:
– Develop 1 cryo-module/ month capability– Three = 1 and one = 0.8 cryo-modules– NML RF unit test facility & CM test stand– System Integration test with beam
• ILC Americas– Cavities and processing: Mark Champion (TD)– Cryomodule design & assembly: Carter (TD)
Page 8AAC, February 3, 2009 – Sergei Nagaitsev
Design Criteria
• Derived from 3 missions of Project X
• Neutrino program with MI: 2 MW at 60-120 GeV• Deliver 1.6e14 protons every 0.8 sec (with specific beam
requirements);
• Mu2e experiment at 8 GeV: 150 kW slow extraction• Specific beam requirement
• Deliver 1.4e13 protons per spill cycle (15-20 Hz)
• Provide a plausible self-consistent path to a 2-MW (and higher) proton source for a muon collider• single bunch, 2-ns rms, 15 Hz, 2mm rms spot size on target,
8-20 GeV
• We have concluded that the total Project X beam power of 0.5MW at 8 GeV is sufficient to meet first 2 criteria
Baselinemissions
Page 9AAC, February 3, 2009 – Sergei Nagaitsev
Project X scope
• The basic scheme of Project X is:– An 8 GeV Linac– H- stripping in the Recycler – Beam distributed to the Main Injector for acceleration to 120 GeV – Beam distributed to Accumulator/Debuncher for an 8 GeV slow spill program
• The major components that comprise Project X are:– A front end linac operating at 325 MHz (max energy 420MeV). – A high-energy linac operating at 1300MHz.– An 8 GeV transfer line and H- Injection system.– The Recycler operating as a stripping ring and a proton accumulator.– The Main Injector acting as a rapid cycling accelerator.– Civil Construction and Utilities– Controls– Cryogenics
Page 10AAC, February 3, 2009 – Sergei Nagaitsev
Project X scope
120 GeV fast extraction spill1.6 x 1014 protons/1.4 sec2 MW
8 GeV H- Linacup to 1.6x1014 x 5 HzFlex chopper pattern
To Accumulator
8 GeV extraction (fast)150 kW total
Stripping Foil
Recycler1 linac pulse/fill
Main Injector1.4 sec cycle
Single turn transfer @ 8 GeV
0.42-8 GeV HE Linac
0.42 GeV LE Linac
Page 11AAC, February 3, 2009 – Sergei Nagaitsev
Project X Requirements (ICD)
• ICD v1.0 exceeds the design criteria in terms of beam power
• Previous version of requirements (AAC May 2008): 360 kW (ILC-like) linac paramentrs– 1 MW at 8 GeV was arrived at by requiring that the MI is loaded in a
single linac pulse (1.6e14 ppp at 5 Hz)
Page 12AAC, February 3, 2009 – Sergei Nagaitsev
What is wrong with operating scenario in ICD?
1. Five out of seven linac pulses are unused.
2. 8e13 every 1.4 sec to Mu2e does not work – (1) high tune shift in Debuncher, (2) long emittance too high (150 eV-s)
3. Incorrect linac chopping pattern to extract 3 batches from Recycler
4. Note: Mu2e beam power in this scenario is 75 kW
Page 13AAC, February 3, 2009 – Sergei Nagaitsev
Operations scenario (60 GeV MI)
Page 14AAC, February 3, 2009 – Sergei Nagaitsev
Mu2e beam requirements
• Slow extraction from the Debuncher:– 8 GeV, 150-ns (FW) bunch length, 20 eV-s (95%) max. long.
emittance
– tune shift limit for slow extraction ≤0.05; 1.4e13 per bunch max.
• Recycler is filled with 7 barrier-bucket bunches (1-µs long), long. emitt. 10 eV-s, 0.6-µs gaps, 1.4e13 ppb– Requires a different chopping pattern
• Bunches are then transferred to the Accumulator (at ~15 Hz rate) for bunch rotation (10 ms) and then to the Debuncher
1 µs
7 bunches
Page 15AAC, February 3, 2009 – Sergei Nagaitsev
Bunch rotation for Mu2e
0.0 0.785 1.59
Time (sec)
0.0 0.785 1.59
Beam at Injection: LE= 10 eVsat t= 0 sec
Beam with h=1+2 buckets at t= 0 sec
E-E
0(M
eV
)E-E
0(M
eV
)
0.0 0.785 1.59
Time (sec)
-120 0 120E-E0(MeV)
Just before transfer to the Debuncherat t= 10msec
RMSW= 24 nsecFW=132 nsec
E-E
0(M
eV
)
RMSW= 29 MeVFW=100 MeV
Arb
itra
ry U
nit
s
Page 16AAC, February 3, 2009 – Sergei Nagaitsev
System Requirements
• Previously reviewed by the AAC (May 2008, Aug 2007)
• Once the major system requirements were formulated, a report was written (Jan 2008) that– Discussed issues arising from the requirements
– Defined the elements of an RD&D plan that
Addresses the issues arising from the requirementsAre directed towards a completion of Conceptual Design
Report– Estimated:
The resources required to complete the R&D planThe schedule required to complete the R&D plan
• The plan is documented at: projectx.fnal.gov/RnDplan/index.html
• We are now modifying the RD&D plan to meet the ICD system requirements
Page 17AAC, February 3, 2009 – Sergei Nagaitsev
Alternative configurations
• Alternative configuration studies are mandated by the DOE project Critical Decision process.
• ACD and its cost range estimate is being created in parallel/series to the ICD by the same people.
• Work on the ACD is part of the RD&D plan
• ACD is considered:– in support of baseline design criteria (neutrino and mu2e missions);
Examples: 1-ms pulse vs. 3-ms, TSR vs. L-band elliptical cavities
– in support of future upgrades; Path to 2 4 MW
– in support of project scope changes; not covered in this talk
Page 18AAC, February 3, 2009 – Sergei Nagaitsev
Why ACD for baseline missions?
• The Recycler is far from being ideal for the proton accumulation:– fixed energy, permanent magnets;
– small acceptance;
– Large transverse impedance because of wall resistivity;
– very long (3.3 km) for an 8 GeV ring;
– no solution found for slow extraction;
• Space-charge tune shift is an issue– The maximum tune shift is limited by how much beam losses one can
tolerate
– Fermilab Booster has a tune shift of -0.3 at injection (400 MeV); it looses 10-15% of particles at injection or 300 W (at 7.5 Hz operation)
– Fermilab MI presently has a tune shift of -0.18 at injection (w/ slip stacking); it looses 5% of particles (mostly because of slip stacking) at injection or 1.5 kW. Number of protons per bunch: 10e10
Page 19AAC, February 3, 2009 – Sergei Nagaitsev
Tune shift
• 2 MW operation in the MI requires 1.6e14 protons at injection in the Recycler and MI or 3e10 ppb 3 times what we have now.
• If do nothing -- beam losses will be too high.
• Our solution in the ICD – painting (transverse and longitudinal):– Make transverse distribution uniform (by “painting”)
– Make transv. emittance bigger: 15 to 25 µm (100%)
– Make bunches longer (long. emittance increase, two-harmonic rf)
• Ultimately, no more beam power upgrades for MI unless the injection energy is increased.
emittance 100% is ;2
1 :ondistributi Uniform nA
emittance 95% is ;2
3 :ondistributiGaussian nA bn
2
r CAN-
2
pb
Page 20AAC, February 3, 2009 – Sergei Nagaitsev
• Are based on the idea that one can reduce the linac energy by making a smaller-size ring with bigger acceptance
• A good alternative appears to be an 800-m Rapidly Cycling Synchrotron (1/4 of MI) with a 2-GeV injection
Alternative configurations
Pulsed H- Linac
Stripping Foil
Synchrotron
Page 21AAC, February 3, 2009 – Sergei Nagaitsev
Cartoon for scale
RCS
2GeV Linac
4GeV Linac
Page 22AAC, February 3, 2009 – Sergei Nagaitsev
Upgrade path
• Provide a plausible self-consistent path to a 2-MW (and higher to 4 MW) proton source for a muon collider
• Project X -> – Neutrino factory -> Muon collider
• We have to anticipate a coherent upgrade path– Energy choice
– Initial infrastructure choice
– Future developments
• The most general structure for Muon collider proton source – Linac -> Synchrotron (?) -> Accumulator ring (?) -> Compressor ring
– single bunch, 2-ns rms, 15 Hz (or higher), 5-20 GeV, 2mm rms spot size on target
Page 23AAC, February 3, 2009 – Sergei Nagaitsev
Alternatives to be considered
Present Project-X with injection to Recycler + Compressor ring
Project-X linac + Compressor ring with direct H- strip injection
Alternative Project-X + compressor ring
Linac Synchrotron Compressor ring Target (2 GeV) (21 GeV, 15 Hz) (21 GeV)
Linac Compressor ring Target (8 GeV) (8 GeV)
Recycler
Linac Recycler Compressor ring Target (8 GeV) (8 GeV, ~3 km) (8 GeV)
1
2
3
Page 24AAC, February 3, 2009 – Sergei Nagaitsev
ICD and ACD
I CD Linac energy 8 GeV Max. linac current (no chopping) 30 mA Average linac current (53 MHz chopping) 20 mA Pulse duration 1.25 ms Repetition rate 5 Hz Power 1 MW
ACD(preliminary) Stage 1 Stage 2 Linac energy 2 GeV Synchrotron energy, GeV 8 21 Average linac current (53 MHz chopping) 20 mA Pulse duration 0.32 ms Repetition rate, Hz 15 15 Power, MW 0.5 2.2
Meets design criteria for nu and mu2e
Page 25AAC, February 3, 2009 – Sergei Nagaitsev
Conclusions for upgrades study(preliminary)
• Option 1 does not work
• Option 2 has a limited beam power reach: 1 MW for 8 GeV, 15 Hz, single bunch (2-ns rms, 2-mm rms size)
• Option 3 has a power reach to 4 MW at 21 GeV, allows to increase the beam power in the MI beyond 2 MW by increasing injection energy to 21 GeV.
Page 26AAC, February 3, 2009 – Sergei Nagaitsev
Summary
• The design criteria and general requirements of Project X are defined
• From the general requirements:– The scope of Project X is defined
– The requirements of the technical subsystems are derived
• The system requirements drive the design and development plan goals.
• A RD&D team was assembled to formulate and execute the design and development plan.
• The updated RD&D plan will be released by the end of February, and will incorporate input from this meeting
• Specific goals for each sub-system have been defined.
• The resources required to accomplish these goals have been defined.