| Cover |
Part
A. An 8 GeV Synchrotron-Based Proton Driver |
Part
B. A 2-MW Main Injector and Upgrade of Beamlines |
| Executive Summary |
1.
Introduction
1.1. Overview
1.2. PD2 vs. PD1
1.3 PD2 vs. the Present Booster |
13.
Introduction
13.1. Introduction
13.2. Main Injector modifications and upgrades
13.3. Beamline upgrades
13.4. Conclusion |
| Author List |
2. Machine Layout and Performance
2.1. Overview
2.2. Siting
2.3. Major design parameters
2.4. Operation modes |
14.
Beam Dynamics
14.1. Space charge and beam stability
14.2. Longitudinal dynamics |
|
3. Optics
3.1. Requirements, constraints, and features
3.2. Lattice description
3.3. Analysis
3.4. Alternative designs |
15.
RF Upgrade
15.1. PD2 rf requirements
15.2. Existing MI rf system
15.3. Rf voltage, power, bucket area, and stability
15.4. Transient beam loading considerations
15.5. Cavity amplifier upgrade considerations
15.6. Main Injector rf R&D program
15.7. Summary of modifications to existing rf cavities
15.8. Increased ramp and repetition rate
15.9. Proposal for a new Main Injector rf amplifier/cavity design |
| Appendix 1: Cost Estimates |
4.
Beam Dynamics
4.1. Space charge and beam stability
4.2. Longitudinal dynamics |
16.
Gamma-t Jump System
16.1. System description and lattice
16.2. Pulsed quadrupole
16.3. Power supplies
16.4. Beam pipes
16.5. Controls |
| Appendix 2: R&D Program |
5.
Technical Systems
5.1. RF
5.2. Magnets
5.3. Power supplies
5.4. Vacuum
5.5. Control system |
17. Large Aperture Quadrupole |
| Appendix 3: Charge from the Director -- Jan.
10, 2002, Mike Witherell to Bill Foster and Weiren Chou |
6. Beam Loss, Collimation and Shielding
6.1. Beam loss and shielding strategy
6.2. Collimation system
6.3. Radiation analysis |
18.
Passive Damper and Active Feedback
18.1. Rf cavity passive spurious mode damping
18.2. Longitudinal feedback and damping |
|
7. Injection and Extraction
7.1. Injection
7.2. Extraction |
19. Radiation, Shielding and Collimation
19.1. Radiation and shielding
19.2. Collimation |
|
8. H- Source and Linac Improvements and Upgrade
8.1. Introduction
8.2. Low energy improvements
8.3.Side-coupled cavity modules from 400 MeV to 600 MeV
8.4. New beam diagnostics and control requirements
8.5. Shielding issues
8.6. Recent measurements of the losses in the linac
Appendix. 402 MHz low-energy linac replacement |
20.
Upgrade of Other Technical Systems
20.1. Magnets
20.2. Power supplies
20.3. Mechanical and utility
20.4. Kickers
20.5. Beam abort dump
20.6. Controls |
|
9. 600-MeV and 8-GeV Beam Transport Lines |
21. Upgrade of Beamlines
21.1. NuMI Beamline
21.2. MiniBooNE Beamline
21.3. Meson, neutrino, and proton external beam areas |
|
10. Civil Construction
10.1. Introduction
10.2. Overview
10.3. Detailed facilities descriptions
10.4. Civil construction issues for linac extension
10.5. Civil construction schedule |
|
|
11. Environment, Safety and Health Considerations
11.1. Introduction
11.2. Overall view of procedure/regulatory matters
11.3. E. S. & H. considerations during construction
11.4. E. S. & H. considerations during operation
11.5. Summary
11.6. Need for work on environmental and safety issues |
|
|
12. Future Upgrade |
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