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Discussion The National HEP Accelerator Based Program

This discussion focuses on the current state of the National HEP Accelerator Program and the need for capital investments to maintain its vitality. Emphasizing the importance of a realistic and world-class plan, it explores various avenues such as the Energy Frontier, Intensity Frontier, and Non-accelerator based experiments. Additionally, it highlights the significance of the International Linear Collider (ILC) and the potential of other possibilities like CLIC and muon colliders. The discussion also addresses the role of the US program in non-accelerator experiments and the intensity frontier, emphasizing the need for precision experiments to study new particles discovered at the LHC. Lastly, it introduces a program based on a new injector for the Fermilab complex, which utilizes ILC technology and positions the US program for future advancements.

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Discussion The National HEP Accelerator Based Program

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  1. DiscussionThe National HEP Accelerator Based Program APS, St. Louis April 12, 2008 Pier Oddone

  2. Present state • No investment made in renewal of national facilities since decision to build NUMI/MINOS in 1998 • To maintain vitality of the field must have capital investments: otherwise the business plan is to go out of business !! • The plan we have been on: shut everything down on hope of starting the ILC early

  3. Present state • Not surprising then: when ILC does not fit OSC budget profile or is late – we are in trouble • We need to re-invest in the national program or we face a very difficult time: we are shutting down $4B worth of facilities with no follow on • We need a realistic plan that can be done within the DOE office of Science profile. ILC decision not impossible in the future (but not immediate)

  4. Getting to a plan • The physics case must be compelling • It should be realistic • It should be world-class in its domain • It should be adaptable to new discoveries • It should be the community and laboratory plan

  5. Respect the rules of the road • Operating facilities with essential programs get top priority. Example: Tevatron running • Next priority is construction projects with a budget and a schedule (except at the very beginning) • R&D programs are squeezable when confronted with the top priorities for both the Administration and Congress: ample demonstrations

  6. HEP world: tools pp-bar pp e+e- m+m- Energy Frontier Intense n, m, K, .. beams; and B, C factories; Intensity Frontier Non-accelerator based Telescopes; Underground experiments;

  7. Energy Frontier: Tevatron • Greatest window into new phenomena until LHC is on. • Strong collaborations, viable through 2010 • About 80 archival papers/year and 80 PhD thesis/year. • Record luminosities. We should run until overtaken by LHC

  8. HEP world: the LHC dominates LHC

  9. CERN site and remote operations Compact Muon Spectrometer CMS Remote Operations Center at Fermilab

  10. HEP world: need TeV lepton collider International Linear Collider (ILC) ILC e- e+ LHC pp

  11. HEP world: the ILC • Strong world-wide collaboration on ILC: by far the easiest machine beyond the LHC – CLIC and muon colliders are more difficult. • ILC will be it – provided LHC tells us the richness is there. • Technology is broadly applicable – R&D on the technology is important: electron cloud effects, reliable high gradient cavities, final focus….

  12. Several possibilities for the future • By far the easiest is the ILC if the physics is kind • Significantly higher energies are difficult to achieve with ILC technology • Need for CLIC R&D (CERN+) and muon collider R&D (needs to ramp up)

  13. HEP world: non-accelerator • The big questions for non –accelerator experiments: nature of neutrinos (neutrino-less double beta decay, reactors), dark energy (DES, SNAP, LSST), gravity (LIGO, LISA), direct dark matter detection (CDMS, Xenon, COUPP….), proton decay, origin of cosmic rays • US program has done well so far: discovery of dark energy, CMB fluctuations (COBE, WMAP), baryon acoustic oscillations (SDSS), dark matter search limits (CDMS, Xenon, COUPP….), cosmic rays (Pierre Auger), GLAST about to be launched

  14. HEP world: non-accelerator • US program is well positioned: • Direct Dark Matter: CDMS-25kg, Noble Liquids, COUPP • Neutrino-less double beta decay: Majorana, EXO • Dark energy: DES, SNAP, LSST • DOE’s role is partial: many of these activities supported by other agencies (NSF, NASA) and lead to program anomalies in DOE’s program: can we do dark energy and not gravity?, or CMB?, etc.

  15. HEP world: intensity frontier • LHC and non-accelerator experiments tell us nothing about the neutrino mass hierarchy and CP violation, little about couplings of any new particles discovered at LHC or charged lepton flavor violation • These issues can be studied at the intensity frontier through a large and rich variety of experiments: essential to complete a unified view

  16. HEP world: intensity frontier • The general rule: • If the LHC discovers new particles – precision experiments tell about the physics behind through rates/couplings to standard particles • If the LHC does not see new particles – precision experiments with negligible rates in the SM are the only avenue to probe higher energies • Additionally, neutrino oscillations coupled with charged lepton number violating processes constrain GUT model building

  17. US and the intensity frontier • We have designed a program based on a new injector for the Fermilab complex. • Can exploits the large infrastructure of accelerators: Main Injector (120 GeV), Recycler (8GeV), Debuncher (8 GeV), Accumulator (8 GeV) – would be very expensive to reproduce today • New source uses ILC technology and helps development of the technology in the US • Provides the best program in neutrinos, and rare decays in the world (great with DUSEL) • Positions the US program for an evolutionary path leading to neutrino factories and muon colliders

  18. Fermilab and the intensity frontier

  19. Project X: Beam power / flexibility Recycler 8 GeV protons with 120 GeV MI protons Main Injector Protons 200 kW (Project X) 0* (SNuMI) 16 kW (NuMI-NOvA) 17 kW (NuMI-MINOS) 35-year-old injection (technical risk) SNuMI NuMI (NOvA) NuMI (MINOS) * Protons could be made available at the expense of 120 GeV power.

  20. Project X: expandability • Initial configuration exploits alignment with ILC • But it is expandable (we will make sure the hooks are there) • Three times the rep rate • Three times the pulse length • Three times the number of klystrons • Would position the program for a multi-megawatt source for intense muon beams at low <8 GeV energies – very difficult with a synchrotron.

  21. Project X: it is the best source • Neutrino program at 120 GeV (2.3 MW); 55% recycler available at 8 GeV (200kW) • We can develop existing 8 GeV rings to deliver and tailor beams, allowing full duty cycle for experiments with the correct time structure: K decays, m e conversion, g-2. • High rate experiments do not decrease protons-on target for the neutrino program at 120 GeV.

  22. Example: neutrino strategy • Build NOvA. With T2K and reactor: best shot at neutrinos, first glimpse of mass hierarchy depending on sin22q13 • Develop beamline, caverns/detectors for DUSEL – with new beam-line from Project X it is the ultimate super-beam experiment (water or LAr) • If neutrino factory is needed – large endowment with source and beamline done

  23. Example: neutrino strategy

  24. Example: m to e conversion • Could start with Booster beam: already better than MECO experiment • If signal found at 10 -16 level: study A dependence, with full Project X • If signal not found, extend search with higher beam levels – Full Project X

  25. Muon – electron conversion New Physics Scale (TeV) (Courtesy of Andre de Gouvea) Potential FNAL m e conv. expt.10-17~ 10-18 (Project X) - 10,000 1,000 •  e conversion detector MEG experiment ~ 10-13 - Model Parameter Compositeness SUSY

  26. Example: evolutionary path to ILC • Project X linac develops US capabilities towards an ILC • Positions Fermilab as potential host • Positions US to contribute on major part of the ILC • Allows concrete collaboration with potential partners

  27. NEUTRINO FACTORY Muon ColliderR&D Hall Rebunch (Upgradable to 2MW) Pre-Accel Cool Decay Phase Rot.& Bunch 0.2–0.8 GeV Target PROJECT X 4 GeVRing MUON COLLIDERTEST FACILITY RLA (1–4 GeV) Illustrative Vision Three projects of comparable scope:  Project X (upgraded to 2MW)  Muon Collider Test Facility  4 GeV Neutrino Factory Far Detectorat Homestake n Example: evolutionary path muons

  28. 1.5-4 TeV Muon Collider at Fermilab RLA Linac 2 detector  Muon Collider RLA Linac 1 Project X -factory beam MCTF Final Cooling

  29. Conclusion • It is possible to design a base program that satisfies the criteria listed earlier in this talk: • Runs the Tevatron until overtaken by LHC • Builds NOvA as first step in world class neutrino program • Builds Project X as the best high intensity platform in the world • Develops the technology for the ILC in the US through Project X and positions the US well for an ILC anywhere • Supports particle astrophysics and LHC upgrades • Has a “long throw” in terms of future possibilities at the intensity frontier (neutrino factory) and energy frontier (muon collider)

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