• M.J. Hogan, I. Blumenfeld, N.A. Kirby, S. Pei, T.O. Raubenheimer, A. Seryi, P. Tenenbaum
  SLAC, Menlo Park, California
• C. Huang, C. Joshi, W. Lu, W.B. Mori
  UCLA, Los Angeles, California
• T.C. Katsouleas
  Duke University, Durham, North Carolina
• P. Muggli
  USC, Los Angeles, California

Funding: Work supported in part by the U.S. Department of Energy under contract number DE-AC02-76SF00515.

Recent progress in generating gradients in the 10's of GV/m range with beam driven plasmas has renewed interest in developing a linear collider based on this technology. This talk will explore possible configurations of such a machine, discuss the key demonstrations and the facilities needed to advance this effort and highlight possible alternative uses of this technology.

Slides

• M.J. Hogan, I. Blumenfeld, N.A. Kirby, S. Pei, T.O. Raubenheimer, A. Seryi, P. Tenenbaum
  SLAC, Menlo Park, California
• C. Huang, C. Joshi, W. Lu, W.B. Mori
  UCLA, Los Angeles, California
• T.C. Katsouleas
  Duke University, Durham, North Carolina
• P. Muggli
  USC, Los Angeles, California

Funding: Work supported in part by the U.S. Department of Energy under contract number DE-AC02-76SF00515.

An electron beam driven Plasma Wake-Field Accelerator (PWFA) has recently sustained accelerating gradients above 50GeV/m for almost a meter. Future experiments will transition from using a single bunch to both drive and sample the wakefield, to a two bunch configuration that will accelerate a discrete bunch of particles with a narrow energy spread and preserved emittance. The plasma works as an energy transformer to transform high-current, low-energy bunches into relatively lower-current higher-energy bunches. This method is expected to provide high energy transfer efficiency (from 30% up to 95%) from the drive bunch to the accelerated witness bunch. The PWFA has a wide variety of applications and also has the potential to greatly lower the cost of future accelerators. We discuss various possible uses of this technique such as: linac based light sources, injector systems for ring based synchrotron light sources, and for generation of electron beams for high energy electron-hadron colliders.

• C. Huang, W. An, C.E. Clayton, C. Joshi, W. Lu, K.A. Marsh, W.B. Mori, M. Tzoufras
  UCLA, Los Angeles, California
• I. Blumenfeld, M.J. Hogan, N.A. Kirby, T.O. Raubenheimer, A. Seryi
  SLAC, Menlo Park, California
• T.C. Katsouleas
  Duke University, Durham, North Carolina
• P. Muggli
  USC, Los Angeles, California

Funding: Work supported by DOE under contracts DE-FG03-92ER40727, DE-FG52-06NA26195, DE-FC02-07ER41500, DE-FG02-03ER54721.

Recent Plasma Wake-Field Acceleration (PWFA) experiments at Stanford Linear Accelerator Center has demonstrated electron acceleration from 42GeV to 84GeV in less than one meter long plasma section. The accelerating gradient is above 50GeV/m, which is three orders of magnitude higher than those in current state-of-art RF linac. Further experiments are also planned with the goal of achieving acceleration of a witness bunch with high efficiency and good quality. Such PWFA sections with 25 GeV energy gain will be the building blocks for a staged TeV electron-positron linear collider concept based on PWFA (PWFA-LC). We conduct Particle-In-Cell simulations of these PWFA sections at both the initial and final witness beam energies. Different design options, such as Gaussian and shaped bunch profiles, self-ionized and pre-ionized plasmas, optimal bunch separation and plasma density are explored. Theoretical analysis of the beam-loading* in the blow-out regime of PWFA and simulation results show that highly efficient PWFA stages are possible. The simulation needs, code developments and preliminary simulation results for future collider parameters will be discussed.

*M. Tzoufras et al, Phys. Rev. Lett. {10}1, 145002 (2008).

• I. Blumenfeld, F.-J. Decker, M.J. Hogan, R. Ischebeck, R.H. Iverson, N.A. Kirby, R. Siemann, D.R. Walz
  SLAC, Menlo Park, California
• C.E. Clayton, C. Huang, C. Joshi, W. Lu, K.A. Marsh, W.B. Mori, M. Zhou
  UCLA, Los Angeles, California
• T.C. Katsouleas, P. Muggli, E. Oz
  USC, Los Angeles, California

High gradient acceleration of electrons has recently been achieved in meter scale plasmas at SLAC. Results from these experiments show that the wakefield is sensitive to parameters in the electron beam which drives it. In the experiment the bunch lengths were varied systematically at constant charge. Here we investigate the correlation of peak beam current to the wake amplitude. The effect of beam head erosion will be discussed and an experimental limit on the transformer ratio set. The results are compared to simulation.

• N.A. Kirby, I. Blumenfeld, M.J. Hogan, R. Siemann, D.R. Walz
  SLAC, Menlo Park, California
• A.W. Davidson, C. Huang
  UCLA, Los Angeles, California

The effect of ion motion and the need for practical positron propagation in a plasma wakefield accelerator (PWFA) have incited interest in hollow plasma channels. These channels are typically assumed to be cylindrically symmetric; however, a different geometry might be easier to achieve. The introduction of an obstruction into the outlet of a high Mach number gas jet can produce two parallel slabs of gas separated by a density depression. Here, there is a detailed simulation study of the density depression created in such a system. This investigation reveals that the density depression is insufficient at the desired plasma density. However, insights from the simulations suggest another avenue for the creation of the hollow slab geometry.