2011 Particle Accelerator Conference - List of Authors (Lu, W.)

Paper

Title

Page

Preliminary Simulations of Plasma Wakefield Accelerator Experiments at FACET

136

W. An, C. Joshi, W. Lu, W.B. Mori
UCLA, Los Angeles, California, USA
M.J. Hogan
SLAC, Menlo Park, California, USA
C. Huang
LANL, Los Alamos, New Mexico, USA

Funding: This work is supported by USDoE under DE-FC02-07ER41500, DE-FG02-92ER40727 and NSF under NSF PHY-0904039, PHY-0936266.
Recent experiments on former facility FFTB at SLAC has demonstrated that a single electron beam driven Plasma Wakefield Accelerator (PWFA) can be produced with an accelerating gradient of 52 GeV/m over a meter-long scale*. If another electron bunch is properly loaded into such a wakefield, it will obtain a high energy gain in a short distance as well as a small energy spread. Such PWFA experiment with two bunches will be performed in FACET, which is a new facility at SLAC**. Simulation results show that with possible beam parameters in FACET the first electron bunch (with less current than that in the FFTB experiment) can still produce a meter-long plasma column with a density of 5x10¹⁶ cm^-3 via field ionization when we use a gas with a lower ionization energy. The second electron bunch can have a 10 GeV energy gain with a very narrow energy spread. If a pre-ionized plasma is used instead of the neutral gas, the energy gain of the second bunch can be enhanced to 30 GeV.
* I. Blumenfeld et al., Nature 445, 741 (2007).
** M. J.Hogan, et al.,NewJ. Phys.12, 055030(2010).

MOP088

A High Transformer Ratio Plasma Wakefield Accelerator Scheme for FACET

265

R.J. England, J.T. Frederico, M.J. Hogan
SLAC, Menlo Park, California, USA
W. An, C. Joshi, W. Lu, W.B. Mori
UCLA, Los Angeles, California, USA
P. Muggli
USC, Los Angeles, California, USA

Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515
The ideal drive beam current profile for the plasma wakefield accelerator (PWFA) has been predicted by 1D and 2D simulations to be characterized by a triangular ramp that rises linearly from head to tail, followed by a sharp drop. A technique for generating such bunches experimentally was recently demonstrated. We present here an adaptation of this scheme to generate ramped bunches using the 23 GeV electron beam produced in the first two-thirds of the SLAC linac, and discuss plans to implement this scheme for high transformer ratio demonstration experiments at the FACET plasma wakefield accelerator facility.

MOP101

Numerical Study of Self and Controlled Injection in 3-Dimensional Laser-Driven Wakefields

286

A.W. Davidson, R. Fenseca, C. Joshi, W. Lu, J.L. Martins, W.B. Mori, L.O. Silva
UCLA, Los Angeles, California, USA

Funding: DOE and NSF
In plasma based accelerators (LWFA and PWFA), the methods of injecting high quality electron bunches into the accelerating wakefield is of utmost importance for various applications. Understanding how injection occurs in both self and controlled scenarios is therefore important. To simplify this understanding, we start from single particle motion in an arbitrary traveling wave wakefields, an electromagnetic structure with a fixed phase velocity(e.g., wakefields driven by non-evolving drivers), and obtain the general conditions for trapping to occur. We then compare this condition with high fidelity 3D PIC simulations through advanced particle and field tracking diagnostics. Numerous numerical convergence tests were performed to ensure the correctness of the simulations. The agreement between theory and simulations helps to clarify the role played by driver evolution on injection, and a physical picture of injection first proposed in * is confirmed through simulations. Several ideas, including ionization assisted injection, for achieving high quality controlled injection were also explored and some simulation results relevant to current and future experiments will be presented.
*W. Lu et al., PRSTAB 10, 061301, 2007

TUOBN4

Plasma Wakefield Experiments at FACET

715

M.J. Hogan, R.J. England, J.T. Frederico, C. Hast, S.Z. Li, M.D. Litos, D.R. Walz
SLAC, Menlo Park, California, USA
W. An, C.E. Clayton, C. Joshi, W. Lu, K.A. Marsh, W.B. Mori, S. Tochitsky
UCLA, Los Angeles, California, USA
P. Muggli, S.F. Pinkerton, Y. Shi
USC, Los Angeles, California, USA

Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515.
FACET, the Facility for Advanced Accelerator and Experimental Tests, is a new facility being constructed in sector 20 of the SLAC linac primarily to study beam driven plasma wakefield acceleration beginning in summer 2011. The nominal FACET parameters are 23GeV, 3nC electron bunches compressed to ~20μm long and focused to ~10μm wide. The intense fields of the FACET bunches will be used to field ionize neutral lithium or cesium vapor produced in a heat pipe oven. Previous experiments at SLAC demonstrated 50GeV/m gradients in an 85cm field ionized lithium plasma where the interaction distance was limited by head erosion. Simulations indicate the lower ionization potential of cesium will decrease the rate of head erosion and increase single stage performance. The initial experimental program will compare the performance of lithium and cesium plasma sources with single and double bunches. Later experiments will investigate improved performance with a pre-ionized cesium plasma. The status of the experiments and expected performance are reviewed.

Slides TUOBN4 [13.080 MB]

TUOBN5

A Proposed Experimental Test of Proton-Driven Plasma Wakefield Acceleration Based on CERN SPS

718

G.X. Xia, A. Caldwell
MPI-P, München, Germany
W. An, C. Joshi, W. Lu, W.B. Mori
UCLA, Los Angeles, California, USA
R.W. Assmann, F. Zimmermann
CERN, Geneva, Switzerland
R.A. Fonseca, N.C. Lopes, J. Vieira
Instituto Superior Tecnico, Lisbon, Portugal
C. Huang
LANL, Los Alamos, New Mexico, USA
K.V. Lotov
BINP SB RAS, Novosibirsk, Russia
P. Muggli
USC, Los Angeles, California, USA
A.M. Pukhov
HHUD, Dusseldorf, Germany
L.O. Silva
IPFN, Lisbon, Portugal

Proton-driven plasma wakefield acceleration (PDPWA) has been proposed as an approach to accelerate electron beam to TeV energy regime in a single passage of plasma channel. An experimental test is recently proposed to demonstrate the capability of PDPWA by using proton beams from the CERN SPS. The preparation of experiment is introduced. The particle-in-cell simulation results based on realistic beam parameters are presented.

Slides TUOBN5 [2.208 MB]

TUOBN1

Laser Wakefield Acceleration Beyond 1 GeV using Ionization Induced Injection

707

K.A. Marsh, C.E. Clayton, C. Joshi, N. Lemos, W. Lu, W.B. Mori, A.E. Pak
UCLA, Los Angeles, California, USA
F. Albert, T. Doeppner, C. Filip, D.H. Froula, S.H. Glenzer, B.B. Pollock, D. Price, J.E. Ralph
LLNL, Livermore, California, USA
R.A. Fonseca, S.F. Martins
Instituto Superior Tecnico, Lisbon, Portugal
L.O. Silva
IPFN, Lisbon, Portugal

Funding: Supported by DOE Grants No. DE-AC52-07NA27344, DE-FG03-92ER40727, DE-FG02-92ER40727, DE-FC02-07ER41500, DE-FG52-09NA29552, NSF Grants No. PHY-0936266, PHY-0904039 and FCT, Por., No. SFRH/BD/35749/2007
A series of laser wakefield accelerator experiments leading to electron energy exceeding 1 GeV are described. Theoretical concepts and experimental methods developed while conducting experiments using the 10 TW Ti:Sapphire laser at UCLA were implemented and transferred successfully to the 100 TW Calisto Laser System at the Jupiter Laser Facility at LLNL. To reach electron energies greater than 1 GeV with current laser systems, it is necessary to inject and trap electrons into the wake and to guide the laser for more than 1 cm of plasma. Using the 10 TW laser, the physics of self-guiding and the limitations in regards to pump depletion over cm-scale plasmas were demonstrated. Furthermore, a novel injection mechanism was explored which allows injection by ionization at conditions necessary for generating electron energies greater than a GeV. The 10 TW results were followed by self-guiding at the 100 TW scale over cm plasma lengths. The energy of the self-injected electrons, at 3x10¹⁸ cm^-3 plasma density, was limited by dephasing to 720 MeV. Implementation of ionization injection allowed extending the acceleration well beyond a centimeter and 1.4 GeV electrons were measured.

Slides TUOBN1 [2.488 MB]

Paper	Title	Page
MOP016	Preliminary Simulations of Plasma Wakefield Accelerator Experiments at FACET	136
	W. An, C. Joshi, W. Lu, W.B. Mori UCLA, Los Angeles, California, USA M.J. Hogan SLAC, Menlo Park, California, USA C. Huang LANL, Los Alamos, New Mexico, USA
	Funding: This work is supported by USDoE under DE-FC02-07ER41500, DE-FG02-92ER40727 and NSF under NSF PHY-0904039, PHY-0936266. Recent experiments on former facility FFTB at SLAC has demonstrated that a single electron beam driven Plasma Wakefield Accelerator (PWFA) can be produced with an accelerating gradient of 52 GeV/m over a meter-long scale. If another electron bunch is properly loaded into such a wakefield, it will obtain a high energy gain in a short distance as well as a small energy spread. Such PWFA experiment with two bunches will be performed in FACET, which is a new facility at SLAC. Simulation results show that with possible beam parameters in FACET the first electron bunch (with less current than that in the FFTB experiment) can still produce a meter-long plasma column with a density of 5x10¹⁶ cm^-3 via field ionization when we use a gas with a lower ionization energy. The second electron bunch can have a 10 GeV energy gain with a very narrow energy spread. If a pre-ionized plasma is used instead of the neutral gas, the energy gain of the second bunch can be enhanced to 30 GeV. I. Blumenfeld et al., Nature 445, 741 (2007). ** M. J.Hogan, et al.,NewJ. Phys.12, 055030(2010).

MOP088	A High Transformer Ratio Plasma Wakefield Accelerator Scheme for FACET	265
	R.J. England, J.T. Frederico, M.J. Hogan SLAC, Menlo Park, California, USA W. An, C. Joshi, W. Lu, W.B. Mori UCLA, Los Angeles, California, USA P. Muggli USC, Los Angeles, California, USA
	Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515 The ideal drive beam current profile for the plasma wakefield accelerator (PWFA) has been predicted by 1D and 2D simulations to be characterized by a triangular ramp that rises linearly from head to tail, followed by a sharp drop. A technique for generating such bunches experimentally was recently demonstrated. We present here an adaptation of this scheme to generate ramped bunches using the 23 GeV electron beam produced in the first two-thirds of the SLAC linac, and discuss plans to implement this scheme for high transformer ratio demonstration experiments at the FACET plasma wakefield accelerator facility.

MOP101	Numerical Study of Self and Controlled Injection in 3-Dimensional Laser-Driven Wakefields	286
	A.W. Davidson, R. Fenseca, C. Joshi, W. Lu, J.L. Martins, W.B. Mori, L.O. Silva UCLA, Los Angeles, California, USA
	Funding: DOE and NSF In plasma based accelerators (LWFA and PWFA), the methods of injecting high quality electron bunches into the accelerating wakefield is of utmost importance for various applications. Understanding how injection occurs in both self and controlled scenarios is therefore important. To simplify this understanding, we start from single particle motion in an arbitrary traveling wave wakefields, an electromagnetic structure with a fixed phase velocity(e.g., wakefields driven by non-evolving drivers), and obtain the general conditions for trapping to occur. We then compare this condition with high fidelity 3D PIC simulations through advanced particle and field tracking diagnostics. Numerous numerical convergence tests were performed to ensure the correctness of the simulations. The agreement between theory and simulations helps to clarify the role played by driver evolution on injection, and a physical picture of injection first proposed in * is confirmed through simulations. Several ideas, including ionization assisted injection, for achieving high quality controlled injection were also explored and some simulation results relevant to current and future experiments will be presented. *W. Lu et al., PRSTAB 10, 061301, 2007

TUOBN4	Plasma Wakefield Experiments at FACET	715
	M.J. Hogan, R.J. England, J.T. Frederico, C. Hast, S.Z. Li, M.D. Litos, D.R. Walz SLAC, Menlo Park, California, USA W. An, C.E. Clayton, C. Joshi, W. Lu, K.A. Marsh, W.B. Mori, S. Tochitsky UCLA, Los Angeles, California, USA P. Muggli, S.F. Pinkerton, Y. Shi USC, Los Angeles, California, USA
	Funding: Work supported by the U.S. Department of Energy under contract number DE-AC02-76SF00515. FACET, the Facility for Advanced Accelerator and Experimental Tests, is a new facility being constructed in sector 20 of the SLAC linac primarily to study beam driven plasma wakefield acceleration beginning in summer 2011. The nominal FACET parameters are 23GeV, 3nC electron bunches compressed to ~20μm long and focused to ~10μm wide. The intense fields of the FACET bunches will be used to field ionize neutral lithium or cesium vapor produced in a heat pipe oven. Previous experiments at SLAC demonstrated 50GeV/m gradients in an 85cm field ionized lithium plasma where the interaction distance was limited by head erosion. Simulations indicate the lower ionization potential of cesium will decrease the rate of head erosion and increase single stage performance. The initial experimental program will compare the performance of lithium and cesium plasma sources with single and double bunches. Later experiments will investigate improved performance with a pre-ionized cesium plasma. The status of the experiments and expected performance are reviewed.
	Slides TUOBN4 [13.080 MB]

TUOBN5	A Proposed Experimental Test of Proton-Driven Plasma Wakefield Acceleration Based on CERN SPS	718
	G.X. Xia, A. Caldwell MPI-P, München, Germany W. An, C. Joshi, W. Lu, W.B. Mori UCLA, Los Angeles, California, USA R.W. Assmann, F. Zimmermann CERN, Geneva, Switzerland R.A. Fonseca, N.C. Lopes, J. Vieira Instituto Superior Tecnico, Lisbon, Portugal C. Huang LANL, Los Alamos, New Mexico, USA K.V. Lotov BINP SB RAS, Novosibirsk, Russia P. Muggli USC, Los Angeles, California, USA A.M. Pukhov HHUD, Dusseldorf, Germany L.O. Silva IPFN, Lisbon, Portugal
	Proton-driven plasma wakefield acceleration (PDPWA) has been proposed as an approach to accelerate electron beam to TeV energy regime in a single passage of plasma channel. An experimental test is recently proposed to demonstrate the capability of PDPWA by using proton beams from the CERN SPS. The preparation of experiment is introduced. The particle-in-cell simulation results based on realistic beam parameters are presented.
	Slides TUOBN5 [2.208 MB]

TUOBN1	Laser Wakefield Acceleration Beyond 1 GeV using Ionization Induced Injection	707
	K.A. Marsh, C.E. Clayton, C. Joshi, N. Lemos, W. Lu, W.B. Mori, A.E. Pak UCLA, Los Angeles, California, USA F. Albert, T. Doeppner, C. Filip, D.H. Froula, S.H. Glenzer, B.B. Pollock, D. Price, J.E. Ralph LLNL, Livermore, California, USA R.A. Fonseca, S.F. Martins Instituto Superior Tecnico, Lisbon, Portugal L.O. Silva IPFN, Lisbon, Portugal
	Funding: Supported by DOE Grants No. DE-AC52-07NA27344, DE-FG03-92ER40727, DE-FG02-92ER40727, DE-FC02-07ER41500, DE-FG52-09NA29552, NSF Grants No. PHY-0936266, PHY-0904039 and FCT, Por., No. SFRH/BD/35749/2007 A series of laser wakefield accelerator experiments leading to electron energy exceeding 1 GeV are described. Theoretical concepts and experimental methods developed while conducting experiments using the 10 TW Ti:Sapphire laser at UCLA were implemented and transferred successfully to the 100 TW Calisto Laser System at the Jupiter Laser Facility at LLNL. To reach electron energies greater than 1 GeV with current laser systems, it is necessary to inject and trap electrons into the wake and to guide the laser for more than 1 cm of plasma. Using the 10 TW laser, the physics of self-guiding and the limitations in regards to pump depletion over cm-scale plasmas were demonstrated. Furthermore, a novel injection mechanism was explored which allows injection by ionization at conditions necessary for generating electron energies greater than a GeV. The 10 TW results were followed by self-guiding at the 100 TW scale over cm plasma lengths. The energy of the self-injected electrons, at 3x10¹⁸ cm^-3 plasma density, was limited by dephasing to 720 MeV. Implementation of ionization injection allowed extending the acceleration well beyond a centimeter and 1.4 GeV electrons were measured.
	Slides TUOBN1 [2.488 MB]