GINGER Results for the NEW LCLS Undulator Configuration William M. Fawley Lawrence Berkeley National Laboratory Presented to LCLS Undulator Parameter Workshop.

Slides:

Advertisements

Similar presentations

Schemes for generation of attosecond pulses in X-ray FELs E.L. Saldin, E.A. Schneidmiller, M.V. Yurkov The potential for the development of XFEL beyond.

Advertisements

Two-Color I-SASE A.Marinelli, J. Wu, C. Pellegrini LCLS2 Meeting SLAC 1/30/2013.

Workshop Issues Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center Diagnostics.

1 Optimal focusing lattice for XFEL undulators: Numerical simulations Vitali Khachatryan, Artur Tarloyan CANDLE, DESY/MPY

Tessa Charles Australian Synchrotron / Monash University 1 Bunch Compression Schemes for X-band FELs.

1 Bates XFEL Linac and Bunch Compressor Dynamics 1. Linac Layout and General Beam Parameter 2. Bunch Compressor –System Details (RF, Magnet Chicane) –Linear.

E. Schneidmiller and M. Yurkov (SASE & MCP) C. Behrens, W. Decking, H. Delsim, T. Limberg, R. Kammering (rf & LOLA) N. Guerassimova and R. Treusch (PGM.

Hard X-ray FELs (Overview) Zhirong Huang March 6, 2012 FLS2012 Workshop, Jefferson Lab.

Beam-Based Alignment with New Parameters Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator.

P. Emma LCLS FAC 12 Oct Comments from LCLS FAC Meeting (April 2004): J. Roßbach:“How do you detect weak FEL power when the.

P. Emma FAC Meeting 7 Apr Low-Charge LCLS Operating Point Including FEL Simulations P. Emma 1, W. Fawley 2, Z. Huang 1, C.

October 12, 2006 Heinz-Dieter Nuhn, SLAC / LCLS Undulator Good Field Region and Tuning Strategy 1 Undulator Good Field Region and.

Performance Analysis Using Genesis 1.3 Sven Reiche LCLS Undulator Parameter Workshop Argonne National Laboratory 10/24/03.

1 Daniel Ratner 1 Gain Length and Taper August, 2009 FEL Gain length and Taper Measurements at LCLS D. Ratner A. Brachmann, F.J.

Wm. Fawley LCLS FAC April Sven Reiche Effects of AC Resistive-Wall Wake Upon LCLS SASE Performance: Numerical.

Z. Huang LCLS FAC April Effect of AC RW Wake on SASE - Analytical Treatment Z. Huang, G. Stupakov see SLAC-PUB-10863, to.

Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center LCLS Undulator Alignment.

45 th ICFA Beam Dynamic Workshop June 8–12, 2009, Cornell University, Ithaca New York Recent Studies with ECLOUD Jim Crittenden Cornell Laboratory for.

Overview of Proposed Parameter Changes Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator.

Spontaneous Radiation at LCLS Sven Reiche UCLA - 09/22/04 Sven Reiche UCLA - 09/22/04.

Undulator Specifications Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center.

FEL simulation code FAST Free-Electron Laser at the TESLA Test Facility Generic name FAST stands for a set of codes for ``full physics'' analysis of FEL.

TTF2 Start-to-End Simulations Jean-Paul Carneiro DESY Hamburg TESLA COLLABORATION MEETING DESY Zeuthen, 22 Jan 2004.

S2E in LCLS Linac M. Borland, Lyncean Technologies, P. Emma, C. Limborg, SLAC.

Soft X-ray Self-Seeding in LCLS-II J. Wu Jan. 13, 2010.

Undulator parameters choice/wish based on a simplified XFEL cost model Jürgen Pfingstner 29 st of July 2015.

Two Longitudinal Space Charge Amplifiers and a Poisson Solver for Periodic Micro Structures Longitudinal Space Charge Amplifier 1: Longitudinal Space Charge.

Simulation of Microbunching Instability in LCLS with Laser-Heater Linac Coherent Light Source Stanford Synchrotron Radiation Laboratory.

B. FaatzS2E workshop, August 18-22, XFEL simulations with GENESIS Outline: Undulator layout (real/simulated) Matching Genesis.

Beam Dynamics and FEL Simulations for FLASH Igor Zagorodnov and Martin Dohlus Beam Dynamics Meeting, DESY.

J. Wu In collaboration with Y. Jiao, W.M. Fawley, J. Frisch, Z. Huang, H.-D. Nuhn, C. Pellegrini, S. Reiche (PSI), Y. Cai, A.W. Chao, Y. Ding, X. Huang,

Max Cornacchia, SLAC LCLS Project Overview BESAC, Feb , 2001 LCLS Project Overview What is the LCLS ? Transition from 3 rd generation light sources.

X-Ray FEL Simulation: Beam Modeling William M. Fawley Center For Beam Physics Lawrence Berkeley National Laboratory ICFA 2003 Workshop.

External Seeding Approaches: S2E studies for LCLS-II Gregg Penn, LBNL CBP Erik Hemsing, SLAC August 7, 2014.

Basic Energy Sciences Advisory Committee MeetingLCLS February 26, 2001 J. Hastings Brookhaven National Laboratory LCLS Scientific Program X-Ray Laser Physics:

LCLS-II Delta Undulator Study for SXR Polarization Control

Harmonic lasing in the LCLS-II (a work in progress…) G. Marcus, et al. 03/11/2014.

NON-WIGGLER-AVERAGED START-TO-END SIMULATIONS OF HIGH-GAIN FREE- ELECTRON LASERS H.P. Freund Science Applications International Corp. McLean, Virginia.

‘S2E’ Study of Linac for TESLA XFEL P. Emma SLAC  Tracking  Comparison to LCLS  Re-optimization  Tolerances  Jitter  CSR Effects.

Design Considerations of table-top FELs laser-plasma accelerators principal possibility of table-top FELs possible VUV and X-ray scenarios new experimental.

S2E (start-to-end) Simulations at DESY T. Limberg TESLA Collaboration Meeting in Frascati, May 2003.

FEL Simulations: Undulator Modeling Sven Reiche Start-end Workshop DESY-Zeuthen 08/20/03.

Genesis /ALICE Benchmarking Igor Zagorodnov Beam Dynamics Group Meeting

J. Wu March 06, 2012 ICFA-FLS 2012 Workshop Jefferson Lab, Newport News, VA Tolerances for Seeded Free Electron Lasers FEL and Beam Phys. Dept. (ARD/SLAC),

E. Schneidmiller and M. Yurkov FEL Seminar, DESY April 26, 2016 Reverse undulator tapering for polarization control at X-ray FELs.

Harmonic lasing in the LCLSII SXR beamline G. Marcus, Y. Ding, Z. Huang 11/21/2013.

Simulations of X-ray production for different undulator options 19 th of March 2015 Juergen Pfingstner.

LCLS-II options: CuRF → SXR, VPU, HXR harmonics G. Marcus 5/13/2015.

Seeding in the presence of microbunching

Beam dynamics for an X-band LINAC driving a 1 keV FEL

Challenges in Simulating EEHG

Undulator Tolerances for LCLS-II using SCUs

Yuhui Li How to edit the title slide

Where Do We Stand With Start-End Simulations

Review of Application to SASE-FELs

F. Villa Laboratori Nazionali di Frascati - LNF On behalf of Sparc_lab

Laser assisted emittance exchange to reduce the X-ray FEL size

G. Marcus, Y. Ding, J. Qiang 02/06/2017

TW FEL “Death-Ray“ Studies

Challenges in Simulating EEHG

Injector Topics for Discussion

Z. Huang LCLS Lehman Review May 14, 2009

Two-bunch self-seeding for narrow-bandwidth hard x-ray FELs

XFEL Simulations with SIMPLEX and GENESIS (Some preliminary results)

SASE FEL PULSE DURATION ANALYSIS FROM SPECTRAL CORRELATION FUNCTION

Gain Computation Sven Reiche, UCLA April 24, 2002

LCLS FEL Parameters Heinz-Dieter Nuhn, SLAC / SSRL April 23, 2002

Achieving Required Peak Spectral Brightness Relative Performance for Four Undulator Technologies Neil Thompson WP5 – 20/03/19.

Enhanced Self-Amplified Spontaneous Emission

Vitali Khachatryan, Arthur Tarloyan, Vahe Sahakyan, V. Tsakanov

Presentation transcript:

GINGER Results for the NEW LCLS Undulator Configuration William M. Fawley Lawrence Berkeley National Laboratory Presented to LCLS Undulator Parameter Workshop 24 October 2003

Outline of GINGER Study ● First determine best K for peak gain for monochromatic cases at =1.5, 0.15, and 0.1 nm ● Examine taper performance for SASE runs at 0.15-nm, GeV base case ● SASE performance at 0.1 nm with E=14.04 GeV ● Study of taper sensitivity for 1.5 nm case ● No wake effects examined --- need ELEGANT time- dependent beam parameters ● Some additional S2E SASE results for ICFA03 study – envelope reconstruction looks surprisingly good

Study Parameters/Bottom-Line Results  F  L  L gain Z sat P sat P max GeV4.27E GW7 GW E GW48 GW E GW84 GW SASE results; best taper for 0.15, 1.5 nm

Effects of Linear K Taper on LCLS SASE Output Power at =0.15nm ● GINGER SASE runs ● New drift space/undulator configuration ● Quadrupole strengths & Twiss parameters from H.-D. Nuhn ● Taper begins at z=75 m; simple linear decrease with z (including drift spaces) ● Max power obtained around 0.3 to 0.4% taper; excessively large tapers appear to lead to rapid debunching with z and thus reduced gain

Bunching and Inverse Bandwidth vs Z: 0.15-nm LCLS GINGER SASE runs for new LCLS drift space/undulator configuration

SASE Results at 0.1-nm Wavelength No taper “1 st ” saturation at ~110 m Output power ~6 GW No obvious anomalies --- but little margin for any beam degradation

1.5-nm Taper Results 1.5 nm option is a “cake-walk” for LCLS parameters “1 st ” saturation at ~30 m; simple linear tapering begins at z=25 m Tapering increases power over 6-fold to > 80 GW 60 m of undulator gives most of output power More “intelligent” tapers probably could increase power to >100 GW

New GINGER Results for ICFA03 “2nd-Order” Simulation Study Extension of results for ICFA03-Zeuthen S2E study for LCLS Full SASE simulation extended over full beam head region - results low-pass filtered in time (original res- olution = 12 attoseconds) In regions where 5D distribution is “simple”, full SASE and envelope reconstruction agree surprisingly well Similar runs underway for wake case (CSR but no wake fields) Output P for SASE; peak P(z) for no slippage cases

Where might we go from here? ● Need ELEGANT runs with/without CSR effects to produce time-dependent 5D distributions at undulator entrance ● Examine temporal sensitivity of P(z) to taper ● Examine “ “ to wakes ● One optimization criterion is maximizing product of power times the inverse bandwidth (at least for experiments in which monochromatization will be done) ● See if results with taper are more sensitive to undulator errors, beam offset/pointing errors – Perhaps greater sensitivity to phase jitter but does deeper ponderomotive well help? ● Develop taper algorithm for undulator with drift spaces & consider effects of “spiky” SASE P(t)