Round-to-Flat Beam Transformation and Applications

Slides:

Advertisements

Similar presentations

High Brightness Electron Source Lab.

Advertisements

Abstract PHOTOINJECTOR PRODUCTION OF A FLAT ELECTRON BEAM E. Thrane, Univ. of Michigan, C. Bohn, Northern Illinois University (NIU) and FNAL, N. Barov,

Radiation Physics | ELBE | SRF Photo Injector for Electron- Laser Interaction LA 3 NET conference: Laser applications at accelerators, Mallorca,

J. Rudolph, Helmholtz-Zentrum Berlin EuCARD 2nd ANNUAL MEETING Slice emittance measurements at the ELBE superconducting RF photoinjector.

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

1 ILC Bunch compressor Damping ring ILC Summer School August Eun-San Kim KNU.

Final Cooling For a High-luminosity High- Energy Lepton Collider David Neuffer Fermilab Don Summers, Terry Hart (University of Mississippi) H.Sayed (BNL)

Flat-Beams and Emittance Exchange P. Emma 1, Z. Huang 1, K.-J. Kim 2, Ph. Piot 3 June 23, 2006 Flat-beam gun can produce >100:1 emittance ratio Smaller.

F Specifications for the dark current kicker for the NML test facility at Fermilab S. Nagaitsev, M. Church, P. Piot, C.Y. Tan, J. Steimel Fermilab May.

High-current ERL-based electron cooling system for RHIC Ilan Ben-Zvi Collider-Accelerator Department Brookhaven National Laboratory.

Generation and Characterization of Magnetized Bunched Electron Beam from DC Photogun for MEIC Cooler Laboratory Directed Research and Development (LDRD)

Magnetic Compression of High Brightness Beams: Survey of Experimental Results Scott G. Anderson ICFA Sardinia July 2002.

ICAR:U of C Activities Kwang-Je Kim September 3, 2003.

Northern Illinois Center for Accelerator and Detector Development Generation and Dynamics of Magnetized Beams for High-Energy Electron Cooling * Philippe.

Generation and Characterization of Magnetized Bunched Electron Beam from DC Photogun for MEIC Cooler Laboratory Directed Research and Development (LDRD)

Modelling of the ALICE Injector Julian McKenzie ASTeC STFC Daresbury Laboratory IOP Particle Accelerators and Beams Group Status and Challenges of Simulation.

Photocathode 1.5 (1, 3.5) cell superconducting RF gun with electric and magnetic RF focusing Transversal normalized rms emittance (no thermal emittance)

Steve LidiaICFA Workshop, Chia LagunaJuly, 2002 Flat Beam Photoinjectors for Ultrafast Synchrotron Radiation Sources Steve Lidia Lawrence Berkeley National.

Low Emittance RF Gun Developments for PAL-XFEL

~ gun3.9 GHz cavity Bunch compressor 3 ILC cryomodules 45 deg. spectro injector main linac user area disp. area transport line Overview of.

IRPSS: A Green’s Function Approach to Modeling Photoinjectors Mark Hess Indiana University Cyclotron Facility & Physics Department *Supported by NSF and.

I.V. Bazarov, ERL advisory mtg, Sept 2012 CLASSE Cornell University CHESS & ERL Cornell Laboratory for Accelerator-based ScienceS and Education (CLASSE)

High Current Electron Source for Cooling Jefferson Lab Internal MEIC Accelerator Design Review January 17, 2014 Riad Suleiman.

Recent Experiments at PITZ ICFA Future Light Sources Sub-Panel Mini Workshop on Start-to-End Simulations of X-RAY FELs August 18-22, 2003 at DESY-Zeuthen,

BROOKHAVEN SCIENCE ASSOCIATES Electron Cooling at RHIC Enhancement of Average Luminosity for Heavy Ion Collisions at RHIC R&D Plans and Simulation Studies.

Field enhancement coefficient  determination methods: dark current and Schottky enabled photo-emissions Wei Gai ANL CERN RF Breakdown Meeting May 6, 2010.

Emittance Partitioning in Photoinjectors Bruce Carlsten, Robert Ryne, Kip Bishofberger, Steven Russell, and Nikolai Yampolsky Los Alamos National Laboratory.

LDRD: Magnetized Source JLEIC Meeting November 20, 2015 Riad Suleiman and Matt Poelker.

R.Chehab/ R&D on positron sources for ILC/ Beijing, GENERATION AND TRANSPORT OF A POSITRON BEAM CREATED BY PHOTONS FROM COMPTON PROCESS R.CHEHAB.

Christopher Gerth DL/RAL Joint Workshop 28-29/4/04 Modelling of the ERLP injector system Christopher Gerth ASTeC, Daresbury Laboratory.

Velocity bunching from S-band photoinjectors Julian McKenzie 1 st July 2011 Ultra Bright Electron Sources Workshop Cockcroft Institute STFC Daresbury Laboratory,

P I T Z Photo Injector Test Facility Zeuthen Design consideration of the RF deflector to optimize the photo injector at PITZ S.Korepanov.

July LEReC Review July 2014 Low Energy RHIC electron Cooling Jorg Kewisch, Dmitri Kayran Electron Beam Transport and System specifications.

Round-to-Flat Beam Transformation and Applications Yine Sun Accelerator System Division Advanced Photon Source Argonne Nation Lab. International Workshop.

Accelerator Laboratory of Tsinghua University Generation, measurement and applications of high brightness electron beam Dao Xiang Apr-17, /37.

Awake electron beam requirements ParameterBaseline Phase 2Range to check Beam Energy16 MeV MeV Energy spread (  ) 0.5 %< 0.5 % ? Bunch Length (

1 Short Electron Pulses from RF Photoinjectors Massimo Ferrario INFN - LNF.

Development of High Current Bunched Magnetized Electron DC Photogun MEIC Collaboration Meeting Fall 2015 October 5 – 7, 2015 Riad Suleiman and Matt Poelker.

Injector Requirements Linac Coherent Light Source Stanford Linear Accelerator Center Technical Review, March 1st, 2004 Cécile.

Final Cooling Options For a High- Luminosity High-Energy Lepton Collider David Neuffer FNAL Don Summers, T. Hart, … U. Miss.

J.Maxson, D. Cesar, P. Musumeci UCLA

ELI PHOTOINJECTOR PARAMETERS: PRELIMINARY ANALYSIS AND SIMULATIONS C. RONSIVALLE.

J. C. T. Thangaraj Fermi National Accelerator Laboratory, Batavia, Illinois 1 Experimental studies on an emittance exchange beamline at the A0 photoinjector.

CLIC DB injector facility, photo-injector option studies LCWS, Granada, September 26 th -30 th,2011Steffen Döbert, BE-RF  CLIC DB injector  Thermionic.

10/18/2012 Yine Sun, APC seminar Electron Beam Current-Profile Shaping Via Transverse-to-Longitudinal Phase-Space Exchange Yine Sun Fermi National Accelerator.

Preservation of Magnetized Beam Quality in a Non-Isochronous Bend

Northern Illinois Center for Accelerator and Detector Development

Beam dynamics simulation with 3D Field map for FCC RF gun

PIs: Riad Suleiman and Matt Poelker

Superconducting RF Photoelectron Source -

BUNCH LENGTH MEASUREMENT SYSTEM FOR 500 KV PHOTOCATHODE DC GUN AT IHEP

Tunable Electron Bunch Train Generation at Tsinghua University

Experimental Overview

Magnetized Bunched Electron Beam from DC High Voltage Photogun

Status of the VEPP-2000 Collider Project at Novosibirsk

The Cornell High Brightness Injector

X-Ray SASE FEL e+e- Linear Colliders. X-Ray SASE FEL e+e- Linear Colliders.

Beam Dynamics in a Spilt SRF-Gun

Magnetized Electron Beam for Ion Cooling at JLEIC

Polarized Positrons at Jefferson Lab

Production of Magnetized Electron Beam from a DC High Voltage Photogun

R. Suleiman and M. Poelker October 12, 2018

R. Suleiman and M. Poelker September 29, 2016

PIs: Riad Suleiman and Matt Poelker

Superconducting High Brightness RF Photoinjector Design

PIs: Riad Suleiman and Matt Poelker

Minimized emittance for high charge with multi cell superconducting guns and solenoidal focusing D. Lipka, BESSY.

Injector for the Electron Cooler

Update on ERL Cooler Design Studies

Generation of Magnetized Bunched Electron Beam for MEIC Cooler

Presentation transcript:

Round-to-Flat Beam Transformation and Applications Yine Sun Accelerator System Division Advanced Photon Source Argonne Nation Lab. International Workshop on Beam Cooling and Related Topics Jefferson Lab, Newport News, Virginia, USA. Sept. 28 – Oct. 2, 2015

Outline Introduction; Generation of magnetized electron beams from a high-brightness photo-injector; Parameterization and measurements of magnetized beam; Experimental demonstration of the removal of the angular momentum and generation of flat beam: theory; measurement method; data analysis and results; comparison with simulations. Cool'15 10/1/2015 Yine Sun

Beam dynamics: three different regimes Magnetized (canonical angular momentum) emittance space charge where envelope equation in a drift: is the generalized perveance. Yine Sun, http://lss.fnal.gov/archive/thesis/2000/fermilab-thesis-2005-17.pdf Cool'15 10/1/2015 Yine Sun

Applications of magnetized beam and flat beam electron cooling for heavy ion: cooling interaction Time flat beam for linear e+e- collider: reduce beamstrahlung Cool'15 10/1/2015 Yine Sun

Applications of magnetized beam and flat beam Flat beam for light sources Radiators of planar geometry such in the Radiabeam-APS THz generation experiment carried out at the Injector Test Stand in APS/ANL. Cool'15 10/1/2015 Yine Sun

Generation of magnetized electron beam From a high-brightness RF photo-injector On the cathode: FNPL 1.625-cell RF gun, 1.3 GHz Cool'15 10/1/2015 Yine Sun

canonical → mechanical angular momentum Solenoidal end field applies a torque to the beam. When Bz=0, canonical = mechanical angular momentum solenoids r z Cool'15 10/1/2015 Yine Sun

round-to-flat transformer Fermilab/NICADD Photoinjector Lab. (FNPL) 4 MeV 16 MeV rf gun TESLA superconducting cavity round-to-flat transformer (skew quadrupoles) Cool'15 10/1/2015 Yine Sun

Measurement of canonical angular momentum on the photocathode B0: B-field on cathode σc :RMS beam size on cathode Cool'15 10/1/2015 Yine Sun

Measurement of mechanical angular momentum in a drift space Y.-E Sun et al. Phys. Rev. ST Accel. Beams 7, 123501 (2004). Cool'15 10/1/2015 Yine Sun

Measurement of rotation angle rotation of the slit image slit image Cool'15 10/1/2015 Yine Sun

Measurement of mechanical angular momentum vs B-field Cool'15 10/1/2015 Yine Sun

Demonstration of conservation of canonical angular momentum as a function of magnetic field on cathode weighted least-squares linear fit: y=(0.98±0.03)x Cool'15 10/1/2015 Yine Sun

Parametric dependencies of angular momentum Angular momentum versus beam longitudinal position z bunch charge beam size on the cathode Cool'15 10/1/2015 Yine Sun

From magnetized beam to flat beam Ya From magnetized beam to flat beam Ya. Derbenev, “Adapting Optics for High Energy Electron Cooling”, University of Michigan, UM-HE-98-04, Feb. 1998. Round photocathode immersed in solenoid field flat beam skew-quads See also: “Matched Electron Cooling”, Ya. Derbenev, WEWAUD02, COOL’15; A. Burov, S. Nagaitsev and Ya. Derbenev, Phys. Rev. E 66, 016503 (2002). Cool'15 10/1/2015 Yine Sun

Round-to-flat beam transformation using skew quadrupoles Flat beam: large transverse emittance ratio, zero average angular momentum. d2 d3 q1 q2 q3 Two sets of solutions: (D. Edwards) Cool'15 10/1/2015 Yine Sun

Round-to-flat beam transformation General form of a round beam at beam waist location (K.-J. Kim) uncorrelated emittance “normalized” canonical angular momentum Transfer matrix of the round-to-flat beam transformer Flat beam emittances given by: e.g. L=20 mm mrad, εu=1 mm mrad ε+=47 mm mrad; ε-=0.02 mm mrad Cool'15 10/1/2015 Yine Sun

Position and velocity snap shots at the entrance/exit of the transformer Round beam flat beam Cool'15 10/1/2015 Yine Sun

Beam evolution through the transformer for the first solution 10 mm Right before 1st quad Right after 1st quad Right before 2nd Quad Right after 2nd Quad Right before 3rd quad Right after 3rd quad Cool'15 10/1/2015 Yine Sun

Removal of angular momentum and generating a flat beam experiment simulation Cool'15 10/1/2015 Yine Sun

Flat beam measurements: beam images Solenoid setting: main=195A, buck=0A, secondary=75A σ = 0.97 mm, σt = 3 ps E = 15.86 MeV Q = 0.51 ± 0.17 nC X5 X3 X4 X6 X8 X7 Cool'15 10/1/2015 Yine Sun

Flat beam experiment: emittance measurements X8 Hslit X8 Vslit Solenoid setting: main=190A, buck=0A, secondary=75A Laser σ = 0.76 mm σt = 3 ps E = 15.8 MeV Q = 0.50 ± 0.05 nC X7 X8 Vslit X8 Hslit Cool'15 10/1/2015 Yine Sun

ASTRA Simulation with experimental conditions Cool'15 10/1/2015 Yine Sun

Experimental results compared with numerical simulations (0.5 nC) P. Piot, Y.-E Sun, K.-J. Kim, Phys. Rev. ST Accel. Beams 9, 031001 (2006). Cool'15 10/1/2015 Yine Sun

Summary Magnetized photo-injector electron beams are generated and dependences on various parameters are studied. The angular- momentum-dominated electron beams are characterized; The magnetized electron beam is converted into a flat electron beam using a skew-quadrupole channel; The emittances of the flat beam are measured and at 0.5 nC, normalized emittance of 0.4 mm mrad was measured; emittance ratio of 100 was achieved. Cool'15 10/1/2015 Yine Sun