I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November 2004 1 CHESS / LEPP ERL DC Gun Injector.

Slides:

Advertisements

Similar presentations

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

Advertisements

Chris Tennant Jefferson Laboratory March 15, 2013 “Workshop to Explore Physics Opportunities with Intense, Polarized Electron Beams up to 300 MeV”

USPAS 2005 Recirculated and Energy Recovered Linacs1 CHESS / LEPP USPAS Course on Recirculated and Energy Recovered Linacs I. V. Bazarov Cornell University.

Brookhaven Science Associates U.S. Department of Energy A Few Comments on the Photoinjector Performance X.J. Wang National Synchrotron Light Source Brookhaven.

C.Limborg-Deprey ERL Workshop, Jefferson March 20th 2005 Optimum electron distribution for space charge dominated beams.

Before aperture After aperture Faraday Cup Trigger Photodiode Laser Energy Meter Phosphor Screen Solenoids Successful Initial X-Band Photoinjector Electron.

Thomas Roser RHIC Open Planning Meeting December 3-4, 2003 RHIC II machine plans Electron cooling at RHIC Luminosity upgrade parameters.

Progress of SRF and ERL at Peking University Lu Xiangyang Institute of Heavy Ion Physics Peking University.

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

MEIC Electron Cooling Simulation He Zhang 03/18/2014, EIC 14 Newport News, VA.

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

Experience on GA optimization of photoinjector and minimum emittance in rings Chun-xi Wang Advanced Photon Source (APS) Argonne National Laboratory (ANL)

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

ASTRA Injector Setup 2012 Julian McKenzie 17/02/2012.

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.

Quantitative Optimisation Studies of the Muon Front-End for a Neutrino Factory S. J. Brooks, RAL, Chilton, Oxfordshire, U.K. Tracking Code Non-linearised.

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,

Electron Source Configuration Axel Brachmann - SLAC - Jan , KEK GDE meeting International Linear Collider at Stanford Linear Accelerator Center.

Accelerator Science and Technology Centre Extended ALICE Injector J.W. McKenzie, B.D. Muratori, Y.M. Saveliev STFC Daresbury Laboratory,

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

R&D opportunities for photoinjectors Renkai Li 10/12/2015 FACET-II Science Opportunities Workshops October, 2015 SLAC National Accelerator 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.

Electron Sources for ERLs – Requirements and First Ideas Andrew Burrill FLS 2012 “The workshop is intended to discuss technologies appropriate for a next.

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,

FLS2010 Workshop, Stanford, March 1-5, 2010 Florian Loehl (Cornell University) Commissioning of the High Current ERL Injector at Cornell Florian Loehl.

Update on Modeling Activities Gun Simulation Optimization Using Genetic Algorithms.

MeRHIC Internal Cost Review October, Dmitry Kayran for injector group MeRHIC Internal Cost Review October 7-8, 2009 MeRHIC: Injection System Gun.

S. Bettoni, R. Corsini, A. Vivoli (CERN) CLIC drive beam injector design.

Status of the Simulations on Photo Injector Optimization for Low Charges Yauhen Kot BD Meeting,

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

ICFA Workshop on Future Light Source, FLS2012 M. Shimada A), T. Miyajima A), N. Nakamura A), Y. Kobayashi A), K. Harada A), S. Sakanaka A), R. Hajima B)

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

Conventional source developments (300Hz Linac scheme and the cost, Part-II) Junji Urakawa, KEK PosiPol-2012 at DESY Zeuthen Contents : 0. Short review.

Beam plan at STF phase1 12/6/2005 TTC-WG3 H. Hayano STF phase1 1st step : DC-gun + photo-cathode (2006) quick beam source( DC gun exist), no pre-acceleration,

GDE FRANCE Why High brillance gun is good for the ERL scheme? And SC GUN? Alessandro Variola For the L.A.L. Orsay group.

Photocathode based Electron Sources for Particle Accelerators – Yesterday, Today and Tomorrow B.L. Militsyn STFC ASTeC, UK European Workshop on Photocathodes.

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

November 17, 2008 A. Brachmann Slide 1 ILC polarized Electron Source R&D Update LCWS 2008 A. Brachmann, J. Sheppard, F. Zhou - SLAC National Accelerator.

An Electron source for PERLE

Welcome! Ivan Bazarov Cornell University

Multi-bunch Operation for LCLS, LCLS_II, LCLS_2025

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

Plans of XFELO in Future ERL Facilities

Beam-beam effects in eRHIC and MeRHIC

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

Parallel 3D Finite Element Particle-In-Cell Simulations with Pic3P*

MIT Compact X-ray Source

Operational Experience with the Cornell ERL Injector SRF Cavities

The Cornell High Brightness Injector

Cornell Injector Performance

ERL Main-Linac Cryomodule

Needle Cathodes for RF Guns

LCLS Commissioning Parameters

Electron Source Configuration

ELIC Injector Working Group High-P, high-I source issues (DC)

Studies of Emittance & Lifetime

LCLS Commissioning Parameters

Selected simulations for XFEL photo injector

Test of Booster at UITF Reza Kazimi (12/12/18)

Simulations for the LCLS Photo-Injector C

MEIC Polarized Electron Source

LCLS Commissioning Parameters

ERL Director’s Review Main Linac

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

Presentation transcript:

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP ERL DC Gun Injector Evolutionary Algorithms Optimization Results Multivariate Optimization of High Brightness High Current DC Photoinjector Ivan Bazarov, Cornell University Talk Outline:

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP ERL Injector Goal: provide diffraction-limited beam at beam average current similar to storage rings (100 mA), or 0.08 mm-mrad (1  )normalized emittance, GHz in a 5 GeV ERL 750 kV DC Gun Cathode-Anode Region 2-Cell SRF Cavity

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Conventional Way to Design an Injector Cut the number of decision variables to some reasonable number (2-4) perhaps by using a simplified theoretical model to guide you in this choice One ends up with a single-point design without capitalizing on beneficial trade-offs that are present in the system Large regions of parameter space remain unexplored Optimize the injector varying the remaining variables with the help of a space-charge code to meet a fixed set of beam parameters (e.g. emittance at a certain bunch charge and a certain length) Primary challenge in exploring the full parameter space is computational speed

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Doing it faster work harder work smarter get help processor speed algorithms parallel processing Solution: use parallel MOGA MultiObjective Genetic Algorithm throw in all your design variables map out whole Pareto front, i.e. obtain multiple designs all of which are optimal use realistic injector model with your favorite space charge code

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Multi-Objective Optimization Problem Vilfredo Pareto,

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP MOGA 1. Initialize population 2. Evaluate objective functions / constraints 3. Assign fitness to all individuals (convergence & diversity) 4. Stochastically choose a subset for mating pool (higher fitness being preferred) 5. Apply crossing and mutation operators to generate offspring 6. Evaluate objectives / constraints for the offspring 7. 'Good' solutions make it to the next generation 8. Repeat from step 3.

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Example: Linear Collider minimize Total Cost maximize Luminosity

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Injector: Decision Variables Fields: DC Gun Voltage ( kV) 2 Solenoids Buncher SRF Cavities Gradient (5-13 MV/m) SRF Cavities Phase Positions: 2 Solenoids Buncher Cryomodule Bunch & Photocathode: E thermal Charge Laser Distribution: Spot size Pulse duration (10-30 ps rms) {tail, dip, ellipticity}  2 Total: dimensional parameter space to explore

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Injector Performance (E thermal = 35 meV, aka 780 nm) Takes several 10 5 simulations

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Closer Look: 80 pC

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Closer Look: 0.8 nC

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Extremely High Gun Voltage?

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Pulse Shaping

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Thermal Energy of the Photocathode

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP Summary DC gun based injector can be operable in wide range of parameters with good emittances: pC and 1 nC Fields required for such performance are modest Parallel MOGA is a powerful tool which should and will be widely used in the accelerator field DC gun based injector is a good / right choice of high current high brightness source We at Cornell are in the process of realizing such a system

I.V. Bazarov, Multivariate Optimization of High Brightness DC Gun Photoinjector, UCLA Workshop, 8-10 November CHESS / LEPP More details coming...