Emittance Oscillations in Long-Pulse Induction Linacs Bruce Carlsten Los Alamos National Laboratory May 25, 2011.

Slides:

Advertisements

Similar presentations

Imperial College London 1 3. Beam extraction 3. Extraction of particle beams 3.1 The space charge limit and Child-Langmuirs law 3.2 External and internal.

Advertisements

Particle acceleration in plasma By Prof. C. S. Liu Department of Physics, University of Maryland in collaboration with V. K. Tripathi, S. H. Chen, Y. Kuramitsu,

Synchrotron Radiation What is it ? Rate of energy loss Longitudinal damping Transverse damping Quantum fluctuations Wigglers Rende Steerenberg (BE/OP)

Effects of External Magnetic Fields on the operation of an RF Cavity D. Stratakis, J. C. Gallardo, and R. B. Palmer Brookhaven National Laboratory 1 RF.

SPACE CHARGE EFFECTS IN PHOTO-INJECTORS Massimo Ferrario INFN-LNF Madison, June 28 - July 2.

Simulations of Neutralized Drift Compression D. R. Welch, D. V. Rose Mission Research Corporation Albuquerque, NM S. S. Yu Lawrence Berkeley National.

1 Chris Rogers MICE Collaboration Meeting 11th Feb 2005 Tracking and Cooling performance of G4MICE.

Yu. Senichev, Coloumb 2005, Italy1 HAMILTONIAN FORMALISM FOR HALO INVESTIGATION IN HIGH INTENSITY BEAM Yu. Senichev, IKP, FZJ.

Eric Prebys, FNAL.  We consider motion of particles either through a linear structure or in a circular ring USPAS, Knoxville, TN, Jan , 2014 Lecture.

2 Lasers: Centimeters instead of Kilometers ? If we take a Petawatt laser pulse, I=10 21 W/cm 2 then the electric field is as high as E=10 14 eV/m=100.

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

COULOMB ’05 Experiments with Cooled Beams at COSY A.Lehrach, H.J.Stein, J. Dietrich, H.Stockhorst, R.Maier, D.Prasuhn, V.Kamerdjiev, COSY, Juelich, I.Meshkov,

NON-SCALING FFAGs: questions needing answers Andy Wolski The Cockcroft Institute, and the University of Liverpool Department of Physics. BASROC-CONFORM.

Simulation of direct space charge in Booster by using MAD program Y.Alexahin, N.Kazarinov.

The 2010 NFMCC Collaboration Meeting University of Mississippi, January 13-16, Update on Parametric-resonance Ionization Cooling (PIC) V.S. Morozov.

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

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

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

Proton Driver: Status and Plans C.R. Prior ASTeC Intense Beams Group, Rutherford Appleton Laboratory.

Transition from isotropic to anisotropic beam profiles in a uniform linear focusing channel Wilson Simeoni Jr In space-charge dominated beams the nonlinear.

REFERENCES [1] C.Y. Tan, FNAL Beams-doc-3646-v16, 2011 [2] V.N. Aseev, TRACK, the beam dynamics code, PAC05 [3] S. Kurennoy, LA-UR TRANSMISSION.

Calculation of the beam dynamics of RIKEN AVF Cyclotron E.E. Perepelkin JINR, Dubna 4 March 2008.

Simulation of direct space charge in Booster by using MAD program Y.Alexahin, A.Drozhdin, N.Kazarinov.

Operated by Los Alamos National Security, LLC for the U.S. Department of Energy’s NNSA U N C L A S S I F I E D Slide 1 Dynamic Electron Injection for Improved.

Two problems with gas discharges 1.Anomalous skin depth in ICPs 2.Electron diffusion across magnetic fields Problem 1: Density does not peak near the.

Accelerator PhysicsOak Ridge National Laboratory Jeff Holmes, Slava Danilov, and Sarah Cousineau SNS/ORNL October, 2004 ICFA Advanced Beam Dynamics Workshop.

1 FFAG Role as Muon Accelerators Shinji Machida ASTeC/STFC/RAL 15 November, /machida/doc/othertalks/machida_ pdf/machida/doc/othertalks/machida_ pdf.

Electron Model for a 3-10 GeV, NFFAG Proton Driver G H Rees, RAL.

K. Floettmann30 th Nov XFEL Injector matching The present XFEL injector foresees operation of the first four cavities of the first module to operate.

CLARA Gun Cavity Optimisation NVEC 05/06/2014 P. Goudket G. Burt, L. Cowie, J. McKenzie, B. Militsyn.

Physics of fusion power Lecture 12: Diagnostics / heating.

A.Shapovalov (DESY, Zeuthen) (MEPhI, Moscow, Russia)

FNAL 8 GeV SC linac / HINS Beam Dynamics Jean-Paul Carneiro FNAL Accelerator Physics Center Peter N. Ostroumov, Brahim Mustapha ANL March 13 th, 2009.

The Heavy Ion Fusion Virtual National Laboratory Neutralized Transport Experiment (NTX) P. K. Roy, S. S. Yu, S. Eylon, E. Henestroza, A. Anders, F. M.

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

Module 5 A quick overview of beam dynamics in linear accelerators

GWENAEL FUBIANI L’OASIS GROUP, LBNL 6D Space charge estimates for dense electron bunches in vacuum W.P. LEEMANS, E. ESAREY, B.A. SHADWICK, J. QIANG, G.

INTENSITY LIMITATIONS (Space Charge and Impedance) M. Zobov.

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

Frictional Cooling A.Caldwell MPI f. Physik, Munich FNAL

By Verena Kain CERN BE-OP. In the next three lectures we will have a look at the different components of a synchrotron. Today: Controlling particle trajectories.

Warp LBNL Warp suite of simulation codes: developed to study high current ion beams (heavy-ion driven inertial confinement fusion). High.

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

Physics 212 Lecture 4, Slide 1 Physics 212 Lecture 4 Today's Concepts: Conductors + Using Gauss’ Law Applied to Determine E field in cases of high symmetry.

Eric Prebys, FNAL.  We consider motion of particles either through a linear structure or in a circular ring USPAS, Hampton, VA, Jan , 2015 Longitudinal.

Beam-beam Simulation at eRHIC Yue Hao Collider-Accelerator Department Brookhaven National Laboratory July 29, 2010 EIC Meeting at The Catholic University.

Progress of Bunched Beam Electron Cooling Demo L.J.Mao (IMP), H.Zhang (Jlab) On behalf of colleagues from Jlab, BINP and IMP.

Pushing the space charge limit in the CERN LHC injectors H. Bartosik for the CERN space charge team with contributions from S. Gilardoni, A. Huschauer,

The Heavy Ion Fusion Virtual National Laboratory Erik P. Gilson** PPPL 15 th International Symposium on Heavy Ion Fusion June 9 th, 2004 Research supported.

Lecture 4 Longitudinal Dynamics I Professor Emmanuel Tsesmelis Directorate Office, CERN Department of Physics, University of Oxford ACAS School for Accelerator.

S.M. Polozov & Ko., NRNU MEPhI

Longitudinal Dynamics of Charged Particle

Positron production rate vs incident electron beam energy for a tungsten target

Preliminary result of FCC positron source simulation Pavel MARTYSHKIN

Preliminary results for electron lens with beam current of 20 A

Parametric Resonance Ionization Cooling of Muons

Beam-beam effects in eRHIC and MeRHIC

Space-Charge Effects in RF Photoinjectors

Jeffrey Eldred, Sasha Valishev

Space-charge Effects for a KV-Beam Jeffrey Eldred

First Experiments Testing the Working Hypothesis in HSX:

Superconducting High Brightness RF Photoinjector Design

Electron Rings Eduard Pozdeyev.

MEBT1&2 design study for C-ADS

Simulating transition crossing in the PS with HeadTail

2. Crosschecking computer codes for AWAKE

Injector for the Electron Cooler

Update on ERL Cooler Design Studies

He Zhang, David Douglas, Yuhong Zhang MEIC R&D Meeting, 09/04/2014

Plans for future electron cooling needs PS BD/AC

Presentation transcript:

Emittance Oscillations in Long-Pulse Induction Linacs Bruce Carlsten Los Alamos National Laboratory May 25, 2011

Slide 2 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA Outline Comments about DARHT Long-term emittance decrease in long-pulse induction linacs Emittance oscillations and their thermalization Nonlinear focusing forces Discussion

Slide 3 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA Long-Pulse Induction Linacs LANL and LBNL (with LLNL) collaborated on DARHT-2 accelerator. DARHT-1 was thoroughly designed and tested at ITS (only experimental demonstration of the centrifugal space-charge force) DARHT-2 was on a faster schedule THOR test facility with DARHT-2 cell

Slide 4 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA DARHT Long design effort on LCLS - short turn on Short design effort on DARHT-2 – long turn on There was a lot of new engineering for DARHT-2, but also unpredicted beam physics

Slide 5 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA Simulations LBNL – AMBER (Fawley and Vay) MRC – SPROP (Hughes) LANL – SLICE (Carlsten) All codes used equivalent physics – Gauss law for radial electric field, Ampere’s law for diamagnetic field, some other features Typically saw remarkable emittance decrease of about a factor of 10 (1000 mircons down to 150 microns) – very unique and interesting beam physics 90% emittances, use radial to avoid effect of solenoids 3.5-MeV, 4-kA diode

Slide 6 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA DARHT Enabled Study of Exciting Beam Physics Centrifugal Space-Charge Force Measurement CSCF is extra force term: CSCF cancels potential depression: Ion-hose suppression in induction cells Halo interception in beam cleanup zone (BCUZ) (Vlasov push)

Slide 7 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA Beam Physics We Want To Understand Today 1. Why does the emittance oscillate? 2. Why is there a gradual emittance decrease? 3. What causes these final stable oscillations?

Slide 8 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? Initial nonlinearities come from: Anode hole Magnetic field nonlinearities Density non-uniformity Spherical aberration from anode hole acerbated by beam Without beamWith beam Minor hollowing of beam density Nonlinearities in initial phase space, minor wavebreaking These two set the initial conditions on beam oscillations

Slide 9 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? Beam wants to oscillate about a stationary state Stationary state in space-charge dominated regime has uniform density – a non-uniform beam (zero emittance) will oscillate between a hollow and a peaked distribution. Below is phase space and density at first emittance maximum:

Slide 10 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? The excess free energy (above the minimum needed for the stationary state) is left over to make the emittance. We can calculate the excess free energy by calculating the beam energy and subtracting the beam energy of the stationary state, using Reiser’s prescription for nonlinear free energy: This approach provides a surprising accurate estimate of the maximum emittance in the plots (within 5% when include correlations)

Slide 11 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? These oscillations are same mechanism as emittance compensation, but with radial variations instead of axial variations: “Thin lens” compensation

Slide 12 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? Emittance compensation in a drift show wavebreaking also: Focusing lens at 28 cm These particles dominate the final emittance Hanerfeld, Herrmannsfeldt, and Miller, 1989 PAC

Slide 13 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? Emittance compensation in a uniform focusing field: (Exact same equations for the radially nonuniform case) Transverse eqn of motion for slice edge Equilibrium particle radius for a slice Do a perturbation expansion Slice expansion is oscillatory with a frequency that only depends on the external focusing Depends on axial position of slice K – external focusing, doesn’t depend on axial position of slice

Slide 14 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? S&R used a Cauchy transform to extend this to an accelerating beam: where: Worth pointing out this solution is substantially different. There are oscillating terms, but also now a constant acceleration term in the slice divergence. S&R addresses this with an “invariant envelope” trajectory. C&P identified that rf focusing at the cathode provides control of   and , which help line up the phase space ellipses.

Slide 15 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? If we keep the next order, we can predict when the phase space oscillations get out of phase: Expand to second order Particle oscillations out of phase after about 30 periods Final equipartitioning at 70% of maximum emittance J is current density up to r

Slide 16 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 1. Why Does the Emittance Oscillate? Boersch effect is very slow (thermalization due to Coulomb scattering), emittance growth of ~ 100 microns over 1 km at 5 MeV, 4 kA: Wavebreaking can also lead to thermalization (Reiser talks about wavebreaking in ¼ betatron period). Not true for low-emittance electron beams, wavebreaking occurs when a beam is focused if the charge density drops to < ½ of the average charge density within that point (Oscar Anderson). We can equivalently equate an emittance that is needed for particles to overcome the potential barrier of the beam and wavebreak: For a 4-kA, 4-MeV beam, this is about microns. For a 1-GeV, 100-mA, 1-mm radius H beam, this is about 0.1 micron.

Slide 17 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 2. Why is There a Gradual Emittance Decrease? The initial phase space curvature is not consistent with the initial beam density profile (doesn’t become flat). We can fix that with nonlinear forces in intense beams: Radial eqn of motion For a uniform density beam, radial variation in diamagnetic field cancels (to first order) change in potential depression This is the dominant nonlinear term, tailor beam focusing to work out phase space nonlinear “kink” We are defining divergences relative to the axial velocity on axis (r=0)

Slide 18 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 2. Why is There a Gradual Emittance Decrease? So we adjust the magnetic field profile to use the nonlinear focusing to straighten out the phase space as the beam is accelerated to 16 MeV

Slide 19 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 3. What Causes the Final Stable Emittance Oscillations? There is a beam halo from periodic wavebreaking (from every radial bounce in). Halo particles are emittance dominated with an oscillation wavenumber half the space-charge oscillation of the core: m 53.7 micron m 85.1 micron m micron m micron m micron Minimum emittance occurs when the two distributions are lined up (2:1 resonance). There is a minor trade between the focusing and minimizing the beam halo.

Slide 20 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 3. What Causes the Final Stable Emittance Oscillations? In principle, we can design a magnetic field match that leads to a nice radial profile spiraling into the axis (not oscillating) and get rid of the emittance oscillations. Let’s assume the beam is emittance dominated: Change of variables: Nice beam radial function (one of many): Leads to reasonable magnetic field profile:

Slide 21 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA 3. What Causes the Final Stable Emittance Oscillations? Using the matched solution, we can squeeze the beam to get the necessary conditions into the field profile (angle in phase space), entire beam is emittance dominated: Final emittance drops to about 40 microns (10 microns rms!) Comparison: thermal emittance is 50 microns from a 0.1 eV temperature, 8-inch cathode

Slide 22 U N C L A S S I F I E D Operated by Los Alamos National Security, LLC for NNSA Final Comments Non-thermalized beam preserves structure remarkably long Provides significant capability to tailor phase space using variety of nonlinear effects Insufficient diagnostics to measure these emittance Emittance dominated by downstream transport and bunch slicing