Kiyoshi Kubo 2008.04 Electron beam in undulators of e+ source - Emittance and orbit angle with quad misalignment and corrections - Effect of beam pipe.

Slides:

Advertisements

Similar presentations

Emittance dilution due to misalignment of quads and cavities of ILC main linac revised K.Kubo For beam energy 250 GeV,

Advertisements

Emittance dilution due to misalignment of quads and cavities of ILC main linac K.Kubo For beam energy 250 GeV, TESLA-type optics for 24MV/m.

On Cavity Tilt + Gradient Change (Beam Dynamics) K. Kubo K. Kubo.

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

ILC Accelerator School Kyungpook National University

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

Main Linac Simulation - Main Linac Alignment Tolerances - From single bunch effect ILC-MDIR Workshop Kiyoshi KUBO References: TESLA TDR ILC-TRC-2.

Dr. Zafer Nergiz Nigde University THE STATUS OF TURKISH LIGHT SOURCE.

ATF2 FB/FF layout Javier Resta Lopez (JAI, Oxford University) for the FONT project group FONT meeting January 11, 2007.

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

LCLS-II Transverse Tolerances Tor Raubenheimer May 29, 2013.

ATF2 Javier Resta Lopez (JAI, Oxford University) for the FONT project group 5th ATF2 project meeting, KEK December 19-21, 2007.

For Draft List of Standard Errors Beam Dynamics, Simulations Group (Summarized by Kiyoshi Kubo)

Y. Ohnishi / KEK KEKB-LER for ILC Damping Ring Study Simulation of low emittance lattice includes machine errors and optics corrections. Y. Ohnishi / KEK.

October 31, BDS Group1 ILC Beam Delivery System “Hybrid” Layout 2006e Release Preliminary M. Woodley.

Y. Ohnishi / KEK KEKB LER for ILC Damping Ring Study Lattice simulation of lattice errors and optics corrections. November 1, 2007 Y. Ohnishi / KEK.

Orbit Control For Diamond Light Source Ian Martin Joint Accelerator Workshop Rutherford Appleton Laboratory28 th -29 th April 2004.

DESY GDE Meeting Global Design Effort 1 / 12 Status of RTML Design and Tuning Studies PT SLAC.

Comparison between NLC, ILC and CLIC Damping Ring parameters May 8 th, 2007 CLIC Parameter working group Y. Papaphilippou.

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

Adiabatic eRHIC Extraction June 3, 2015Stephen Brooks, eRHIC meeting1 With emittance growth analysis.

Rough Estimation of energy spread produced in Final Focus line and effects to chromatic correction in ILC and ATF minor change Kiyoshi.

July 19-22, 2006, Vancouver KIRTI RANJAN1 ILC Curved Linac Simulation Kirti Ranjan, Francois Ostiguy, Nikolay Solyak Fermilab + Peter Tenenbaum (PT) SLAC.

Low emittance tuning in ATF Damping Ring - Experience and plan Sendai GDE Meeting Kiyoshi Kubo.

28-May-2008Non-linear Beam Dynamics WS1 On Injection Beam Loss at the SPring-8 Storage Ring Masaru TAKAO & J. Schimizu, K. Soutome, and H. Tanaka JASRI.

1 Alternative ILC Bunch Compressor 7 th Nov KNU (Kyungpook National Univ.) Eun-San Kim.

1 Alternative Bunch Compressor 30 th Sep KNU Eun-San Kim.

Placet based DFS simulations in the ILC Main Linac. Some preliminary results of error scans open for discussion Javier Resta Lopez JAI, Oxford University.

Emittance Tuning Simulations in the ILC Damping Rings James Jones ASTeC, Daresbury Laboratory.

DMS steering with BPM scale error - Trial of a New Optics - Kiyoshi Kubo

Main Linac Tolerances What do they mean? ILC-GDE meeting Beijing Kiyoshi Kubo 1.Introduction, review of old studies 2.Assumed “static” errors.

Simulations - Beam dynamics in low emittance transport (LET: From the exit of Damping Ring) K. Kubo

ERHIC Orbit Correction Studies (Minor Update) Using Oct’14 lattice and dispersion diagnostic January 5, 2015Stephen Brooks, eRHIC FFAG meeting1.

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

Undulator Based ILC positron source for TeV energy Wanming Liu Wei Gai ANL April 20, 2011.

DRAFT: What have been done and what to do in ILC-LET beam dynamics Beam dynamics/Simulations Group Beijing.

Wakefield effect in ATF2 Kiyoshi Kubo

8 th February 2006 Freddy Poirier ILC-LET workshop 1 Freddy Poirier DESY ILC-LET Workshop Dispersion Free Steering in the ILC using MERLIN.

Progress in CLIC DFS studies Juergen Pfingstner University of Oslo CLIC Workshop January.

Wakefield of cavity BPM In ATF2 ATF2 Project Meeting K.Kubo.

Review of Alignment Tolerances for LCLS-II SC Linac Arun Saini, N. Solyak Fermilab 27 th April 2016, LCLS-II Accelerator Physics Meeting.

CLIC Frequency Multiplication System aka Combiner Rings Piotr Skowronski Caterina Biscari Javier Barranco 21 Oct IWLC 2010.

ILC Main Linac Beam Dynamics Review K. Kubo.

Simulation for Lower emittance in ATF Damping Ring Kiyoshi Kubo Similar talk in DR WS in Frascati, May 2007 Most simulations were done several.

From Beam Dynamics K. Kubo

Arun Saini, N. Solyak Fermi National Accelerator Laboratory

ILC DR Lower Horizontal Emittance, preliminary study

Correlated Misalignments Studies for LCLS-II SC Linac

For Discussion Possible Beam Dynamics Issues in ILC downstream of Damping Ring LCWS2015 K. Kubo.

Emittance Dilution and Preservation in the ILC RTML

Beam Dynamics in Curved ILC Main Linac (following earth curvature)

ILC Z-pole Calibration Runs Main Linac performance

DFS Simulations on ILC bunch compressor

Adaptive Alignment & Ground Motion

Large Booster and Collider Ring

First Look at Nonlinear Dynamics in the Electron Collider Ring

Progress activities in short bunch compressors

The Proposed Conversion of CESR to an ILC Damping Ring Test Facility

Collider Ring Optics & Related Issues

Studies on orbit corrections

BEAM REALISTIC ERROR ORBIT IMPACT ON SASE PERFORMANCE

Linear beam dynamics simulations for XFEL beam distribution system

Yuri Nosochkov Yunhai Cai, Fanglei Lin, Vasiliy Morozov

Alternative Ion Injector Design

Fanglei Lin MEIC R&D Meeting, JLab, July 16, 2015

Progress Update on the Electron Polarization Study in the JLEIC

Possibility of MEIC Arc Cell Using PEP-II Dipole

Fanglei Lin JLEIC R&D Meeting, August 4, 2016

Main Linac Beam Optics and Tolerances

Status of RCS eRHIC Injector Design

Presentation transcript:

Kiyoshi Kubo Electron beam in undulators of e+ source - Emittance and orbit angle with quad misalignment and corrections - Effect of beam pipe wakefiled

Part1. Emittance and orbit angle with quad misalignment and corrections Review of old work Report in ILC LET meeting at Daresbury Main Concerns were: Radiation in undulators may increase transverse emittance if there is dispersion Section by section orbit angle change, then gamma-ray angle change, can make polarization of e+ impossible.

Lattice and assumption Undulator: –Field 1T –Period 14 mm –Total undulator length 119 m 11.9 m between quadrupole magnets, 10 sections –No field errors, no misalignment Lattice: –Quadrupole magnet every 12.4 m, –x 70 deg. y 90 deg. per FODO cell –Quad-BPM-dipole corrector package Errors –Quad offset 0.3 mm, rotation 0.3 mrad –BPM offset 10 micron w.r.t. quad, rotation 0.3 mrad No wakefield Parameters are not exactly the same as present design, but probably the difference is not too significant for rough estimations here. (or, scaling will be possible.)

Kick Minimization Quad magnet, BPM and steering magnets should be attached.

Helical Undulator in SAD Simulation used computer code SAD –Helical undulator is not supported as a standard magnet. Represented by series of bend magnets –16 bend magnets/period (0.875 mm/magnet) –Rotate i-th magnet by (360/16)*i deg.

Beam Energy and Energy Spread vs. s

Emittance increase in the undulator section No undulator (replaced by drift space) With undulator (radiation) average 0.16 nm average 0.38 nm Quad offset 0.3 mm, rotation 0.3 mrad BPM offset 10 micron w.r.t. quad, rotation 0.3 mrad KM steering, 100 random seeds.

Orbit angle distribution Each set consists of 10 points (There are 10 undulator sections, each of which is between two quadrupole magnets.). Each point represents orbit angle at the entrance of a quadrupole magnet after each undulator section. Note: 1/gamma = 3.3e-6.  x’ ~ 2-3e-6,  y’ <<  x’ Note: Design y’ is not zero, to make overall orbit straight. We assumed ends of each undulator have horizontal field.

Distribution of r.m.s. of orbit angle Below 1/gamma

Summary of part 1 Misalignment of quadrupole magnets 0.3 mm. Orbit correction (KM steering) We assumed a good BPM and a dipole corrector attached to every quadrupole magnet. Radiation in undulators with dispersion –Vertical emittance increase ~ 1 nm or less. OK. Section by section orbit angle change, –Angle distribution ~ 2  rad or less (<1/  ). Probably OK.

Part 2. Effect of beam pipe resistive wake Rough estimation of effects of resistive wall wake to transverse (vertical) motion. Dependence on Wake- potential (W_T) Wakefield itself was studied by: –Dr. Thesis of Duncan J. Scott –But, it assumed bunch length 0.15 mm (0.3 mm is nominal. The longer the bunch, the larger the W_T) beam pipe radius 1mm or 2 mm. (Looks too small.) –So, I did rough estimation of W_T too.

Transverse wake for short bunch K.L.F.Bane, Int. J. Mod. Phys. A. vol. 22, p 3736, 2007 and thesis of Duncan J. Scott, For 0.3 mm bunch length, Peak of wake potential ~  -1/2 b -3 ~ 200 V/pC/m 2 for Cu 77K (  =500 M  -1 ), radius= 2.38 mm

Rough estimation of effect to beam motion Wake potential: W T [V/pC/m^2] Relevant beam pipe length: L [m] Beam - beam pipe center offset: y [micron] Bunch charge = 3.2 nC Beam energy = 150 GeV  Kick angle of bunch tail:  [nrad] ~ 2 x * W T * L * y The kick angle should be compared with angular divergence:  y’ = sqrt(  y /  y ) ~ 60 nrad  y ~ /  = 7 x m  y ~ 20 m

Effect of Beam Orbit Jitter (Faster than corrections) Wake potential: W T [V/pC/m^2] Relevant beam pipe length: L [m] ~ 200 Vertical beam jitter: y [micron] ~  y ~ 1   [nrad] ~ 4 x * W T Requiring  y’ ~ 60 [nrad]  W T << 1.5 x 10 4 [V/pC/m^2] This limit is 75 times bigger than the estimated W T for the case of Cu 77K (  =500 M  -1 ) and radius= 2.38 mm. OK.

Effect of Beam Pipe misalignment (Pipe center - beam offset) (Relevant beam pipe length can be set as beta-function. ) Wake potential: W T [V/pC/m^2] Relevant beam pipe length: L [m] ~  ~ 20 Total length/relevant length: n ~ 200/20 = 10 Vertical movement: y [micron]    [nrad] ~ 4 x * W T * y*sqrt(n)  (Assuming each 20 m is randomly misaligned) Requiring  y’ ~ 60 [nrad]  W T [V/pC/m^2] * y [micron] << 4.7 x 10 4 Assuming W T for the case of Cu 77K (  = 500 M  -1 ) and radius= 2.38 mm, this means y [micron] << 240 Assume corrections (minimize down stream emittance, changing either orbit or pipe position), the tolerance for static misalignment will be larger.  Probably OK. But we will need diagnostics (emittance measurement) section after the undulators.

Summary Misalignment of quadrupole magnets 0.3 mm. With a good BPM and a dipole corrector attached to every quadrupole magnet. Radiation in undulators with dispersion –Vertical emittance increase ~ 1 nm or less. OK. Section by section orbit angle change, –Angle distribution ~ 2  rad or less (<1/  ). Probably OK. Effect of resistive wall wakes Assuming 2.38 mm radius, Cold Cu beam pipe Effect of beam orbit jitter will be negligible. Alignment (pipe center to beam) should be much better than 240 micron, assuming no corrections. –Will be loosened with corrections. Need diagnostics section (emittance measurement) after the undulators. Question: Whether all important issues have been studied or not.