TATIONpRÆSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET High Energy Collimator Recommendation H.D. Thomsen, S.P. Møller (ISA, Aarhus University) M. Eshraqi,

Slides:

Advertisements

Similar presentations

R. Miyamoto, Beam Physics Design of MEBT, ESS AD Retreat 1 Beam Physics Design of MEBT Ryoichi Miyamoto (ESS) November 29th, 2012 ESS AD Retreat On behalf.

Advertisements

ISIS Accelerator Division

ESS End-to-End Optics and Layout Integration Håkan Danared European Spallation Source Catania, 6 July 2011.

Experience with Bunch Shape Monitors at SNS A. Aleksandrov Spallation Neutron Source, Oak Ridge, USA.

Masahito TOMIZAWA and Satoshi MIHARA Accelerator and proton beam.

TUPD02 BEAM DIAGNOSTICS FOR THE ESS BLM BPM Trans Profile Bunch Shape BCM Preliminary System Count A. Jansson, L. Tchelidze, ESS AB, Lund, Sweden Hybrid.

Space Charge Issues in the SNS Linac and Ring

(ISS) Topics Studied at RAL G H Rees, RAL, UK. ISS Work Areas 1. Bunch train patterns for the acceleration and storage of μ ± beams. 2. A 50Hz, 1.2 MW,

GRD - Collimation Simulation with SIXTRACK - MIB WG - October 2005 LHC COLLIMATION SYSTEM STUDIES USING SIXTRACK Ralph Assmann, Stefano Redaelli, Guillaume.

Managed by UT-Battelle for the Department of Energy SNS MEBT : Beam Dynamics, Diagnostics, Performance. Alexander Aleksandrov Oak Ridge National Laboratory.

ORNL-SNS Diagnostic Group SNS Beam Loss Monitors and HARPs Machine Protection System FDR September 11,2001 Presented by Saeed Assadi.

100 MeV- 1 GeV Proton Synchrotron for Indian Spallation Neutron Source Gurnam Singh Beam Dynamics Section CAT, Indore CAT-KEK-Sokendai School on Spallation.

Field and Phase Error Studies in Normal Conducting Structures LLRF and Beam Dynamics in Hadron Linacs – EuCARD2 Workshop Ciprian Plostinar

Loss problems associated with the acceleration of radioactive beams and what we can do about it A.Jansson f fermilab Loss issues (and ideas for solutions)

3 GeV,1.2 MW, Booster for Proton Driver G H Rees, RAL.

Ion Programme of LHC Hans-H. Braun Miniworkshop on Machine and Physics Aspects of CLIC based future Collider Option, Ion Programme of LHC Hans-H.

TATIONpRÆSEN APRIL 8, 2014 AARHUS UNIVERSITET Commissioning of the A2T: DC and AC Magnet Systems Heine Dølrath Thomsen, ISA, Aarhus University 1.

Related poster [1] TPAG022: Slow Wave Electrode Structures for the ESS 2.5 MeV Chopper – Michael A. Clarke-Gayther Status Funding bids have been prepared.

Experience from the Spallation Neutron Source Commissioning Dong-o Jeon Accelerator Physics Group Oak Ridge National Laboratory May 9, 2007.

NUFACT August 2014 E. Wildner, CERN 13/03/14Nufact14, Glasgow, E. Wildner 2 Accumulator Ring for the ESS Neutrino Super Beam.

J-PARC Accelerators Masahito Tomizawa KEK Acc. Lab. Outline, Status, Schedule of J-PARC accelerator MR Beam Power Upgrade.

UKNF OsC RAL – 31 st January 2011 UKNF - Status, high lights, plans J. Pozimski.

F Project-X Related Issues in Recycler A.Burov, C.Gattuso, V.Lebedev, A.Leveling, A.Valishev, L.Vorobiev Fermilab AAC Review 8/8/2007.

FFAG-Workshop Dec Kumatori Japan Diagnostics for FFAG- accelerator Takahisa ITAHASHI Department of Physics, Osaka Univ. Toyonaka, Osaka, ,Japan.

Alexander Aleksandrov Oak Ridge National Laboratory

Report from Task Force on Beam Instrumentation Stephen Molloy.

R. Miyamoto, Beam Loss and Collimation in the ESS Linac, HB Beam Loss and Collimation in the ESS Linac Ryoichi Miyamoto (ESS) B. Cheymol, H. Danared,

Managed by UT-Battelle for the Department of Energy Residual Does Rate Analyses for the SNS Accelerator Facility I. Popova, J. Galambos HB2008 August 25-29,

PROTON LINAC FOR INDIAN SNS Vinod Bharadwaj, SLAC (reporting for the Indian SNS Design Team)

Managed by UT-Battelle for the Department of Energy Using Online Single Particle Model for SNS Accelerator Tuning Andrei Shishlo, Alexander Aleksandrov.

HWDB: Operations at the Spallation Neutron Source Workshop on Accelerator Operations August 6-10, 2012 Glen D. Johns Accelerator Operations Manager.

Overview of Booster PIP II upgrades and plans C.Y. Tan for Proton Source group PIP II Collaboration Meeting 03 June 2014.

Managed by UT-Battelle for the Department of Energy SNS Injection and Extraction Systems Issues and Solutions by M. Plum for the SNS team and our BNL collaborators.

Accelerator Science and Technology Centre POST-LINAC BEAM TRANSPORT AND COLLIMATION FOR THE UK’S NEW LIGHT SOURCE PROJECT D. Angal-Kalinin,

NuFact'06 WG3, Aug. 2006A. Fabich, CERNBeta-beam Ion Losses, 1 The EURISOL Beta-beam Acceleration Scenario: Ion Losses A. Fabich, CERN NuFact’06, UCIrvine.

ICFA-HB 2004 Commissioning Experience for the SNS Linac A. Aleksandrov, S. Assadi, I. Campisi, P. Chu, S. Cousineau, V. Danilov, G. Dodson, J. Galambos,

Design Optimization of MEIC Ion Linac & Pre-Booster B. Mustapha, Z. Conway, B. Erdelyi and P. Ostroumov ANL & NIU MEIC Collaboration Meeting JLab, October.

Project X RD&D Plan Beam Transfer Line and Recycler Injection David Johnson AAC Meeting February 3, 2009.

1 Question to the 50GeV group 3GeV からの 54π と 81π 、 6.1π の関係 fast extraction 部の acceptance (81π?) Comments on neutrino beamline optics?

Accelerator Science and Technology Centre POST-LINAC BEAM TRANSPORT AND COLLIMATION FOR THE UK’S NEW LIGHT SOURCE PROJECT D. Angal-Kalinin,

Beam Instrumentation in Monolith Stephen Molloy PBI Taskforce Leader.

Paul Scherrer Institut

LHC collimation R. Bruce on behalf of the CERN LHC collimation team R. Bruce,

Proton Driver Design Keith Gollwitzer Fermilab February 19, 2014.

Beam collimation in the transfer line from 8 GeV linac to the Main Injector A. Drozhdin The beam transfer line from 8 GeV Linac to the Main Injector is.

Future Circular Collider Study Kickoff Meeting CERN ERL TEST FACILITY STAGES AND OPTICS 12–15 February 2014, University of Geneva Alessandra Valloni.

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,

SNS Beam Diagnostics A. Aleksandrov Spallation Neutron Source, Oak Ridge, USA.

Beam losses and collimation at the Oak Ridge Spallation Neutron Source by Mike Plum Beam losses and collimators in transfer lines workshop Lund May 13-14,

Beam on Target Diagnostics Beam on Target Meeting 2013 March Tom Shea.

R. Miyamoto, MEBT Lattice Optimization, ESS AD Beam Physics Internal Review 1 MEBT Lattice Optimization Ryoichi Miyamoto (ESS) For Beam Physics Group,

Collimation design considerations at CERN (with some applications to LHC) R. Bruce on behalf of the CERN LHC collimation project R. Bruce,

ORNL is managed by UT-Battelle for the US Department of Energy SNS beam loss and control By M. Plum ICFA mini-workshop on beam commissioning for high intensity.

SNS linac beam commissioning By Michael Plum Spallation Neutron Source Oak Ridge National Laboratory ESS Workshop on beam commissioning April 8-9, 2014.

HEBT Design Considerations Jingyu Tang, Xiangqi Wang, Hao Hao, Jiajia Tian IHEP, USTC International Review Meeting on Accelerator Physics Design of C-ADS,

Machine Protection Systems (MPS) Arden Warner, and Jim Steimel Project X Machine Advisory Committee March 18-19, 2013.

M. Munoz April 2, 2014 Beam Commissioning at ESS.

J-Parc Neutrino Facility Primary Proton Beam Design A. K. Ichikawa(KEK), Y.Iwamoto(KEK) and K.Tanabe(Tokyo) et.al. 7 th Nov. 2003,

ORNL is managed by UT-Battelle for the US Department of Energy Commissioning experience of SNS Ring By M. Plum ICFA mini-workshop on beam commissioning.

ANNE I. S. HOLM AARHUS UNIVERSITET INSTITUT FOR FYSIK OG ASTRONOMI BASELINE DESIGN OF THE ESS HIGH ENERGY BEAM TRANSPORT LINE ANNE I. S. HOLM.

TATIONpRÆSEN January 25, 2013 AARHUS UNIVERSITET Raster Scanning of the ESS Beam Heine Dølrath Thomsen 1.

Zheng Yang, Jing-Yu Tang, IHEP, China

Collimation Concept for Beam Halo Losses in SIS 100

Joint Meeting SPS Upgrade Study Group and SPS Task Force

Acknowledgments: LIU-PT members and deputies, H. Bartosik

1- Short pulse neutron source

Advanced Research Electron Accelerator Laboratory

Beam Commissioning at ESS

Beam Commissioning Planning

DTL for MEIC Ion Injection

Presentation transcript:

TATIONpRÆSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET High Energy Collimator Recommendation H.D. Thomsen, S.P. Møller (ISA, Aarhus University) M. Eshraqi, R. Miyamoto, E. Laface, T. Shea, E. Pitcher, A. Nordt, L. Lari, L. Tchelidze, H. Danared, P. Ladd (ESS) S. Wronka, K. Szymczyk, P. Warzybok (NCBJ, Swierk) 1

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET HEBT Layout + Collimator Baseline 2 μ x,y = 60° ≠Neutron Shield Wall! Single-stage

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Beam Expander System 3 Focusing = (Lin. – non-lin) PBW Dogleg

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Collimator Workshop, May, ESS: “Beam Losses and Collimators in Transfer Lines” ›11 external experts at hand: CERN (6), SNS (1), KEK (1), PSI (2), GSI (1) ›Uncontrolled losses? Focus on ~2 GeV ›If possible, beam should be stopped at lower energies. ›Solution & experience sharing! Collimation strategies? ›Visiting labs: collimators are being used to (HDT’s impression): ›Reduce operational beam losses: Prepare the beam for a next-stage accelerator (typically ring-based) ›Protect sensitive accelerator hardware (e.g. SC magnets) ›Clean beam downstream of parasitic secondary beam production targets (PSI) ›Workshop recommendations: ›Experience from similar operating facilities should be studied with the SNS being the lead candidate. ›Beam physics studies should be performed to fully determine the need for collimation. Be very specific in purpose! Every-day operation & infrequent catastrophic events. ›If possible, consider a more global collimation strategy, i.e. MEBT + HEBT collimator performance? 4

R. Bruce, General design considerations When designing an accelerator facility: Do we need collimators? Where should collimators be installed? – Global/local protection? – Betatron / momentum collimation? Multi-stage system? Movable devices or fixed masks? What material? What simulation tools do we have? Design choices depend on losses we want to protect against

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Inter-Diciplinary Ad-Hoc Working Group Kick-off meeting late August. ›ISA, Denmark: H.D. Thomsen, S.P. Møller ›ESS: M. Eshraqi, R. Miyamoto, E. Laface, T. Shea, E. Pitcher, A. Nordt, L. Lari, L. Tchelidze, H. Danared, P. Ladd, S. Molloy ›NCBJ, Poland: S. Wronka, K. Szymczyk, P. Warzybok ›Linac + HEBT beam physics, beam instrumentation, target, machine protection, beam loss simulations & shielding, vacuum, mechanical design, … Conclusive proposal: ›No clear justification for the existing HEBT collimator systems. Remove them from the ESS baseline design. ›Reducing the overall project contingency a tiny degree. ›Continue collimator design, but not construction, to be prepared for surprises? ›(Another discussion: how far?) 6

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET A SIMILAR FACILITY The Oak Ridge Spallation Neutron Source 7

M. Plum – ESS Beam Losses and Collimation wkshp May Managed by UT-Battelle for the U.S. Department of Energy SNS Scrapers and collimator locations RTBT HEBT Injection Extraction RF Collimators In MEBT: Left-right, top-bottom scrapers In HEBT: Two pairs of left-right scrapers Two pairs of top-bottom scrapers Two collimators In HEBT: Left-right (high and low momentum) scrapers Followed by beam dump In Ring: Four scrapers (0, 45, 90, 135 deg.) Three collimators Most effective Occasionally used Scrapers almost never used Rarely used In RTBT: Two collimators Target protection ESS – no ring: Small emittance Strictly single-pass Beam quality?

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET ESS (5 MW, p) vs. SNS (1.4 MW, H - )? Shishlo et al., IPAC'12, TUOBA03 (2012), Intra-Beam Stripping (IBST): The reduced beam loss for protons implies that a proton SCL should be able to provide several times higher power with the same low activation and ``hands on'' maintainability as the existing SNS linac. SNS HEBT? Beam debunches -> IBST not a concern. 9 H-H- p H -, I p 2 p, I p

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET BEAM STUDIES Operational Beam Losses: activation, material deterioration, etc. 10

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Simulating the HEBT Halo? HEBT s = 0 ›Two-component beam, (core + halo) ›Typically 2 x Gaussians ›ε h / ε c = 5 ›N h / (N h +N c ) = 1% ›6D: transverse + longitudinal End-to-End, ESS Acc. Phys. ›4D Gaussian is fed into the RFQ ›MEBT->DTL->SCL->HEBT ›Time-consuming but can be rewarding (long. effects) 11 Errors (stat + dyn) can be applied to both approaches

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Injection: HEBT Error Studies 12 IPAC’14, WEPRO074: 1000 HEBTs x 10 6 particles: STAT (+ corr) + DYN Errors No losses until target monolith (<100 W)

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET End-to-End (ESS Beam Physics Group) HEBT: ›Low-energy protons ( MeV) ›E < 800 MeV are lost inside the first dipole 13 RFQ output R. Miyamoto, HB2014, MOPAB18 +Errors 10 3 x10 5 -Errors 1x10 7

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Also SNS Achromat to Ring? 14 mrem / hr 10 mSv/h

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET “Alternative”: Normalized HEBT Aperture 15 SNS HEBT: 15 – 1.4 MW APT HEBT: 100 MW

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET 16

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET 17 HEBT Aperture

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET BEAM STUDIES Accidental Beam Losses: accelerator component damage 18

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Timescales of Component Failure Initiating event: The failure of an accelerator component leads to dramatic beam parameter changes. Result: Beam losses are increased dramatically at downstream (key) locations. Collimators can buy time before beam-induced accelerator component damage. Timescale τ f of the initiating event is important in order to determine response time of mitigating system. ›FAST: τ f < 2.86 ms, beam parameters can change considerable during a pulse ›RF (arcing) ›Low-inductance magnets (raster system?) ›MODERATE: τ f > 2.86 ms, impact can build up over a number of pulses ›High-inductance magnets (conventional magnets) 19

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Case 1: RF Failure, ∆E = 0 MeV 20 ∆y < 0.33 mm/MeV

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Case 1: RF Failure, ∆E = -100 MeV 21 ∆y < 0.33 mm/MeV

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Case 1: ∆E, BEW 22

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Case 2: Raster System ›8 raster magnets (4H + 4V). ~40 kHz triangle wave, nom. ±2 mT.m (max. ±5 mT.m) ›Failure cases: ›2a: full failure. Beam is left static on target and PBW. ›2b: Excessive amplitude? ›2c: Internal synchronization? ›Only 2b could possibly be mitigated by collimation. Part of Target Monolith? 23

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Case 3: Final Doublet, 71 ms failure in QP5 24

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET “Alternative”: Machine Protection 25 Beam can be inhibited within ~20 µs (133 µs of beam corresponds to 1 SNS pulse)

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET Summary ›No universal collimator design available: focus on actual problem(s) in our unique machine! ›SNS: ›H - problem: irrelevant to collimation questions ›HEBT collimators only applied to make small improvements to the beam losses. ›MEBT scraper system has been upgraded. ESS status & actual problems? ›Transverse halo: does not seem to be a problem. Ample apertures are used. ›BES suppresses beam distribution (quality) + no second-stage accelerator ›Upstream dogleg dipole will filter out low-energy tail. May be “considerable” (~10 W/m)? ›Accidental beam failures: passive machine protection ›HEBT collimators cannot provide global protection Proposal: ›Remove HEBT collimators from the ESS baseline ›Design. Build if found necessary (latency!) ›Pursue the issue with the upstream dipole 26

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET EXTRA SLIDES 27

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET E2E Error Magnitudes 28 HB2014, MOPAB18 RFQ beam errors Element errors

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET BEAM STUDIES MEBT Scraper System? 29

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET 30

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET 71 ms failure in QP6 31

HEINE DØLRATH THOMSEN ESS TAC, 5-6 Nov, 2014 AARHUS UNIVERSITET 71 ms failure in QP6 32

33Managed by UT-Battelle for the U.S. Department of Energy M. Plum – ESS Beam Losses and Collimation wkshp May 2014 Some sample H + beam profiles in the SNS HEBT Horizontal Vertical Profiles measured Dec. 22, 2013 Non-Gaussian tails / halo appear beginning at ~1/10 of peak Solid lines show Gaussian fits to the data 1/10

34Managed by UT-Battelle for the U.S. Department of Energy M. Plum – ESS Beam Losses and Collimation wkshp May 2014 More H + beam profiles in the SNS HEBT Horizontal Vertical Profiles measured April 6, 2014 Non-Gaussian tails / halo appear beginning at ~1/10 of peak Solid lines show Gaussian fits to the data 1/10