Alexei Fedotov, 02/02/12 1 Potentials for luminosity improvement for low-energy RHIC (with electron cooling) February 2, 2012.

Slides:

Advertisements

Similar presentations

Stochastic cooling and 56 MHz SRF update for Run-14 W. Fischer 21 January 2014.

Advertisements

Beam Dynamics in MeRHIC Yue Hao On behalf of MeRHIC/eRHIC working group.

Overview of Low Energy RHIC e-Cooler (LEReC) project and needed RHIC upgrades Vladimir N. Litvinenko Department of Physics and Astronomy, Stony Brook.

Note: most of the slides shown here are picked from CERN accelerator workshops. Please refer to those workshop for further understanding of the accelerator.

Ion Accelerator Complex for MEIC January 28, 2010.

Cooling Accelerator Beams Eduard Pozdeyev Collider-Accelerator Department.

SuperB and the ILC Damping Rings Andy Wolski University of Liverpool/Cockcroft Institute 27 April, 2006.

ERHIC Main Linac Design E. Pozdeyev + eRHIC team BNL.

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

Thomas Jefferson National Accelerator Facility Operated by the Southeastern Universities Research Association for the U.S. Department of Energy Issues.

Copyright, 1996 © Dale Carnegie & Associates, Inc. Intra-beam Scattering -- a RHIC Perspective J. Wei, W. Fischer Collider-Accelerator Department EIC Workshop,

Laslett self-field tune spread calculation with momentum dependence (Application to the PSB at 160 MeV) M. Martini.

1 QM2006 D.I.Lowenstein RHIC : The Path Forward Presented to Quark Matter 2006 Shanghai, PRC Derek I. Lowenstein Brookhaven National Laboratory November.

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

Toward a Test Facility for an ERL Circulator Ring Based e-Cooler MEIC Electron Cooler Test Facility Planning Retreat January 31, 2012.

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

Preliminary design of SPPC RF system Jianping DAI 2015/09/11 The CEPC-SppC Study Group Meeting, Sept. 11~12, IHEP.

Particle dynamics in electron FFAG Shinji Machida KEK FFAG04, October 13-16, 2004.

Theoretical studies of IBS in the SPS F. Antoniou, H. Bartosik, T. Bohl, Y.Papaphilippou MSWG – LIU meeting, 1/10/2013.

Beam dynamics on damping rings and beam-beam interaction Dec 포항 가속기 연구소 김 은 산.

October 4-5, Electron Lens Beam Physics Overview Yun Luo for RHIC e-lens team October 4-5, 2010 Electron Lens.

1 Flux concentrator for SuperKEKB Kamitani Takuya IWLC October.20.

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

July LEReC Review July 2014 Low Energy RHIC electron Cooling (LEReC) Alexei Fedotov LEReC overview: project goal and cooling approach.

Beam-Beam and e-Cloud in RHIC Oct. 6, 2015 Haixin Huang, Xiaofeng Gu, Yun Luo.

ERHIC design status V.Ptitsyn for the eRHIC design team.

ECOOL Meeting 03/26/10 1 Low-E cooler baseline decisions: 1.FNAL’s cooling section “as is” – with weak solenoids, correctors, etc. (to prevent over focusing.

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

Damping Ring Parameters and Interface to Sources S. Guiducci BTR, LNF 7 July 2011.

The SPS as a Damping Ring Test Facility for CLIC March 6 th, 2013 Yannis PAPAPHILIPPOU CERN CLIC Collaboration Working meeting.

Emittances Normalised r.m.s. Emittances at Damping Ring Extraction Horizontal Emittance (  m) Vertical Emittance (  m)

A First Look at the Performance for Pb-Pb and p-Pb collisions in FCC-hh Michaela Schaumann (CERN, RWTH Aachen) In collaboration with J.M. Jowett and R.

J.M. Jowett, S. Maury, PANIC05 HI Satellite meeting, 23/11/ LHC as a Heavy-Ion Collider An update John M. Jowett, Stephan Maury I-LHC Project CERN.

Prospects for RHIC Low-Energy Operations Todd Satogata (W. Fischer, T. Roser, A. Fedotov, N. Tsoupas, M. Brennan, C. Montag, and others) “Can We Discover.

09-21 Study of bunch length limits Goals: To identify and observe effects which put limits on the minimum bunch length in RHIC. Try to distiguish the limitation.

Synchronization Issues in MEIC Andrew Hutton, Slava Derbenev and Yuhong Zhang MEIC Ion Complex Design Mini-Workshop Jan. 27 & 28, 2011.

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

Robert R. Wilson Prize Talk John Peoples April APS Meeting: February 14,

1 RHIC II – Ion Operation Wolfram Fischer RHIC II Workshop, BNL – Working Group: Equation of State 27 April 2005.

LER Workshop, Oct 11, 2006Intensity Increase in the LER – T. Sen1 LHC Accelerator Research Program bnl-fnal-lbnl-slac  Motivation  Slip stacking in the.

1 Machine issues for RHIC II Wolfram Fischer PANIC Satellite Meeting – New Frontiers at RHIC 30 October 2005.

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,

Parameter scan for the CLIC damping rings July 23rd, 2008 Y. Papaphilippou Thanks to H. Braun, M. Korostelev and D. Schulte.

ApEx needs for CeC PoP Experiment December 11, 2015.

ELENA RF Manipulations S. Hancock. Apart from debunching before and rebunching after cooling, the principal role of the rf is to decelerate the beam and.

IBS and Touschek studies for the ion beam at the SPS F. Antoniou, H. Bartosik, Y. Papaphilippou, T. Bohl.

ECOOL Meeting 03/26/10 1 Electron beam transport for FNAL electron cooler E-cooling is referred as “non-magnetized” OVERVIEW Material is taken from FNAL’s.

EC plans in connection with eRHIC Wolfram Fischer ILCDR08 – Cornell University, Ithaca, New York 10 July 2008.

Alexei Fedotov, December 7, Beam parameters and collective effects for pEDM ring (December 7, 2009)

Alternative/complementary Possibilities

Electron Cooling Simulation For JLEIC

Luminosity Optimization for FCC-ee: recent results

CASA Collider Design Review Retreat Other Electron-Ion Colliders: eRHIC, ENC & LHeC Yuhong Zhang February 24, 2010.

I-LHC NOMINAL ions beam in 2007

Low Energy Electron-Ion Collision

PSB magnetic cycle 900 ms MeV to 2 GeV

JLEIC Reaching 140 GeV CM Energy: Concept and Luminosity Estimate

JLEIC ion fullsize booster (2256m) space charge limit (Δν=0

MEIC New Baseline: Part 10

Ion bunch formation options for 400GeV JLEIC

JLEIC 200 GeV ion beam formation options

HE-JLEIC: Boosting Luminosity at High Energy

JLEIC Main Parameters with Strong Electron Cooling

MEIC New Baseline: Part 7

Annular Electron Cooling

HE-JLEIC: Do We Have a Baseline?

Some Thoughts on the JLEIC Ion Injector

Optimization of JLEIC Integrated Luminosity Without On-Energy Cooling*

Updated MEIC Ion Beam Formation Scheme

Presentation transcript:

Alexei Fedotov, 02/02/12 1 Potentials for luminosity improvement for low-energy RHIC (with electron cooling) February 2, 2012

Alexei Fedotov, 02/02/12 2 Beam dynamics luminosity limits for RHIC operation at low energies Some fundamental limitations come from: Intra-beam Scattering (IBS): Strong IBS growth at lowest energies- can be counteracted by Electron cooling Beam-beam: Becomes significant limitation for RHIC parameters only at  > 20. Space-charge: At lowest energies, ultimate limitation on achievable ion beam peak current is expected to be given by space-charge effects.

Alexei Fedotov, 02/02/12 3 Luminosity limitation by space-charge and beam-beam Luminosity expressed through beam-beam parameter  Luminosity expressed through space-charge tune shift  Q: Single-bunch luminosity (shown for  *=10 m) limitation of Au ions in RHIC: 1) magenta line – limitation due to beam-beam parameter of (such values could not be reached without exceeding space-charge limit first) 2) limited by space-charge tune spread  Q sc =0.03 (blue, lower curve), 0.05 (red, solid line) and 0.1 (black, upper dash curve). Ratio of space-charge tune spread to beam-beam spread at low-energies in RHIC for rms bunch length 2 m (red) and 1 m (blue, upper dash line).

Alexei Fedotov, 02/02/12 Cooling of bunches with nominal length (1-2 m rms): Improvement comes mostly from counteracting IBS and longer stores. Expect larger gain for higher energies. 4

Alexei Fedotov, 02/02/12 5 With e-cooling at 3.85 GeV/n (sqrt[s]=7.7) factor 3 (in average Luminosity) x 1.5 (duty factor between stores, assumes 6-7 minutes between fills)=4.5 with cooling no cooling

Alexei Fedotov, 02/02/12 6 E-cooling benefits with nominal bunch length 1.Electron cooling can provide significant luminosity improvement for low-energy RHIC operation: - sqrt[s] < 11 GeV/n : factor sqrt[s]=11-16 GeV/n: about factor of 6 - sqrt[s]=16-20 GeV/n: factor 6-10 (additional factor at higher energies comes from cooling of transverse emittance to the space charge limit and decrease of  *) 2. Electron cooling offers longer stores with relatively constant luminosity. 3. Present choice of the cooler with electron energy up to 5MeV will extend cooling all the way up to present injection energy with heavy ions. As such, if needed, pre-cooling of transverse and/or longitudinal emittance can be done for high- energy program as well. At least factor of 3-6 gain in luminosity for all low energies with nominal bunch length (1-2 m rms, 28 MHz RF)

Alexei Fedotov, 02/02/12 Additional gain in luminosity is possible if one can tolerated operation with longer bunches (9MHz RF) for lowest energies: Since we are limited by space-charge, we cannot cool transverse emittance at lowest energy points of interest (sqrt[s] < 11 GeV/n). If bunch length is relaxed, we can now cool transverse emittance which in turn allows to reduce  *. Losses on transverse acceptance will be minimized as well. 7

Alexei Fedotov, 02/02/12 8 Luminosity limitation by space-charge Luminosity expressed through space-charge tune shift  Q sc : When also limited by transverse acceptance (which is the case for RHIC lowest energy points): f(  s /  *) f(  s /  *)*(  s /  *) hour-glass function

Alexei Fedotov, 02/02/12 Projection for luminosity improvement 9 Projection of total (without vertex cut) luminosity for 111 bunches of Au ions in RHIC with electron cooling and long bunches (for  s /  *=3) for the space-charge tune spread  Q sc =0.05 (red, solid curve) and 0.1 (blue, dash curve), and without cooling  Q sc =0.05,  s /  *=1/3 (magenta). Magenta (without cooling) – is optimistic projection which does not include losses on transverse acceptance and assumes very short stores to maximize average luminosity. Expect to get within factor of 2 of this line. Assumes acceptance limitation <  =4 (if <  =6, such drop in luminosity would start at  =6). expect with cooling

Alexei Fedotov, 02/02/12 10 E-cooling benefits and longer bunch length Operation with longer bunches allows to get more benefits from cooling at lowest energy points as well: (additional factor comes from cooling of transverse emittance to the space charge limit and decrease of  *) About factor of 10 gain in total luminosity for all low energies with longer bunch length. Some gain will be upset if detector length is not optimized for longer bunches.

Alexei Fedotov, 02/02/12 Electron cooler for Low-energy RHIC 11 1.Available working DC accelerator Pelletron from FNAL – suitable for cooling: < sqrt[s]=20 GeV/n: requires 3-4 years from the start of the project with full commitment of needed resources from C-AD. 2.RF-gun bunched beam electron cooler - can be designed to go above sqrt[s]=20 GeV/n: longer time scale and R&D needed. Different approaches are possible:

Alexei Fedotov, 02/02/12 12 Low-E RHIC Electron Q3 E-cooler: Recycler’s 6MV Pelletron (FNAL) RHIC beams

Alexei Fedotov, 02/02/12 13 Status of Pelletron-based (FNAL) cooler for RHIC Cost estimate of the project June 2010 (done) Estimate of C-AD manpower December 2010 (done) Feasibility study completed December 2010 (done) Start of the project ? January 2011 – did not start Due to significant resources required from C-AD, project is put on hold until decisions by Experiments are made at what energies significant increase in luminosity is required for future low-energy program at RHIC. October 2011: FNAL was informed that C-AD does not plan to start the project until needs from Experiments are fully established. March 2012: FNAL will start to decommission cooling section without assumption that it will be used for RHIC. For luminosity improvement need 3-4 years from the start of the project assuming full commitment of all needed resources from C-AD.