Longitudinal beam parameters and stability

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Presentation transcript:

Longitudinal beam parameters and stability E. Shaposhnikova, J. E. Muller 6th HL-LHC collaboration meeting, Paris 15 November 2016 Acknowledgements: P. Baudrenghien, H. Timko

Outline Summary Experience from present LHC operation HL-LHC Bunch length Stability Longitudinal emittance blow-up and distribution HL-LHC Single RF operation Double RF operation higher harmonic lower harmonic Summary

Bunch length during physics 2012: 4.0 TeV 2015: 6.5 TeV

Longitudinal beam stability in LHC Single bunch stability threshold is well defined by measurements in MDs and operation (long fills) J. E. Muller et al. → Single bunch instability for multi-bunch beam No wideband FB in LHC → we rely on Landau damping

Controlled emittance blow-up Synchrotron frequency distribution inside the bunch Phase noise Bunch length bifurcation during emittance blow-up for 0.85 ns target length in 2015 MD Similar observations in 2016 MDs and initial operation with reduced bunch length → Increased initial target bunch length during ramp in 2016 operation

(Un)controlled emittance blow-up H. Timko → Maximum bunch length ~ 1.5 ns limited by losses (~5%) from the RF bucket (MD ramp with target bunch length 1.2 s leading to maximum gain in BL FB)

Longitudinal beam parameters Bunch-to-bunch variation (from injectors) leads to different synchrotron frequency shifts and therefore final emittance blow-up (denser bunches are blown up less) → Bunch-to-bunch length variation after controlled emittance blow-up (BUP) Beam-to-beam and fill-to-fill variation (also due to action of bunch length feedback) → Variation in instability threshold Synchrotron frequency distribution after BUP (PD Schottky spectrum)

Longitudinal beam stability in LHC Preliminary results of MD on 28.10.2016 (T. Mastoridis, J. E. Muller, E. Shaposhnikova, H. Timko et al.) Beam1 V=7.5 MV @6.5 TeV, nominal intensity Beam1: Target bunch length 1.1 ns (1.05 ns obtained) → All bunches above single bunch instability threshold → No coupled-bunch modes were observed, but phase oscillations with amplitude increasing along the beam Beam1: flat top

Longitudinal beam stability in LHC Phase oscillations on flat bottom and during ramp for nominal beam with 1.2 ns target bunch length (blow-up and after arrival to flat top) Beam1: flat bottom average/(SPS batch) during ramp and flat top

HL-LHC

Double RF operation Full detuning scheme will be used in operation for high intensity beams (P. Baudrenghien et al.) leading to bunch displacements → Only bunch-shortening operation mode is really feasible in a double RF system V2/V1=2

Longitudinal beam stability in HL-LHC 400 MHz & (400 MHz + 800 MHz) RF E=7 TeV, V400 = 16 MV, V800 = 4 MV ImZ/n ~ 0.11 Ohm (N. Biancacci et al.) → 1.0 ns bunches are unstable → Voltage of 4 MV @ 800 MHz would be sufficient for stability of bunches > 0.85 ns (as now) 10% spread in bunch length Controlled longitudinal BUP, if done too close to instability threshold, may excite dipole motion SR leads to bunch shrinkage → 1.2 ns nominal average bunch length in a single RF system Cavity design: T. Roggen & Y. Shashkov

Longitudinal instability for HL-LHC intensity Bunch length during ramp Bunch length on LHC flat top RF MD on 25.08.2016, V=12 MV, P. Baudrenghien, J. Muller, H. Timko, E. S.

Longitudinal beam stability in HL-LHC: 200 MHz & (200 MHz + 400 MHz) RF V200=6 MV, V400=3 MV Reduction of e-cloud, beam-induced heating, pile-up density… → Bunches with 1.9 ns length are at the limit of stability in a single RF and with 1.4 ns in a double RF (BSM) → Operation (assuming 10% spread and uncertainty in BUP): τav > 1.55 ns in 2RF → 1.7 ns τav > 2.1 ns in 1RF → 2.3 ns Cavity design: R. Calaga

Longitudinal beam parameters in 1 & 2 RF systems for stable operation @7 TeV with 2.2x1011 ppb & minimum (average) bunch length RF system V1 [MV] V2 Bunch length (4σ) [ns] Emittance (2σ) [eVs] dE/E [10-4] 400 MHz 16.0 0.0 1.2 3.0 2.36 400 & 800 MHz (BSM) 8.0 0.85 2.1 2.32 4.0 1.0 2.5 2.34 200 MHz 6.0 2.3 4.85 1.97 200 & 400 MHz (BSM) 1.7 3.6 2.0 Based on single-bunch stability threshold (loss of Landau damping) for beam with 10% spread in bunch length and with additional 10% margin (shrinkage due to SR damping and uncertainty in emittance blow-up)

Bunch distribution in single RF system Binomial line density distribution λ(t) = λ0 (1 – 4 t2/τ2)2.5 fits well the present LHC bunches (single RF) on flat bottom and at the beginning of flat top (after controlled emittance blow-up with band-limited noise during ramp) Real bunch tails are more populated (also visible from the PD Schottky) Profiles become Gaussian after a few hours due to IBS and SR

Bunch distribution in double RF system Example of double RF system with V2/V1=0.5 in BSM Band-limited noise applied to the bunch centre flattens the profile Tested in BLonD simulations (H. Timko) bunch profiles bunch spectra particle distribution functions

Summary In the 400 MHz RF system longitudinal stability of bunches with nominal HL-LHC length of 1.08 ns is at the limit. Margins are required due to bunch-to-bunch and fill-to-fill variations together with shrinkage due to synchrotron radiation. Stability is recovered for 1.2~ns long bunches in single RF or in double for 1.0 ns with 4 MV at 800 MHz. Possible uncertainties due to increased HL-LHC impedance and coupled-bunch instabilities. Beam lifetime is reduced for bunch length more than 1.5 ns (in the 400 MHz RF): → narrow operational window (1.2 - 1.5) ns New operation regime with long (> 1.7 ns) bunches in 200 MHz (+ 400 MHz) RF system has many advantages (e-cloud…) Double RF system should make controlled emittance blow-up during ramp more reliable

SPARE SLIDES

Capture 200 MHz RF system: needs from the SPS

Impedance reduction of vacuum flanges: 72 bunches 2RF systems (1 MV @ 800 MHz) With 1.5 MV at 800 MHz the threshold increase is already sufficient, but margin is still small 24 b 2 RF 72 b 1.5 MV @800 MHz 1 MV @800 MHz 24 b 1 RF 72 b BLonD simulations A. Lasheen & J. Repond

Possible uncertainties Available voltage (very high RF power, main power couplers, LLRF: pulsing mode of operation) SPS impedance model still some impedance missing (synchrotron frequency shift)… Simulations Done for 1 batch of 72 bunches on the flat top Stability during ramp (work in progress) Don’t include longitudinal damper, phase loop, phase error,…

Nominal injected emittance & BUP: RF power for longer cycle and Q22

Summary - SPS From the RF point of view we should be able to obtain HL-LHC parameters after the 200 MHz RF upgrade and LIU baseline longitudinal impedance reduction We rely on simulations and it is difficult to take into account all possible uncertainties Extra margins can come from bunch rotation on the SPS flat top 5% longer bunches at injection into the LHC 200 MHz RF system in the LHC Further longitudinal emittance increase in the SPS is limited by beam loading in the 200 MHz RF during ramp