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Beam stability in the SPL - Proton Driver accumulator for a Neutrino Factory at CERN. E.Benedetto (CERN) 21/7/09. NUFACT’09 Workshop, 20-25 July ‘09. Beam stability in the SPL Proton Driver accumulator for a n -Factory at CERN. Introduction & motivations
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Beam stability in the SPL - Proton Driver accumulator for a Neutrino Factory at CERN E.Benedetto (CERN) 21/7/09 NUFACT’09 Workshop, 20-25 July ‘09
Beam stability in the SPL Proton Driver accumulator for a n -Factory at CERN • Introduction & motivations • Stability for the 6-bunches option • Simulations & analytical considerations • Resistive-wall • Broad-band impedance • Electron cloud • Longitudinal (BB-impedance) • 3-bunches option • Preliminary considerations • Conclusions Acknowledgements:M. Aiba, R. Garoby, M. Martini, E. Metral, G. Rumolo,... Beam stability in the SPL Proton Driver accumulator for a…
Intro: CERN SPL-Proton Driver • Separate accumulator & compressor rings: • to adapt the SPL time structure to the target • 4 MW proton beam @ 5 GeV, from HP-SPL → R. Garoby, NuFact’06 • 6-bunches design meets the 3rd ISS requirements → M. Aiba, Feasibility Study of Accumulator and Compressor for the 6-bunches SPL-based Proton Driver, CERN-AB-2008-060 BI (& NuFact’07) • 3/1-bunches scenario option → M.Aiba, CERN-AB-Note-2008-048 BI (& Poster @ NuFact’08) Beam stability in the SPL Proton Driver accumulator for a…
Intro: CERN SPL-Proton Driver • 6-bunches scenario (the CERN baseline) • Accumulator ring • Isochronous (h=0), no RF, ~400ms, beam frozen longitudinally to preserve Dp/p • 6 bunches, 120 ns total bunch length • Compressor ring • rapid phase rotation in ~36ms, strong RF, large slippage factor h • ~2ns rms bunch length @ extraction to the Target • Fast (t<400ms) instabilities may arise in accumulator • No synchrotron motion to stabilize • Collective effects studies aim at: • finding cures for instabilities • setting limits to the machine impedance Beam stability in the SPL Proton Driver accumulator for a…
Intro: Machine impedance • EM interactions of the beam with the environment → wake-fields(t) & impedances(w) • In the transverse plane: • Resistive wall(beam pipe finite resistivity) • Narrow-band resonators (RF cavities, cavity-like objects) • Broad-Band (BB) resonator (beam-pipe discontinuities) • Electron cloud • In the longitudinal plane: • Narrow-band resonators (RF cavities,…) • BB resonator(kickers & other discontin) • Mainly single-bunch (since neglecting narrow-band) • PESSIMISTIC analysis: • → assumed full intensity,while: • → accumulation (400 ms): intensity going from 0 →max Beam stability in the SPL Proton Driver accumulator for a…
Localized impedance source Intro: Machine impedance • Analytical estimations & simulations • HEADTAIL:macroparticles code • Impedance localized @ few positions • transfer matrix to the next one • Bunch sliced longitudinally • Each slice interacts w. impedance: • leaves a wake-field behind • gets a kick → G.Rumolo, F.Zimmermann, CERN-SL-Note-2002-036-AP → D.Quatraro, G.Rumolo et al.,Proceedings PAC’09 Beam stability in the SPL Proton Driver accumulator for a…
6-bunches Accumulator parameters • Parameters designed to match: • SPL incoming beam • Compressor requirements • for time-structure @ target → M. Aiba, CERN-AB-2008-060 BI Transverse emittance (not normalized) 3 p mm mrad: → beam size @ target → space-charge → injection foil heating Bunch length 120ns & energy spread5 MeV → structure @ target - Flat bunch with smooth edges → longitud SC Beam stability in the SPL Proton Driver accumulator for a…
bunch spectrum of mode m Re(Z) m=0 m=2 m=1 Resistive wall transverse impedance • In the “classical” regime: • Complex modes frequency shift: • Instability rise-time: • Mode m=0 is unstable, butt = 8.2 ms>> 400 ms • Simulations w. HEADTAIL confirm Beam stability in the SPL Proton Driver accumulator for a…
Electron cloud • e- trapped in the bunch may contribute to instabilities • “Long bunch” regime: many e- oscillations in a bunch • e- released at the bunch tail (“trailing-edge” multipacting) can extract secondaries form the wall. • Dependence on: • SEY →Surfaces coating/conditioning (studies @ CERN for LHC injectors upgrade) • Longitudinal bunch profile:→Truncated tails orflat is good! • gap between bunches, intensity, transverse shape, … e-cloud should not to be an issue Beam stability in the SPL Proton Driver accumulator for a…
Broad-band transverse impedance • No synchrotron motion → cfr. Beam Break Up • Can be cured by introducing some tune spread: • Chromaticity • Detuning w. amplitude (octupoles) • BB parameters: • Rt = 1 MW /m • QR = 1 • fR ~ c/(2pb) ~ 1GHz <x Nz> z Beam stability in the SPL Proton Driver accumulator for a…
t~28ms Broad-band transverse impedance • Cured by chromaticity Horiz. Beam size vs. # turns, for different chromaticities Q’x=6, -6 Q’x=0 Q’x=8, -8 sx (m) Q’x=10, -10 Q’nat,x= - 8.4 • Positive/negative values of Q’ are OK (h=0) • Needed chromaticity |Q’| > 10 → DQrms ~ 0.01 for (dp/p)rms~10-3 Beam stability in the SPL Proton Driver accumulator for a…
Rt -wR wR -Rt BB analytical estimation DQ • Coasting beam formula w. peak values Re (Z) Im (Z) w*~ wR the most critical one I0 = e Nb/tb 1GHz >> 1/120ns ~ 9 ms • Approx. stability criterion: Dw > 2 |U-jV| → DQ > ~0.025 Beam stability in the SPL Proton Driver accumulator for a…
If Q’=0 → t~28ms / Z [MW/m] Q’th > 10 x Z [MW/m] Broad-band transverse impedance • Scan over impedance values (Rs=1,2,3 MW/m) Rs • Threshold proportional to Z t-1[ms] / Z [MW/m] • For a given Q’, risetime inversely prop. to Z Q’th / Z [MW/m] Beam stability in the SPL Proton Driver accumulator for a…
Broad-band transverse impedance • Cured with octupoles (detuning w. amplitude) • Beam size is growing, then saturation • Q’’xx~1200 (-2000 if negative polarity) needed to cure instability DQrms~0.006 (for sx~10 mm) Beam stability in the SPL Proton Driver accumulator for a…
Longitudinal BB impedance • Isochronous ring • No RF cavities → negligible Narrow-band impedance • Beam frozen longitudinal • BB impedance → microwave instability • If only h0 (=0) taken into account: • The threshold is zero • Risetime is • Need to consider second order momentum compaction = 0.117 (for Q’nat) =0 =0.0365 Beam stability in the SPL Proton Driver accumulator for a…
Longitudinal BB impedance • Scan over BB shunt impedance (QR=1, fR=1 GHz) Zl=10 kW Zl=8 kW Zl=6 kW Zl=5 kW Zl=4 kW Zl=3 kW • Zl < 4 kW → Zl/n < 4 W → OK! a few W easily achieved Beam stability in the SPL Proton Driver accumulator for a…
Nb twice as much Circumference ~ 1.7 x smaller # turns: ~1.6 more 3-bunches option • same bunch length, dp/p • similar emittance, Q, Q’nat Parameters for the 3-bunches accumulator it was b=20 Beam stability in the SPL Proton Driver accumulator for a…
3 bunches option: Transverse BB • Natural chromaticity can cure transverse BB • BB resonator: • 1MW/m • Q=1 • 1GHz Beam stability in the SPL Proton Driver accumulator for a…
3-bunches: Longitudinal BB • Scan over BB shunt impedance (QR=1, fR=1 GHz) 6 kW 5 kW 4 kW 3kW → (Zl/n)MAX~ 3.2 W Zl=2 kW OK! 1 kW 0.5 kW Beam stability in the SPL Proton Driver accumulator for a…
Conclusions (1/2) • Stability in the P-Driver accumulator → isochronous ring • The 6-bunch option is under control • Space Charge→ OK! it guided in definition of emittance & bunch length/shape in the design • Machine impedance: • narrow-band component →negligible (no RF-cavities) • resistive wall→not an issue (long risetime) • longitudinal BB→ Zl/n < 4 W + error-bar (fR) (~few Ohm easily achieved in modern machines) • transverse BB→ OK! fast rising instability cured by DQ (chromaticity (|x|~ 1.3) or octupoles) Beam stability in the SPL Proton Driver accumulator for a…
Conclusions (2/2) • transverse BB • need DQ ~ 0.02, → ok for tune footprint/ resonance • assumed Rt=1MW/m → Scaling laws with higher value of BB impedance • e-cloud→ not an issue (flat & long bunch → no multipacting) • 3-bunches option as well seems feasible Beam stability in the SPL Proton Driver accumulator for a…
R.Garoby, NuFact’06 Trev~1 ms Phase rotation: 36 turns Beam stability in the SPL Proton Driver accumulator for a…
Introduction:SPL-based proton driver (1) M.Aiba, NuFact’07 • SPL=Superconducting Proton Linac • SPL-based proton driver for neutrino factory • Design parameters has been determined to meet the summary of the 3rd ISS
SPL beam M.Aiba, poster NuFact’08 6- bunches 3- bunches