The SPL [1] working group at CERN is studying a 2.2 GeV H- linac, which recuperates a large amount of RF hardware from the now decommissioned LEP at CERN. During the ongoing design effort for an optimized layout, it was found that in some cases non-equipartitioned beams tend to exchange energy between the longitudinal and the transverse planes. Strict energy equipartition, however, imposes tight restrictions on such a high energy linac and often contradicts the goal of cost effective design. On the other hand, stability charts derived from 2D Vlasov analysis suggest the existence of stable non-equipartitioned equilibria in certain regions of parameter space. Due to the low bunch current (22 mA) in the SPL, these regions are large enough to ensure stable machine operation for non-equipartitioned beams. Systematic multiparticle simulations with IMPACT [2] are used to apply the stability charts to the beam dynamics design of a realistic high energy linac. Using the example of the SPL, it is shown that designs with stable non-equipartitioned bunches are feasible, and how these designs react to mismatched input beams

Gerigk, F

Hofmann, I

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Beam dynamics of non-equipartitioned beams in the case of the SPL project at CERN

BEAM DYNAMICS OF NON-EQUIPARTITIONED BEAMS IN THE CASEOF THE SPL PROJECT AT CERNFrank Gerigk, CERN, Geneva, SwitzerlandIngo Hofmann, GSI Darmstadt, GermanyAbstractThe SPL [1] working group at CERN is studying a 2.2GeV H– linac, which recuperates a large amount of RFhardware from the now decommissioned LEP at CERN.During the ongoing design effort for an optimized layout,it was found that in some cases non-equipartitioned beamstend to exchange energy between the longitudinal and thetransverse planes. Strict energy equipartition, however, im-poses tight restrictions on such a high energy linac and of-ten contradicts the goal of cost effective design. On theother hand, stability charts derived from 2D Vlasov analy-sis suggest the existence of stable non-equipartitioned equi-libria in certain regions of parameter space. Due to thelow bunch current (22 mA) in the SPL, these regions arelarge enough to ensure stable machine operation for non-equipartitioned beams. Systematic multiparticle simula-tions with IMPACT [2] are used to apply the stability chartsto the beam dynamics design of a realistic high energylinac. Using the example of the SPL, it is shown that de-signs with stable non-equipartitioned bunches are feasible,and how these designs react to mismatched input beams.1 INTRODUCTIONSince the emittance exchange in unstable areas of thestability charts developed by Hofmann [3], [4] has alreadybeen demonstrated for idealized cases, the goal of thisstudy is to establish the validity of the charts for a realis-tic linac set-up, using a periodic focusing structure and 3Dbunched beams. For this purpose the first two supercon-ducting sections of the SPL [5] were chosen to benchmarkdifferent areas in the parameter space of the charts. Thesesections include a transition with a change of period length,as well as phase slippage in the multicell cavities, a phe-nomenon occurring in all present designs of superconduct-ing linacs. Both sections consist of 4-cell cavities, designedfor the particle velocities of β = 0.52 and β = 0.7.2 SIMULATIONSAll simulations use approximately twice the design cur-rent (40mA) of the actual layout (Table 1) and start withan initial 6D Waterbag distribution. Four realistic caseswere simulated to explore the parameter space on the sta-bility chart, which was calculated for the SPL emittanceratio of εl/εt ≈ 2 (Fig.1). The chart indicates regions(in grey) where third and fourth order modes of collec-tive space charge density oscillations are expected to causeemittance transfer. It is noted that the dangerous regionsTable 1: Main layout parameters of simulated structureParticles H−Injection energy 120 MeVTransition energy betweenβ = 0.52 and β = 0.7 236 MeVOutput energy 383 MeVNo. of focusing periods 22RF frequency 352.2 MHzMax. bunch current 22 (40)* mAεt,r.m.s.,norm. 0.4 π mm mradεl,r.m.s. 0.755 π mm mradhave a resonance structure, with a predominant resonancearound tune ratio 1, which is caused by a fourth order mode(corresponding to a relationship 2σ l − 2σt ≈ 0 in a singleparticle picture).0.20.40.60.80.20.40.60.80.5 1.0 1.5 2.0emittance ratio=20,010,030,050,070,090,110,130,150,170,190,210,23transv.tune depressionσ /σz xcase 1case 2case 3SPLequipartitioned beamFigure 1: Stability chart for SPL nominal emittance ratiowith set-ups for different simulations (120 MeV- 383 MeV). Regions are shown, where theorypredicts emittance exchange (grey scales indicatetheoretical growth rates of resonances in termsof transverse betatron periods; stability occurs inwhite regions).All four cases use the same longitudinal settings, butdifferent quadrupole adjustments. The phase advance inall three planes always remains below 90o, with maximumvalues for the SPL case (σt0 < 80o) and minimum valuesfor case 1 (σt0 > 36o).A modified version of the envelope code FIX3D [6] isused to fit the quadrupole settings for the desired ratios ofthe matched full current tunes. Cases 1 and 2 are fitted forconstant ratios of 1.6 and 1.1, while case 3 and the SPLscan along a line in the chart. Due to the matching between0-7803-7191-7/01/$10.00 ©2001 IEEE. 2872Proceedings of the 2001 Particle Accelerator Conference, Chicagothe sections, there are three points per case outside these ra-tios. Table 2 lists the main characteristics of the four casesand Fig. 2 depicts the simulation results for a matched inputbeam.Table 2: Boundaries of the four casescase 1 case 2 case 3 SPLσt0 37o − 52o 45o − 65o 45o − 62o 55o − 79oσl0 45o − 62o 44o − 62o 42o − 62o 42o − 62oσt/σt0 .58 − .61 .64 − .67 .63 − .68 .68 − .72σl/σl0 .77 − .78 .73 − .75 .72 − .75 .68 − .72anisotr.* 2.7 − 3.1 2.1 − 2.4 2.3 − 1.7 1.6 − 1.3* anisotropy defined as :(σl ·εl)/(σt ·εt)0.350.40.450.50.550.60.650.70.750.8[pi mm mrad]case 10.350.40.450.50.550.60.650.70.750.8[pi mm mrad]case 20.350.40.450.50.550.60.650.70.750.8[pi mm mrad]case 30.350.40.450.50.550.60.650.70.750.80 50 100 150 200[pi mm mrad]length [m]SPLFigure 2: R.m.s. emittance evolution (upper curves: longi-tudinal, lower curves: transverse)Case 1, which has the highest anisotropy ratio (3.1) be-tween the longitudinal and the transverse plane, and theSPL show a practically constant emittance evolution (seealso Table 2) while in cases 2 and 3 a clear energy ex-change between the longitudinal and the transverse planecan be observed. This exchange involves: 1.) a rise ofthe matched tunes in the transverse plane and a decrease inthe longitudinal plane, meaning that the beam moves out ofthe unstable region towards equipartitioning; 2.) a reducedemittance ratio and therefore a changing chart topology, re-sulting in a shrinking size of the unstable area and again amove towards equipartitioning; and3.) due to the changing r.m.s. emittances the beam becomesmismatched. The changing tune and emittance ratios arenot included in Fig.1.Since the coupling resonances are induced by spacecharge one expects that the outermost particles react differ-ently to the core particles. Simulations with 106 particles11.11.21.31.41.51.61.7transverse emittance evolution0.70.750.80.850.90.9511.051.11.151.20 20 40 60 80 100 120 140 160 180 200length [m]longitudinal emittance evolutionFigure 3: Evolution of fractional normalized emittances forcase 2 in ascending order: r.m.s., 99%, 99.9%,and 99.99%on a 1283 space charge grid show that in case of r.m.s. emit-tance reduction (here in the longitudinal plane, lower partof Fig. 3) the outer 0.1% fraction of the particles are hardlyinfluenced by the changing core distribution, whereas the99% emittance is still considerably reduced. In case ofemittance growth (here in the transverse plane, upper partof Fig. 3) the outer particles first show a delayed reaction tothe expanding core but then experience twice the growth ofthe r.m.s. emittance. These results indicate a clear migra-tion of particles into a diffused beam halo due to the emit-tance exchange via space charge resonances, a process thatshould at all costs be avoided in the design of high intensitylinacs. However, a fast transition of an unstable area mightbe possible with only moderate emittance degradation.Table 3: Relative emittance growth for matched in-put beams at the end of the simulated linac(383 MeV)case εt,r.m.s. εl,r.m.s. εt,99.99% εl,99.99%SPL 1.01/1.01 .994 1.16/1.20 1.111 1.02/1.02 .986 1.23/1.20 1.082 1.24/1.23 .759 1.63/1.62 1.133 1.20/1.20 .793 1.45/1.43 1.082873Proceedings of the 2001 Particle Accelerator Conference, Chicago3 MISMATCH STUDYTo study the effect of mismatched input beams for dif-ferent lattices we follow the approach suggested in [7]. Weexcite the three envelope modes of mismatched bunchedbeams (related to the Quadrupolar-, High-frequency, andLow-frequency mode, though we are not rigorously ex-citing the eigenmodes) so that the largest oscillation hasa relative amplitude of 1.3 corresponding to a 30% mis-match. Fig. 4 shows the ratio between the mismatched and0.60.70.80.911.11.21.31.40 20 40 60 80 100 120 140 160 180 200length [m]dax/ax day/ay db/bFigure 4: Ratio between the mismatched and matchedr.m.s. radii in case of a 30% High-frequencymode excitation for case 1the matched r.m.s. radii for case 1. Here the longitudi-nal oscillation has the largest amplitude and is set to 1.3.The anti-phased transverse oscillations have an amplitudeof 1.1.Table 4: Relative emittance growth for mismatched inputbeams (120 MeV - 383 MeV)case/mode εt,r.m.s. εl,r.m.s. εt,99.99% εl,99.99%SPL/Q 1.11/1.09 .997 4.68/3.97 1.101/Q 1.08/1.04 .988 3.85/2.38 1.092/Q 1.27/1.27 .799 3.51/3.30 .9923/Q 1.23/1.25 .837 3.67/3.43 .993SPL/L 1.01/1.01 1.01 1.21/1.18 2.581/L 1.02/1.02 .990 1.38/1.23 1.152/L 1.24/1.21 .835 1.94/1.83 3.263/L 1.19/1.19 .894 2.12/1.86 3.46SPL/H 1.03/1.02 .994 1.92/1.28 1.101/H 1.01/1.01 .993 1.20/1.18 1.222/H 1.26/1.20 .787 2.54/1.47 1.093/H 1.20/1.20 .805 1.45/1.42 1.16Case 1 can be considered as an alternative layout to theSPL, since it is the only one that does not exchange emit-tances in the matched case. Comparing the sensitivity tomismatch mode excitation, the SPL emittance growth ratesseem to be slightly higher than for case 1. However, goingto higher energies, case 1 would have to cross the fourthorder instability due to the decreasing longitudinal phaseadvance. Since the transverse focusing for case 1 is weakerthan for the SPL, the transverse matched beam radius issmaller in the SPL lattice (this still applies for mismatchedinput beams). Therefore the SPL lattice was chosen as thereference layout for the project. Cases 2 and 3 still show aclear r.m.s. emittance exchange, indicating that the processof energy exchange between the planes is not sensitive tomismatch. All cases show distinctly increased halo produc-tion for mismatched input beams.4 CONCLUSIONSA good agreement has been established between the pre-diction of unstable areas derived from 2D Vlasov analysis,and fully 3D PIC simulations of realistic designs. Beams inunstable areas of the theoretical Stability Charts show dis-tinct emittance exchange in spite of the relatively low tunedepression of ≈ 0.7. Due to the exchange, these beamsmove towards stable areas in the charts in the directionof equipartitioning. It has also been demonstrated that thenon-equipartitioned equilibria predicted by the charts exist(see also [8], [9]) and that, in case of the SPL layout, theseequilibria do not show distinctly higher or lower sensitivityto mismatched input beams. The energy exchange for mis-matched beams is of the same order as for matched beams,although the values get blurred by an overall tendency foremittance growth and halo formation. In the design of highintensity linacs, the unstable areas should be avoided dueto the development of beam halo during energy exchange.However, the option of a fast transition of unstable areasshould be a subject for further studies.5 ACKNOWLEDGEMENTSThis research used resources of the National Energy Re-search Scientific Computing Center.6 REFERENCES[1] Ed. M. Vretenar. Conceptual Design of the SPL, a High-Power Superconducting H-Linac at CERN, CERN 2000-012.[2] J. Qiang; R.D. Ryne; S. Habib; V. Decyk. An Object-Oriented Parallel Particle-In-Cell Code for Beam DynamicsSimulation in Linear Accelerators. Journal of ComputationalPhysics, 163:1–18, 2000.[3] I. Hofmann. Stability of Anisotropic Beams with SpaceCharge. In Physical Review E 57, 4713, 1998.[4] I. Hofmann; J. Qiang; R.D. Ryne. Collective ResonanceModel of Energy Exchange in 3D Non-EquipartitionedBeams. Phys.Rev.Lett. 86,accepted, 2001.[5] F. Gerigk; M. Vretenar; R.D. Ryne. this conference.[6] R.D. Ryne. Finding Matched RMS Envelopes in RF Linacs:A Hamiltionian Approach, LA-UR-95-391. LANL, LosAlamos, NM 87545, 1995.[7] A. Letchford; K. Bongardt; M. Pabst. Halo Formation ofBunched Beams in Periodic Focusing Systems. In Proc. PAC1999, page 1767, New York.[8] K. Bongardt; M. Pabst; A. Letchford. High Intensity InjectorLinacs for Spallation Sources. In Proc. LINAC 98, page 339.[9] J-M. Lagniel; S. Nath. On Energy Equipartition Induced bySpace Charge in Bunched Beams. In Proceedings of EPAC98, page 1118.2874Proceedings of the 2001 Particle Accelerator Conference, Chicago

Beam Dynamics of Non-Equipartitioned Beams in the Case of the SPL Project at CERN

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