Application of Frequency Map Analysis to Storage Rings in China

1. Application of Frequency Map Analysis to Storage Rings in China Jiao Yi Institute of High Energy Physics Chinese Academy of Sciences, Beijing, China

2. Outline • Shanghai Synchrotron Radiation Facility (SSRF) Super-periodic structural resonance (SSR) • Beijing Electron Positron Collider Upgrade Project (BEPCII) Synchro-betatron resonance • Beijing Advanced Photon Source (BAPS) Multi-objective genetic algorithms (MOGA) method

3. Frequency map analysis (FMA) Frequency map: SOLEIL, France SSRF, China Courtesy of L. Nadolski, SOLEIL 1/42

4. SSRF: A third generation light source Main parameters of SSRF storage ring Twiss parameters in one super-period Dominative resonance: 3Qx-2Qy = 44 2/42

5. Motion near the resonance 3Qx-2Qy=44 It is a Super-periodic Structural Resonance (SSR). For particle with different coordinates Tune vs. horizontal amplitude Tracking with AT. 3/42

6. Linear super-periodic structural resonances-I Linear magnetic field errors lead to first or second order super-periodic structural resonances. If Q is closed to stop band, the off momentum particle dynamics optimization will be difficult. Stopbands: Q = M N /2, M is the super-period No. Qx=22 Qx=23 Qx=24 v=Kd / kd0 Qy=12 Qy=11 Qy=10 Blue: horizontal Red：Vertical u=Kf / kf0 DK source: off-momentum particles (1+d) p0 Necktie diagram for SSRF Black star: nominal working point (22.22, 11.32) 4/42

7. Linear super-periodic structural resonances-II For modern acclerators with complex lattice structure, necktie diagram still works well. Some integer or half integer resonance exhibits as “stopband” in Kf - Kdspace, implying stronger effect than others. “…The formation of the structural resonance stopband comes from the harmonic number of the super-periodic resonance in the lattice configuration. …” Courtesy ofS.X. Fang and Q. Qin, HEP & NP 30(9) 880 The first and second order super-periodic structural resonance (SSR) is M is super-period number of the lattice. The resonance is first order when l is even and second order when l is odd. How about higher order resonances with the same harmonics as the linear SSR? For SSRF, the resonance 3Qx-2Qy = 44 has the same harmonic with the 2Qx = 44 second order SSR stop band How about nonlinear magnetic fields (sextupoles, most strong nonlinear components in light source)? 5/42

8. Linear SSR by sextupoles Ideal SSRF lattice, with sextupoles as the only one nonlinear source. (22.04, 11.24) (23.04, 11.24) Qx =22 is second order SSR, Qx =23 is not linear SSR. 6/42

9. B C A Sextupoles & SSR 11.36 Coutesy of S.Q. Tian, SSRF A, B (~0.1): 2Qx = 44 C(~0.04) : 3Qx- 2Qy = 44 On-momentum DA vs. Qx off-momentum DA vs. Qx 7/42

10. Higher order SSR vs. Working point Five work points, (22.12, 11.17), (22.16, 11.23), (22.22, 11.32), (22.26, 11.38) and (22.32, 11.47) along the resonance 3Qx- 2Qy = 44. 8/42

11. Pruple-(22.12,11.17) black-(22.16,11.23)A Yellow-(22.16,11.23)B Red -(22.22,11.32) Green- (22.26,11.38) Blue- (22.32,11.44) Higher order SSR vs. Working point (cont.) Identify resonance with FMA 1, Average diffusion rate (resonance strength) 2, Resonance location in (x, y) space 3, Resonance-trapped particle NO. Lie Method calculation (LieMath) for contrast 1, Resonance amplitude term 2, Resonance location 9/42

12. Higher order SSR vs. Working point (cont.) Resonance location comparison W.P. further away from the SSR stopband 2Qx = 44, Resonance strength becomes weaker ((22.16, 11.23)A is an exception, with low tune diffusion while much more particles are trapped into the resonance). Resonance strength comparison W.P. further away from the SSR stopband 2Qx = 44, Resonance affects the particle with larger initial amplitudes. 10/42

13. Higher order SSR & tune optimization If the lattice is Mperiodic, i.e., composed of M identical sectors (this is the case for a perfect machine), the first and second order SSR is The resonance is first order when l is even and second order when l is odd. If the working point near the first or second order SSR stopband and the nearby structural resonance satisfies SSR diagram near the SSRF W.P. Namely, the harmonic number of the resonance is the multiple of both M and RQ, the resonance will be HOSSR. SSR is structural resonance with specific harmonic number, even with high order, it can have relatively large effects on beam dynamics. Y. Jiao, S.X. Fang, “High Order Super-periodic Structural resonance”, EPAC08 11/42

14. Application of higher order SSR, SOLEIL e d f c Super-period No. = 4 SSR stopband nearby W.P.： Qy = 8, 2Qx = 36 HOSSR nearby W.P.: a. 7Qx =16×8; b. 5Qx + 2Qy = 3×36; c. 3Qx + 4Qy=11×8; d. 3Qx + 3Qy=10×8; e. -Qx + 6Qy=4×8; f. 4Qx - 3Qy=6×8 b a SSR diagram nearby the W. P. Frequency maps in the following slides, mostly come from paper: L. Nadolski and J. Laskar, Review of single particle dynamics for third generation light sources through frequency map analysis, Phys. Rev. ST AB 6, 114801 (2003) 12/42

15. Application of higher order SSR, SOLEIL (cont.) Modify the sextupoles strength to fold the frequency map thus avoid 5Qx+ 2Qy = 3×36。 The 7th-order coupling resoance, 5vx + 2vy- 4×27=0, reached for the horizontal amplitude x =24mm. Courtesy of L. Nadolski, SOLEIL 13/42

16. New W.P. (18.30, 8.38) Application of higher order SSR, SOLEIL (cont.) Move W. P. right to avoid 7Qx= 16×8。 …the new working pint is (vx, vy) = (18.30, 8.38), in order that the horizontal tune never cross the 7th-order resonance 7vx - 4×32=0… Courtesy of L. Nadolski, SOLEIL 14/42

17. On-momentum particle can cross the integer resonance Qx = 36 without loss. Application of higher order SSR, ESRF ESRF Super-period No.=16，W.P. = (36.44，14.39), far away from first or second order SSR stopband. Courtesy of L. Nadolski, SOLEIL 15/42

18. Application of higher order SSR, ALS Circumference = 196m，super-period No. = 12，W.P. = (14.25，8.18), far away from SSRs. On-momentum particle can cross the integer resonanceQy = 8 without loss. Courtesy of L. Nadolski, SOLEIL 16/42

19. Application of higher order SSR, Super-ACO Circumference = 72m，super-period NO.=4，W.P.=（4.72，1.70）, close to SSR stopband The dominative resonance Qx + 2Qy = 4×2 is a third order HOSSR. …Globally the beam dynamics is mainly dominated by this coupoled resonance vx + 2vy -2×4=0. In its vicinity, a particle repidly escapes to unbonded motions… Courtesy of L. Nadolski, SOLEIL 17/42

20. BEPCII: a high luminosity double-ring collider e+ e 18/42

21. BEPCII high luminosity mode lattice Qx near 0.5 provides the highest luminosity Coutesy of Dr. Y. Zhang Twiss functions and main parameters along the ring 19/42

22. FMA on the high luminosity mode RF and radiation are turned on while tracking. Dp / p=0 Dp / p= -0.6% Dp / p= 0.6% On- and off-momentum DAs 20/42

23. FMA on the high luminosity mode (cont.) The off-momentum FMs are not folded as the on-momentum case and the tune footprints cover the rangeQx (6.514, 6.516)with a high diffusion rate or even particle loss. Synchro-betatron resonance: 2Qx- Qs= 13 Off-momentum FM 1, Reduce the anharmonic terms (dQx/dx2, dQx/dy2, dQy/dy2) from(73, 77, 208) to (70, 68, 198) . 2, Reduce the effect of the synchro-betatron resonance On-momentum FM The growth time of the resonance 2Qx - Qs = 13 is: H along the whole ring is calculated and minimized by fine-tuning all the sextupole strengths. For example, we reduce the H from 19.7 to 3.1 for d = 0.3%. The FMs with Dp /p =0, ±0.6% together 21/42

24. Optimizing the high luminosity mode before optimization The increase of size of DA with errors tracking with SAD Reduce anharmonicity Minimize the growth time of resonance Solid line square: collision DA requirement Dashed line square: injection DA requirement 22/42

25. Resonance confirmed in commissioning Luminosity scan in tune space, 8th May, 2009. Electron ring Positron ring Qy Qy Qx Qx Luminosity falls down in tune range Qx (6.515, 6.520) Beam lost when Qx is nearby 6.515 23/42

26. Beijing Advanced Photon Source (BAPS) A third generation light source, Energy: 5Gev, Circumference: ~1200m, Low emittance: ~1nm PEP-X BAPS PEP-X 24/42

27. Beijing Advanced Photon Source (BAPS) Twiss functions through one super-period of Storage ring W.P.: (64.28, 29.20) Phase advance per cell: (1.307, 0.588) Natural chromaticity per cell: (-5.54, -1.31) 25/42

28. BAPS sextupoles arrangement Two groups of chromaticity correction sextupoles (SD/SF) Seven groups of harmonic correction sextupoles (SYF/SZF/SWD/SZD/SXD/SXF/SYD) SYF SWD SD SD SXD SYD SZF SZD SF SXF 26/42

29. BAPS—Dynamics with no harmonic sextupoles Large DQ/Dp/p0 ~0.5 Large DQ/Jx,y Small DA for all Dp/p0 W.P. 64.28, 29.20 27/42

30. BAPS—OPA optimization OPA code based on Hamilton resonance theroy DA still small DQx nonlinear increase with Jx DQx with Dp/p still large W.P. 64.35, 29.20 28/42

31. BAPS—MOGA optimization Multi-objective genetic algorithms Seven Variables: harmonic sextupole strength Aim value: larger DA size and smaller tune variation over dp/p~(-0.03, 0.03) Initial random seeds (104) Calculate aim value Choose the best ones Selection, crossing, mutation New generation New random seeds W.P. 64.28, 29.20 The final best result(s) D. Robin et al, PRSTAB, 11, 024002 (2008) 29/42

32. BAPS—three approaches comparison Can we find a lattice with small emittance and relatively small natural chromaticity at the same time? How can we make sure the lattice we find is the best one? 30/42

33. BAPS—linear optics scanning with MOGA D1 D2 D3 D4 D5 D6 D5 D4 D3 D2 D1 QM5 QM5 QM4 QM1 QM2 QM4 QM3 QM2 QM3 QM1 B B D0 +DM(3.2m) DM(3.2m)+D0 Twelve Variables: Drift lengths, quadrupole gradients Attention: Phase advance per cell Natural chromaticity per cell Circumference Emittance Twiss function at the middle of the straight section and the entrance of the dipole Limitions: Structure: 48 standard DBA cells Straight section length: not small than 6.4m Circumference: not larger than 1180m 3.2m>bx/by at the center of the straight section>1.5m 31/42

34. Stable solution-generation I 32/42

35. Stable solution-generation II 33/42

36. Stable solution-generation III 34/42

37. Stable solution-generation IV Most stable solutions exist in range of Qx~ (0, 1.5) per cell. With the Qx per cell changes from 0 to 1.5, the available low emittance decreases, and the available small natural chromaticity increases, as we expected. 35/42

38. Stable solution-detail information Emittance 1.0nm, Qx, min ~0.9, xx ~ (0.7, 2.0) per cell 36/42

39. Stable solutions fulfilling achromatic conditions Achromatic conditions: Dx=Dx’=0 at the entrance of dipole (numerically smaller than 0.01) Solutions fulfilling achomatic condition exist only in Qx ~(0.9,1.5) 37/42

40. Dx, |Dx’|<10-4 Dx, |Dx’|<0.01 Dx, |Dx’|<0.01 Dx,|Dx’|<10-4 Stable solutions fulfilling achromatic conditions II When achromatic conditions are satisfied for DBA cells, L: dipole length; r: bending radius; a0, b0: beta functions at the entrance of the dipole; g: energy factor; Cq=3.8319×10-13m For e=1.2, MOGA vs. theoretical calculation 41/42

41. Stable solutions fulfilling achromatic conditions III If e<2nm, Qx>1.2, xx>2.65 per cell Dx=Dx’=0 at the entrance of dipole (numerically smaller than 10-4) 38/42

42. Stable solutions fulfilling achromatic conditions IV 2 nm is a turning point. Above 2 nm, emittance changes a lot, the corresponding available small chromaticity changes a little. Below 2 nm, with emttiance decreases a little, the corresponding available small chromaticity increases very quickly. Dx=Dx’=0 at the entrance of dipole smaller than 10-4。 Emittance vs. xx per cell 39/42

43. Stable solutions fulfilling achromatic conditions V With 48 achromatic DBA cells, it is hard to reach 1nm with natural chromaticity smaller than 5.5. To reach e~1.3nm, the available small xx is about 4.5, the available small circumference is about 1120m. Emittance vs. circumference for specific xx 40/42

44. Stable solutions fulfilling achromatic conditions VI Lattice based on MOGA linear optics scanning Super-period No. is 4. The circumference is 1186.7m. The tune per cell is (1.326, 0.628). The natural chromaticity per cell is (-4.5, -1.63); The emittance is 1.33nm. Half matching + half standard cell 42/42

45. Frequency map analysis is very helpful in nonlinear optimization. Super-periodic structural resonances have non-negligible effects on beam dynamics for the third generation light sources. Synchro-betatron resonance is an important source of dynamic aperture limitation for the BEPCII colliding mode lattice. FMA together with MOGA show large potential in design and optimization of light source nowadays. Summary

46. Thanks for your attention!

47. Additional slides

48. First and second order SSR mechanism If too closed to the stopband, the particle amplitude will increase quickly, finally lost Tune is closed to stopband Chromaticity correction Effective range will be small, for a little dp/p, tune may change a lot, cause asymmetry of dynamic aperture (DA)for different dp/p. Beta function variation rate will be large The nonlinear correction effective range may be small, thus possibly bad results for nonzero momentum DA。 Particles with different momentum will “experience” different optics, the natural chromaticity will be different too

49. Experimental evidence for SSRs ? Two best experimental machines: SSRF,does not start FMA experiments till now SOLEIL,design changed. W.P. from (18.28, 8.38) to (18.2, 10.3) The W.P. just locates on the SSR resonance SSR diagram nearby the SOLEIL W.P.

50. Experimental evidence for SSRs ? The SSR resonance’s effect is obvious, but the resonance is not very strong. W. P.：（18.2，10.3）(18.2，10.305)