STUDIES OF ENERGY RECOVERY LINACS AT ... - CASA

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[64] L. Merminga, Nucl. Instrum. Methods A 483, 107 (2002). [65] E. Pozdeyev, Phys. Rev. ST Accel. Beams 8, 054401 (2005). [66] E. Pozdeyev, Private communication (2005). [67] G. Krafft, J. Bisognano, and S. Laubach, unpublished. [68] B. Yunn, in Proceedings of the Particle Accelerator Conference, San Francisco, CA, 1991 (IEEE, Piscataway, NJ, 1991), pp. 1785–1787. [69] G. Hoffstaetter and I. Bazarov, Phys. Rev. ST Accel. Beams 7, 054401 (2004). [70] G. Krafft and J. Bisognano, in Proceedings of the Particle Accelerator Confer- ence, Washington, DC, 1987 (IEEE, Piscataway, NJ, 1987), pp. 1356–1358. [71] K. Beard, Technical Note 02-045, Jefferson Laboratory (2002). [72] B. Yunn, Phys. Rev. ST Accel. Beams 8, 104401 (2005). [73] K. Beard, Technical Note 02-044, Jefferson Laboratory (2002). [74] Z. Li, L. Ge, and K. Ko, Presentation at Collaboration Meeting of JLab-SLAC Computer Simulations on SRF Structures (2005). [75] H. Wang et al., in Proceedings of the Particle Accelerator Conference, Portland, OR, 2003 (IEEE, Piscataway, NJ, 2003), pp. 1104–1106. [76] I. Campisi and L. Merminga, Technical Note 98-011, Jefferson Laboratory (1998). [77] K. Jordan, Private communication (2004). [78] Herotek, Inc. (http://www.herotek.com/). 201

[79] L. Merminga et al., in Proceedings of the Particle Accelerator Conference, Chicago, IL, 2001 (IEEE, Piscataway, NJ, 2001), pp. 173–175. [80] A. Vetter, Ph.D. thesis, Stanford University (1980). [81] K. Mittag et al., Nucl. Instrum. Methods 76, 245 (1969). [82] D. Sagan and J. Smith, in Proceedings of the Particle Accelerator Conference, Knoxville, TN, 2005 (IEEE, Piscataway, NJ, 2005), pp. 4159–4161. [83] I. Bazarov and G. Hoffstaetter, in Proceedings of the European Particle Accel- erator Conference, Lucerne, Switzerland, 2004 (2004), pp. 2194–2196. [84] R. Rand and T. Smith, Part. Accel. 11, 1 (1980). [85] D. Douglas, in Proceedings of the Particle Accelerator Conference, San Fran- cisco, CA, 1991 (IEEE, Piscataway, NJ, 1991), pp. 449–451. [86] D. Douglas, Technical Note 04-017, Jefferson Laboratory (2004). [87] D. Douglas, Technical Note 04-016, Jefferson Laboratory (2004). [88] D. Douglas, Technical Note 04-025, Jefferson Laboratory (2004). [89] C. Tennant and E. Pozdeyev, Technical Note 04-020, Jefferson Laboratory (2004). [90] E. Pozdeyev, Talk presented at 32 nd Advanced ICFA Beam Dynamics Workshop on ERLs, Newport News, VA (2005). [91] G. Hoffstaetter, I. Bazarov, and C. Song, physics/0508089 (2006). [92] S. Benson, FEL FLOG 1345135 (2006). [93] D. Douglas, Technical Note 04-023, Jefferson Laboratory (2004). 202

Page 1 and 2: STUDIES OF ENERGY RECOVERY LINACS A

Page 3 and 4: DEDICATION To my wife Danielle and

Page 5 and 6: 2 CEBAF with Energy Recovery . . .

Page 7 and 8: 5.2 HOM Power . . . . . . . . . . .

Page 9 and 10: ACKNOWLEDGMENTS First and foremost

Page 11 and 12: 6.1 Summary of the measured effects

Page 13 and 14: 2.10 Illustration of quadrupole sca

Page 15 and 16: 5.1 Successive frames in time (prog

Page 17 and 18: 6.8 A plot of 1/Qeff versus average

Page 19 and 20: ABSTRACT An energy recovering linac

Page 21 and 22: CHAPTER 1 Introduction An increasin

Page 23 and 24: FIG. 1.1: Schematic of a generic li

Page 25 and 26: FIG. 1.2: A CEBAF 5-cell cavity wit

Page 27 and 28: The solution to Eq. (1.3) is U(t) =

Page 29 and 30: y reducing the impedance of HOMs, a

Page 31 and 32: Despite its success, this method of

Page 33 and 34: design parameters, most notably ach

Page 35 and 36: 1.4.2 Machine Optics The second cat

Page 37 and 38: analytic model elucidates many impo

Page 39 and 40: CHAPTER 2 CEBAF with Energy Recover

Page 41 and 42: FIG. 2.1: Energy versus average cur

Page 43 and 44: FIG. 2.3: Additional hardware insta

Page 45 and 46: FIG. 2.4: A picture of the energy r

Page 47 and 48: dipoles and beam diagnostics such a

Page 49 and 50: FIG. 2.7: Horizontal (red) and vert

Page 51 and 52: FIG. 2.8: Illustration of the cryom

Page 53 and 54: linac and θNL is the RF phase. The

Page 55 and 56: 2.4 Transverse Emittance One of the

Page 57 and 58: where σ2 is the rms beam size meas

Page 59 and 60: eams. The effects of varying the qu

Page 61 and 62: FIG. 2.12: A typical wire scan near

Page 63 and 64: quadratic fit and a multiple regres

Page 65 and 66: ting the data is difficult. Without

Page 67 and 68: primary source of error is measurin

Page 69 and 70: identified, although the phase dela

Page 71 and 72: TABLE 2.3: Comparison of Twiss para

Page 73 and 74: the results of the fits. The vertic

Page 75 and 76: FIG. 2.18: Schematic illustrating t

Page 77 and 78: FIG. 2.19: The GASK signal measured

Page 79 and 80: FIG. 2.20: The measured normalized

Page 81 and 82: CHAPTER 3 The Jefferson Laboratory

Page 83 and 84: FIG. 3.1: Schematic of the 10 kW FE

Page 85 and 86: FIG. 3.2: Layout of the DC photocat

Page 87 and 88: accelerating gradient at the front

Page 89 and 90: eason for making the endloops achro

Page 91 and 92: FIG. 3.7: Illustration of path leng

Page 93 and 94: 3.5 Longitudinal Dynamics This sect

Page 95 and 96: FIG. 3.9: The effect of a thin focu

Page 97 and 98: Under the constraint that each orde

Page 99 and 100: form of beam breakup not only occur

Page 101 and 102: 4.1 The Pillbox Cavity Although the

Page 103 and 104: FIG. 4.2: Electric field (red) and

Page 105 and 106: where the full 4×4 transfer matrix

Page 107 and 108: The threshold is inversely proporti

Page 109 and 110: 4.3 BBU Simulation Codes: Particle

Page 111 and 112: 6. The second pass beam bunch then

Page 113 and 114: which excites it. The BBU instabili

Page 115 and 116: Equation (4.41) is a dispersion rel

Page 117 and 118: FIG. 4.4: Output from MATBBU showin

Page 119 and 120: FIG. 4.5: Setup for measuring cavit

Page 121 and 122: Consequently, depending on the exte

Page 123 and 124: The projection of the beam displace

Page 125 and 126: TABLE 4.1: Experimental measurement

Page 127 and 128: FIG. 4.10: A plot showing the effec

Page 129 and 130: these cryomodules. Modes from these

Page 131 and 132: CHAPTER 5 Experimental Measurements

Page 133 and 134: threshold current - preferably with

Page 135 and 136: occurred at approximately 2 mA of a

Page 137 and 138: FIG. 5.5: FFT of a pure 2106.007 MH

Page 139 and 140: FIG. 5.6: Illustration to show the

Page 141 and 142: 5.4 Measuring the Threshold Current

Page 143 and 144: for the HOM-beam system and is deri

Page 145 and 146: FIG. 5.10: Schematic of the experim

Page 147 and 148: FIG. 5.12: A plot of 1/Qeff versus

Page 149 and 150: measured HOMs in zone 3, a BTF meas

Page 151 and 152: FIG. 5.16: HOM voltage measured fro

Page 153 and 154: FIG. 5.18: A plot of the three valu

Page 155 and 156: the beam’s response in regions wh

Page 157 and 158: CHAPTER 6 BBU Suppression: Beam Opt

Page 159 and 160: FIG. 6.1: Schematic of a FODO cell

Page 161 and 162: plane [85]. Equations (6.7) and (6.

Page 163 and 164: 6.2.3 Discussion The method of poin

Page 165 and 166: FIG. 6.3: Beam envelopes (horizonta

Page 167 and 168: FIG. 6.6: Beam position monitor rea

Page 169 and 170: FIG. 6.8: A plot of 1/Qeff versus a

Page 171 and 172: ⎛ ⎞ ⎜ ⎝ 0 0 0 0 0 −1/K 0

Page 173 and 174: FIG. 6.11: A plot of 1/Qeff versus

Page 175 and 176: FIG. 6.12: Threshold current for no

Page 177 and 178: FIG. 6.14: Threshold current utiliz

Page 179 and 180: TABLE 6.1: Summary of the measured

Page 181 and 182: CHAPTER 7 BBU Suppression: Feedback

Page 183 and 184: FIG. 7.1: A schematic of the feedba

Page 185 and 186: FIG. 7.4: A coaxial 3-stub tuner us

Page 187 and 188: All of these considerations are con

Page 189 and 190: FIG. 7.6: Generic layout for a feed

Page 191 and 192: in Section 4.2.1, however, in the p

Page 193 and 194: FIG. 7.7: The threshold current as

Page 195 and 196: FIG. 7.8: Threshold current versus

Page 197 and 198: FIG. 7.10: The threshold current as

Page 199 and 200: CHAPTER 8 Conclusions The work pres

Page 201 and 202: le were experimentally measured. Du

Page 203 and 204: APPENDIX A The Pillbox Cavity Start

Page 205 and 206: FIG. A.1: A pillbox cavity exhibiti

Page 207 and 208: Ez(ρ, φ) = ψ(ρ, φ) = E0Jm(γρ

Page 209 and 210: FIG. B.1: Relationship of the S-par

Page 211 and 212: FIG. C.1: Impedance and frequency o

Page 213 and 214: FIG. C.5: Impedance and frequency o

Page 215 and 216: BIBLIOGRAPHY [1] M. Tigner, Nuovo C

Page 217 and 218: [22] L. Merminga, in Proceedings of

Page 219: [50] C. Hernandez-Garcia et al., in

Page 223 and 224: VITA Christopher D. Tennant Christo

beam

threshold

cavity

linac

frequency

feedback

dipole

optics

quadrupole

horizontal

studies

linacs

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