Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /221 TRANSVERSE INSTABILITIES E. Métral (CERN) Time (20 ns/div)  The purpose.

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Presentation transcript:

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /221 TRANSVERSE INSTABILITIES E. Métral (CERN) Time (20 ns/div)  The purpose of this course is to explain (theoretically) such pictures of “transverse (single-bunch) instability” Observation in the CERN PS in 1999 Observation in the CERN PSB in ~1974 (J. Gareyte and F. Sacherer) Following Laclare (and longitudinal)

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /222 SINGLE PARTICLE TRANSVERSE MOTION (1/3) uA purely linear synchrotron oscillation around the synchronous particle is assumed (with no coherent oscillations) uFor the transverse betatron oscillation, the equation of unperturbed motion, e.g. in the horizontal plane, is written as uThe horizontal betatron frequency is given by with Chromaticity

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /223 SINGLE PARTICLE TRANSVERSE MOTION (2/3) Horiz. chromatic frequency and

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /224 SINGLE PARTICLE TRANSVERSE MOTION (3/3) uIn the presence of electromagnetic fields induced by the beam, the equation of motion writes When following the particle along its trajectory uIn the absence of perturbation, the horizontal coordinate satisfies

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /225 SINGLE PARTICLE TRANSVERSE SIGNAL (1/2) uThe horizontal signal induced at a perfect PU electrode (infinite bandwidth) at angular position in the ring by the off-centered test particle is given by uDeveloping into exponential functions and using relations given in the longitudinal course, yields Complex conjugate

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /226 SINGLE PARTICLE TRANSVERSE SIGNAL (2/2) with uThe spectrum is a line spectrum at frequencies uAround every betatron line, there is an infinite number of synchrotron satellites m uThe spectral amplitude of the mth satellite is given by uThe spectrum is centered at the chromatic frequency

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /227 STATIONARY DISTRIBUTION (1/2) uIn the absence of perturbation, and are constants of the motion uTherefore, the stationary distribution is a function of the peak amplitudes only uNo correlation between horizontal and longitudinal planes is assumed and the stationary part is thus written as the product of 2 stationary distributions, one for the longitudinal phase space and one for the horizontal one

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /228 STATIONARY DISTRIBUTION (2/2) uSince on average, the beam center of mass is on axis, the horizontal signal induced by the stationary distribution is null

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /229 uIn order to get some dipolar fields, density perturbations that describe beam center-of-mass displacements along the bunch are assumed uThe mathematical form of the perturbations is suggested by the single- particle signal PERTURBATION DISTRIBUTION (1/3)  Low-intensity Coherent betatron frequency shift to be determined

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2210 PERTURBATION DISTRIBUTION (2/3) uIn the time domain, the horizontal signal takes the form (for a single value m) Fourier transform with

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2211 PERTURBATION DISTRIBUTION (3/3)  High-intensity

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2212 TRANSVERSE IMPEDANCE All the properties of the electromagnetic response of a given machine to a passing particle is gathered into the transverse impedance (complex function => in Ω / m)

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2213 EFFECT OF THE PERTURBATION (1/10) u Vlasov equation Linearized Vlasov equation

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2214 EFFECT OF THE PERTURBATION (2/10) uThe expression of can be drawn from the single-particle horizontal equation of motion

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2215 EFFECT OF THE PERTURBATION (3/10) uUsing the definition of the transverse impedance, the force can be written uDeveloping the into exponential functions, keeping then only the slowly varying term, making the approximation and using the relations and one from the longitudinal course, yields

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2216 EFFECT OF THE PERTURBATION (4/10) For each mode m, one has with Spectrum amplitude at frequency Multiplying both sides by and integrating over using the relation

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2217 EFFECT OF THE PERTURBATION (5/10) Averaged peak betatron amplitude uNote that the horizontal stationary distribution disappeared and only the longitudinal one remains => Only the beam center of mass is important (in our case). This should also be valid for the perturbation, which can be written Final form of the equation of coherent motion of a single bunch: Contribution from all the modes m

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2218 EFFECT OF THE PERTURBATION (6/10) with uCoherent modes of oscillation at low intensity (i.e. considering only a single mode m) Multiplying both sides by and integrating over

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2219 EFFECT OF THE PERTURBATION (7/10) uFollowing the same procedure as for the longitudinal plane, the horizontal coherent oscillations (over several turns) of a “water-bag” bunch interacting with a constant inductive impedance are shown in the next slides for the first head-tail modes (Note that the index x has been removed for clarity)

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2220 EFFECT OF THE PERTURBATION (8/10) DIPOLE QUADRUPOLE

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2221 EFFECT OF THE PERTURBATION (9/10)

Elias Métral, CERN Accelerator School, Darmstadt, Germany, October 3rd, 2009 /2222 EFFECT OF THE PERTURBATION (10/10) (Laclare’s) theory