Phase mixing of transverse oscillations in the linear and nonlinear regimes for IFR relativistic electron beam propagation
Abstract
Phase mixing of transverse oscillations changes the nature of the ion hose instability from an absolute to a convective instability. The stronger the phase mixing, the faster an electron beam reaches equilibrium with the guiding ion channel. This is important for long distance propagation of relativistic electron beams where it is desired that transverse oscillations phase mix within a few betatron wavelengths of injection and subsequently an equilibrium is reached with no further beam emittance growth. In the linear regime phase mixing is well understood and results in asymptotic decay of transverse oscillations as 1/Z(exp 2) for a Gaussian beam and channel system, Z being the axial distance measured in betatron wavelengths. In the nonlinear regime (which is likely mode of propagation for long pulse beams) results of the spread mass model indicate that phase mixing is considerably weaker than in the regime. In this paper we consider this problem of phase mixing in the nonlinear regime. Results of the spread mass model will be shown along with a simple analysis of phase mixing for multiple oscillator models. Particle simulations also indicate that phase mixing is weaker in nonlinear regime than in the linear regime. These results will also be shown.
- Publication:
-
Presented at the Charged Particle Beam Conference
- Pub Date:
- 1991
- Bibcode:
- 1991cpb..confR..25S
- Keywords:
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- Emittance;
- Mixing;
- Nonlinear Systems;
- Plasmas (Physics);
- Relativistic Electron Beams;
- Transverse Oscillation;
- Frequencies;
- Nonlinearity;
- Simulation;
- Nuclear and High-Energy Physics