A Review of High-Gain Free-Electron Laser Theory
Abstract
:1. Basic Concepts
1.1. FEL Spontaneous Emission
- (i)
- The intensity is proportional to the electrons’ current, i.e., the radiation is incoherent ( where is the number of electrons).
- (ii)
- The emitted radiation is confined in a narrow cone along the direction of electrons motion (that will be identify with the z-axis) within an angle of order of .
- (iii)
- It is a narrow-band radiation, with on-axis spectral distributionThe radiation line-width, from Equation (3), isThe above result can be easily understood in the (average) longitudinal electron rest frame: here each electron “sees” an -periods undulator magnetic field as an -periods counter-propagating pseudo-radiation field (known as “Weizsacker–Williams Approximation” [6,7]), with Lorentz contracted wavelength . Hence, it oscillates times, emitting a sinusoidal wave train of length at a wavelength . In other terms, it acts as a “relativistic mirror” where the radiation is back-reflected. From this picture, we obtain the same result of Equations (3)–(7). In fact, by Lorentz-transforming the incident and reflecting wavelengths and back to the laboratory frame, we obtain the relation (5). Moreover, it is well-known that the Fourier transform of a plane-wave truncated after oscillations is a sinc-function with line-width .
1.2. FEL Stimulated Emission
- (a)
- the electron gives energy to the field and decelerates, i.e., stimulated emission which provides “gain”,
- (b)
- the electron takes energy from the field and accelerates, i.e., absorption.
1.3. High-Gain Regime and SASE
1.4. Quantum FEL
2. Classical Model of Equations
3. 3D FEL Model
3.1. 3D Hamiltonian
- the fast oscillating term can be neglected,
- the ultra-relativistic limit, is assumed,
- the small term is neglected.
3.2. Maxwell Evolution Equations
3.2.1. Vector Potential
3.2.2. Space Charge Effects
3.3. 1D FEL Model
3.4. Universal Scaling
3.5. Steady State Regime
Constants of Motion
3.6. Linear Analysis
- given a spread , the optimal gain occurs for the specific detuning shift;
- energy spread () lowers the growth rate, and shift the resonance to ;
- the width of the gain curve shrinks as .
3.7. Superradiant Regime
3.8. SASE Operation
- high gain instability;
- propagation effects, i.e., “slippage”;
- start-up from noise.
4. From 1D to 3D
4.1. Transverse Effects
- The matching between electron and radiation beam requires that the beam waist and the Rayleigh range of each other must be comparable:
- The electron beam should be contained in the laser beam and the electron beam should not diverge appreciably in a Rayleigh range
- different longitudinal momentum distribution, (see Equation (93))
- off-axis variation of the undulator parameter
- angular divergence of the beam
4.2. Full 3D Model
Optical Guiding
4.3. Quantum Regime of FEL
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
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Piovella, N.; Volpe, L. A Review of High-Gain Free-Electron Laser Theory. Atoms 2021, 9, 28. https://doi.org/10.3390/atoms9020028
Piovella N, Volpe L. A Review of High-Gain Free-Electron Laser Theory. Atoms. 2021; 9(2):28. https://doi.org/10.3390/atoms9020028
Chicago/Turabian StylePiovella, Nicola, and Luca Volpe. 2021. "A Review of High-Gain Free-Electron Laser Theory" Atoms 9, no. 2: 28. https://doi.org/10.3390/atoms9020028
APA StylePiovella, N., & Volpe, L. (2021). A Review of High-Gain Free-Electron Laser Theory. Atoms, 9(2), 28. https://doi.org/10.3390/atoms9020028