A free-electron laser operating in the gain-focusing regime is discussed. The variation of growth rate, radius of curvature of wave fronts, filling factor, and efficiency with emittance and energy spread is derived. The results, which are based on the Vlasov-Maxwell system of equations, are obtained by minimizing a variational functional. When plotted as a function of emittance, the efficiency at maximum growth rate peaks at a nonzero value of emittance. For small values of energy spread, the efficiency at maximum growth rate increases with energy spread, in contrast to intuitive expectations. PACS numbers: 41.60.Cr We present the results of an analytical study of the effect of emittance and energy spread [1-15] on a freeelectron laser (FEL) in the gain-focusing regime [16-19] of operation. Based on the Vlasov-Maxwell equations a differential eigenvalue equation for the wave number k of the radiation is derived and solved by a variational technique. We make use of the scaled parameters of Refs. [11,15]. However, in contrast to Refs. [11,15], our trial function depends on a variational parameter. This parameter furnishes additional information about the radiation field; namely, the spot size and the radius of curvature of radiation wave fronts [18,19]. The stationarity condition imposed on the variational functional implies that our results are insensitive to the choice of the trial function [20]. The variation of growth rate, radius of curvature of wave fronts, filling factor, and efficiency with emittance and energy spread is displayed graphically.The model consists of a matched electron beam and a matched radiation beam propagating along the z axis through a planar wiggler. The wiggler vector potential is given by A* =A W cosh(k w y)sin(k w z)e x , where A w is the amplitude, 2n/k w is the period, and c x is the unit vector along the x axis.
The vector potential of the optical beam is given by A, = j A s (y)exp[i(kz -a)t)]e x +c.c, where (o is the angular frequency andA s is the amplitude. The equations of motion of an electron are derived from the Hamiltonian function -p z (y,p y U, ~~E,z) [21]: E P== -c m 2 c y IE l+^^ + ^[l+(*"^ m 2 c 2 where E = ymc 2 is the energy of an electron of rest mass m and charge -|e|, / is the time, (P x ,p y ) are the momenta conjugate to the coordinates (*,>>), a w^S Bt \e\A w^/ mc 2 , /fi = /o(^)-^i(^) is the usual difference of Bessel functions, and £-W/2)7(l +a M V2). In the absence of the optical field electrons perform betatron oscillations in the y-p y plane. The area in this plane is the action /=/fdydp y /2x m *H/kfr where H =cp 2 /2E + Ek}y 2 l2c is the Hamiltonian for the transverse motion and kp-a w k w /J2y is the betatron wave number. The electron distribution function evolves according to the Vlasov equation. For the equilibrium distribution we choose exp[-(r-ro) 2 /q?] e/w ^exp(-J2I/a w k w mc
