Author_Institution :
US Naval Res. Lab., Washington, DC, USA
Abstract :
Vacuum microtriode RF amplifier performance, based upon a unit cell with a conical field emitter tip, gate, and anode, was evaluated using computer simulation. Electron emission was calculated from the Fowler-Nordheim equation. The dependence of emitted current, transconductance, and field enhancement upon geometrical factors, e.g., tip sharpness, tip height, cone half-angle, and gate hole radius, is shown. The device design parameters of transconductance, cutoff frequency, small signal gain, and efficiency have been calculated. Electron streamlines and current flux are shown for time-dependent RF input. Because a compact electron beam source has wide application, the normalized beam emittance, brightness, and beam quality are calculated for a typical case. Potential difficulties with anode power deposition are noted
Keywords :
electron field emission; electronic engineering computing; radiofrequency amplifiers; triodes; vacuum microelectronics; Fowler-Nordheim equation; anode power deposition; beam emittance; beam quality; brightness; computer simulation; cone half-angle; conical field emitter tip; current flux; cutoff frequency; electron streamlines; emitted current; field emission microtriodes; field enhancement; gate hole radius; small signal gain; tip height; tip sharpness; transconductance; vacuum microtriode RF amplifier; Anodes; Computational modeling; Computer simulation; Cutoff frequency; Electron emission; Equations; Radio frequency; Radiofrequency amplifiers; Signal design; Transconductance;
