Jesse M. Snelling, Gregory R. Werner, John R. Cary
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Empirically extending 1D Child-Langmuir theory to a finite temperature beam
Numerical solutions to the 1D steady-state Vlasov-Poisson system are used to
develop a straightforward empirical formula for the electric current density
transmitted through a vacuum diode (voltage gap) as a function of gap distance,
gap voltage, the injected current density, and the average velocity and
temperature of injected particles, as well as their charge and mass. This
formula generalizes the 1D cold beam Child-Langmuir law (which predicts the
maximum transmitted current for mono-energetic particles in a planar diode as a
function of gap voltage and distance) to the case where particles are injected
with a finite velocity spread. Though this case is of practical importance, no
analytical solution is known. Found by a best-fit to results from
particle-in-cell (PIC) simulations, the empirical formula characterizes the
current transmitted across the diode for an injected velocity distribution of a
drifting Maxwellian. It is not meant to yield a precise answer, but
approximately characterizes the effect of space charge on transmitted current
density over a large input space. The formula allows quick quantitative
estimation of the effect of space charge in diode-like devices, such as
gate-anode gaps in nanoscale vacuum channel transistors.
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