The implications of collisions on the spatial profile of electric potential and the space-charge limited current

Abstract

The space-charge limited current (SCLC) in a vacuum diode is given by the Child-Langmuir law (CLL), whose electric potential (x) = (x/D)4/3, where x is the spatial coordinate across the gap and D is the gap separation distance. For a collisional diode, SCLC is given by the Mott-Gurney law (MGL) and (x) = (x/D)3/2. This Letter applies a capacitance argument for SCLC and uses the transit time from a recent exact solution for collisional SCLC to show that (x) = (x/D) for a general collisional gap, where 4/3 ≤slant ≤slant 3/2. Furthermore, is strictly a function of T, where is the collision frequency and T is the electron transit time. Using this definition of , we estimate the spatial dependence of the electron velocity and use the capacitance to derive an analytic equation for collisional SCLC that agrees within 5-6\% of the exact solution that requires solving parametrically through T. We derive equations in the limits of 0 and ∞ for general that asymptotically recover the CLL as 0 and the MGL as ∞. Matching these limits shows that 1.40 and V D22 at the transition from a vacuum to collisional diode for any device condition.

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