Physical factors governing the shape of the Miram curve knee in thermionic emission

TL;DR

This paper investigates the physical factors influencing the shape of the Miram curve knee in thermionic emission, focusing on space charge and patch field effects, and provides insights for optimizing thermionic cathode design.

Contribution

It offers a comprehensive analysis of how space charge and patch field effects affect the Miram curve knee, linking physical parameters to emission characteristics.

Findings

Three main physical parameters significantly impact the Miram curve shape.

Patch size, work function, and device geometry influence the knee's smoothness and flatness.

Physical understanding guides the design of more efficient thermionic cathodes.

Abstract

In a current density versus temperature (J-T) (Miram) curve in thermionic electron emission, experimental measurements demonstrate there is a smooth transition between the exponential region and the saturated emission regions, which is sometimes referred to as the "roll-off" or "Miram curve knee". The shape of the Miram curve knee is an important figure of merit for thermionic vacuum cathodes. Specifically, cathodes with a sharp Miram curve knee at low temperature with a flat saturated emission current are typically preferred. Our previous work on modeling nonuniform thermionic emission revealed that the space charge effect and patch field effect are key pieces of physics which impact the shape of the Miram curve knee. This work provides a more complete understanding of the physical factors connecting these physical effects and their relative impact on the shape of the knee, including the smoothness, the temperature, and the flatness of the saturated emission current density. For our analyses, we use a periodic, equal-width striped ("zebra crossing") work function distribution as a model system and illustrate how the space charge and patch field effects restrict the emission current density near the Miram curve knee. The results indicate there are three main physical parameters which significantly impact the shape of the Miram curve. Such physical knowledge directly connects the patch size, work function values, anode-cathode voltage, and anode-cathode gap distance to the shape of the Miram curve, providing new understanding and a guide to the design of thermionic cathodes used as electron sources in vacuum electronic devices (VEDs).