Thermionic Current Beyond the Traditional Space Charge Limit Enabled by Trapped Ions in the Virtual Cathode

TL;DR

This paper demonstrates that trapped ions in virtual cathodes can significantly increase electron current beyond traditional space charge limits, offering potential improvements in plasma device performance.

Contribution

It introduces a model showing how ion trapping can elevate transmitted current beyond classical limits, with implications for plasma technology optimization.

Findings

Trapped ions enable higher electron currents than traditional space charge limits.

The transmitted current depends on well voltage balancing ion creation and leakage.

Current can reach much higher levels without saturation, improving device performance.

Abstract

We show that ion trapping in virtual cathodes can raise the transmitted current of emitted electrons much closer to the full emission than is predicted by theories without trapped ions. The transmitted current is controlled by the well voltage whose value must adjust to balance the creation of low-energy ions within the well, and their leakage over the well. Our model quantifies these rates and derives the current in terms of system parameters for cathode emission into a plasma in several geometries. A general prediction is that the current as a function of emitted flux does not saturate at the traditional space charge limit (the onset of a well) but can reach far higher values. Improved performance might be achieved in plasma technologies with hot cathodes through suitable optimization of the trapped ion balance.