Optimal neutralization of negative space charges in photon-enhanced thermionic emission devices under bidirectional discharge

TL;DR

This paper develops a comprehensive model for photon-enhanced thermionic emission devices that accounts for positive ion injection and bidirectional discharge, offering insights into optimizing space charge neutralization and device performance.

Contribution

It introduces a novel model that integrates positive ion distribution and bidirectional discharge effects, enhancing understanding of space charge neutralization in PETE devices.

Findings

Increased positive ion ratio enhances space charge neutralization.

Lower electron affinity reduces the required positive ion ratio.

Higher anode temperature or lower work function amplifies reverse discharge effects.

Abstract

In this study, we innovatively modeled photon-enhanced thermionic emission (PETE) devices, incorporating positive ion injection and bidirectional discharge's effects on the space charge barrier simultaneously. Compared to previous models, our model allows the positive ion distribution function to be compatible with scenarios in which the anode motive is either higher or lower than the cathode motive, and also adapts to significant anode discharge. Through numerical simulations and parametric analyses, we found that: (1) As the ratio of the positive ion increases, the capability for space charge neutralization becomes stronger. (2) The lower the electron affinity is, the smaller the ratio of positive ions are required. (3) When the anode temperature is higher or the anode work function is lower, the impact of reverse discharge on the net current density is more pronounced. Conversely, when the anode temperature is higher or the anode work function is greater, the ratio of positive ions required to achieve complete space charge neutralization increases. This study further elucidates the mechanisms and characteristics of space charge neutralization effects in PETE devices, providing a theoretical foundation for optimizing their design. Additionally, the accompanying theory and algorithm possess the potential to spark innovative research across diverse fields.