# Revisiting Submicron-Gap Thermionic Power Generation Based on   Comprehensive Charge and Thermal Transport Modeling

**Authors:** Devon Jensen, Mohammad Ghashami, Keunhan Park

arXiv: 1907.06161 · 2021-04-06

## TL;DR

This paper develops a comprehensive model for nanoscale-gap thermionic energy conversion, showing that optimized submicron gaps can significantly outperform traditional micron-gap devices in power and efficiency.

## Contribution

It introduces a detailed charge and thermal transport model considering nanoscale effects like tunneling and near-field radiation, advancing the theoretical understanding of submicron-gap TEC.

## Key findings

- Submicron-gap TEC can produce ~4 times more power than micron-gap devices.
- Optimized submicron-gap TEC achieves 5-10% higher efficiency.
- Adding a bottom-cycle heat engine further enhances power and efficiency.

## Abstract

Over the past years, thermionic energy conversion (TEC) with a reduced inter-electrode vacuum gap has been studied as an effective way to mitigate a large potential barrier due to space charge accumulation. However, existing theoretical models do not fully consider the fundamental aspects of thermionic emission when the inter-electrode gap shrinks to the nanoscale, which results in underestimation of thermionic power generation for such small gaps. The present work addresses this challenge by comprehensively modeling charge and thermal transport processes with specific consideration of nanoscale gap effects, such as image charge perturbation, electron tunneling, and near-field thermal radiation. Carefully conducted energy balance analysis reveals that if optimized, submicron-gap TEC can excel the micron-gap counterpart with $\sim$4 times the power output and ~5-10 % higher energy conversion efficiency. Moreover, the high-temperature collector of the submicron-gap TEC, which is due to thermionic and near-field radiative heat transfer, allows the addition of a bottom-cycle heat engine to further enhance the power and efficiency when combined. Electric field concentration due to engineered surface roughness is also examined as a potential approach to produce an additional increase in power generation. We believe that the present work provides a theoretical framework for submicron-gap thermionic power generation as a promising energy recycling scheme for high-quality heat sources.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1907.06161/full.md

## References

47 references — full list in the complete paper: https://tomesphere.com/paper/1907.06161/full.md

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Source: https://tomesphere.com/paper/1907.06161