Thermoelectric Energy Harvesting Via Piezoelectric Material

TL;DR

This paper proposes using piezoelectric materials in thermoelectric energy harvesters to overcome power output limitations, demonstrating an order of magnitude increase in maximum power through analysis and simulation.

Contribution

Introducing a novel concept of integrating piezoelectric materials to enhance thermoelectric device power output, validated by comprehensive physics analysis and quantum simulation.

Findings

Maximum output power increased by at least tenfold.

The new approach addresses the power limitation in thermoelectric harvesters.

Validation through device physics analysis and quantum simulation.

Abstract

Thermoelectric energy harvesters can have a much higher conversion efficiency by implementing quantum dots/wells between the high temperature region and the low temperature region. However they still suffer a limitation of the maximum output power, represented by the maximum $\Delta E$ (maximum energy gap of two quantum dots/wells layers). In this work, we use the piezoelectric material in the high temperature region, which has conceptually addressed the problem of the maximum power limitation. Full analysis of device physics including comparison with the existing technology and quantum simulation has been conducted to validate this concept. Results show that with the new concept, the maximum output power has been increased by at least an order of magnitude with the same power input and identical device dimensions.