Metal-organic framework coated porous structures for enhanced thermoelectric performance

Self-powered sensors/transmitters can be operated by thermoelectric generators if the temperature difference across the device is maximized. Here, we demonstrate a novel strategy to increase the overall thermoelectric conversion efficiency near room temperature (asymptotic to 30 & DEG;C) through enhancement of the heat transfer between the thermoelectric generator and the atmosphere by utilizing the latent heat of atmospheric water, radiative cooling, and an enhanced surface area. To maximize the sorption and emissivity, we coat porous copper substrates with metal-organic frameworks. Thermoelectric generators interfaced with these heat sinks exhibit a 50%-70% enhancement in the overall heat transfer coefficient owing to the increased surface area due to particle binding and the material properties of metal-organic frameworks. Furthermore, proof-of-concept experiments reveal an asymptotic to 100% increase in the total electromotive force generated by the thermoelectric generator within 30 min. Our study not only introduces a novel method to enhance the thermoelectric conversion efficiency, but also provides physical insight into the link between sorption and thermal processes.

Automated summary

We demonstrate a novel strategy to enhance the thermoelectric conversion efficiency by utilizing the latent heat of atmospheric water, radiative cooling, and an enhanced surface area. Coating porous copper substrates with metal-organic frameworks significantly increases the heat transfer efficiency, leading to a substantial increase in the total electromotive force generated by the thermoelectric generator within 30 minutes.