Solar radiation heats the earth’s crust signi­ficantly during daylight hours, but that energy is lost into the coldness of space when the sun goes down. Now, researchers within the School of Photovoltaic and Renewable Energy Engineering at UNSW Sydney have success­fully tested a device capable of converting infrared heat into electrical power. The team, including members of the ARC Centre of Excellence in Exciton Science, used a power-genera­tion device – a thermo­radiative diode, which is similar to the technology in night-vision goggles.

Exciton Science Associate Investigator Nicholas Ekins-Daukes, the leader of the research team, said: “In the late 18th and early 19th century it was discovered that the effi­ciency of steam engines depended on the temperature difference across the engine, and the field of thermo­dynamics was born. “The same principles apply to solar power – the sun provides the hot source and a relatively cool solar panel on the Earth’s surface provides a cold absorber. This allows elec­tricity to be produced. “However, when we think about the infrared emission from the Earth into outer space, it is now the Earth that is the compara­tively warm body, with the vast void of space being extremely cold.

“By the same principles of thermo­dynamics, it is possible to generate elec­tricity from this temperature difference too: the emission of infrared light into space”, Ekins-Daukes says. Norwegian researcher Rune Strandberg first explored the theo­retical possi­bility of such a device, and researchers at Stanford University are investigating alter­native approaches to capturing thermal energy at night. The amount of energy produced through this new test is small – roughly equivalent to 0.001 percent of a solar cell –, but the proof of concept is signi­ficant.

“We usually think of the emission of light as something that consumes power, but in the mid-infrared, where we are all glowing with radiant energy, we have shown that it is possible to extract elec­trical power,” Nicholas said. “We do not yet have the miracle material that will make the thermo­radiative diode an everyday reality, but we made a proof of principle and are eager to see how much we can improve on this result in the coming years.” The team are now excited to move to the next research phase in creating and refining their own devices to harness the power of the night, and welcome potential industry partners. (Source: Exciton Sci.)

Reference: M. P. Nielsen et al.: Thermoradiative Power Conversion from HgCdTe Photodiodes and Their Current–Voltage Characteristics, ACS Phot. 9, 1535 (2022); DOI: 10.1021/acsphotonics.2c00223

Link: School of Photovoltaic and Renewable Energy Engineering, University of New South Wales, Sydney, Australia