Wearable Solar Thermoelectric Generator sets Temperature Record
A recent study, led by Professor Kyoung Jin Choi in the School of Materials Science and Engineering at Ulsan National Institute of Science and Technology (UNIST) in South Korea has introduced a new advanced energy harvesting system, capable of generating electricity by simply being attached to clothes, windows, and outer walls of a building.
In this study, Professor Choi and his team designed a noble wearable solar thermoelectric generator (W-STEG) by integrating flexible BiTe-based TE legs and sub-micron thick solar absorbers on a polymide (PI) substrate.
The TE legs were prepared by dispenser printing with an ink consisting of mechanically alloyed BiTe-based powders and a Sb2Te3-based sintering additive dispersed in glycerol. They report that a W-STEG comprising 10 pairs of p-n legs has an open-circuit voltage of 55.15mV and an output power of 4.44μW when exposed to sunlight.
This new device is based on a temperature difference between the hot and cold sides. The temperature difference can be increased as high as 20.9 degrees C, which is much higher than the typical temperature differences of 1.5 to 4.1 degrees C of wearable thermoelectric generators driven by body heat.
The research team expects that their wearable solar thermoelectric generator proposes a promising way to further improve the efficiency by raising the temperature difference.
Energy harvesting is a diverse field encompassing many technologies, which involve a process that captures small amounts of energy that would otherwise be lost as heat, light, sound, vibration, or movement. A thermoelectric generator (TEGs) refers to a device that converts waste heat energy, such as solar energy, geothermal energy, and body heat into additional electrical power.
There has been a great increase in the study of wearable thermoelectric (TE) generators using the temperature difference between the body heat and surrounding environment. However, one of the main drawbacks of wearable TEG techniques driven by body heat was that such temperature difference is only 1 to 4 degrees C and this has hindered further commercialization.
The research team solved this low temperature difference faced by conventional wearable TEGs by introducing a local solar absorber on a PI substrate. The solar absorber is a five-period Ti/MgF2 superlattice, in which the structure and thickness of each layer was designed for optimal absorption of sunlight. This has increased the temperature difference as high as 20.9 degrees C, which is the highest value of all wearable TEGs reported to date.
"Through this study, we have secured a temperature difference with the ten-fold increase from the conventional wearable solar thermoelectric generators," says Yeon Soo Jung in the Graduate School of Materials Science and Engineering at UNIST. "Since the output of a TE generator is proportional to the square root of the temperature difference, one can significantly increase the output with the help of this technology."
"Our new werable STEG is expected to be useful in various applications, such as in self-powered wearable electronic devices," says Professor Choi. "It will also serve as a catalyst to further improve the future wearable electronic technology market."
The findings of the research have been published in the August issue of the prestigious journal Nano Energy (IF: 12.34). This work has been supported by the R&D Convergence Program of National Research Council of Science & Technology (NST) of Republic of Korea and the KIST-UNIST partnership program.