posted on 2022-05-06, 22:43authored byThanh Nguyen, Toan Dinh, John Bell, Van Thanh Dau, Nam-Trung Nguyen, Dzung Viet Dao
Utilizing
harvesting energy to power sensors has been becoming
more critical in the current age of the Internet of Things. In this
paper, we propose a novel technology using a monolithic 3C-SiC/Si
heterostructure to harvest photon energy to power itself and simultaneously
sense the surrounding temperature. The 3C-SiC/Si heterostructure converts
photon energy into electrical energy, which is manifested as a lateral
photovoltage across the top material layer of the heterostructure.
Simultaneously, the lateral photovoltage varies with the surrounding
temperature, and this photovoltage variation with temperature is used
to monitor the temperature. We characterized the thermoresistive properties
of the 3C-SiC/Si heterostructure, evaluated its energy conversion,
and investigated its performance as a light-harvesting self-powered
temperature sensor. The resistance of the heterostructure gradually
drops with increasing temperature with a temperature coefficient of
resistance (TCR) ranging from more than −3500 to approximately
−8200 ppm/K. The generated lateral photovoltage is as high
as 58.8 mV under 12 700 lx light illumination at 25 °C.
The sensitivity of the sensor in the self-power mode is as high as
360 μV·K–1 and 330 μV·K–1 under illumination of 12 700 lx and 7400 lx
lights, respectively. The sensor harvests photon energy to power itself
and measure temperatures as high as 300 °C, which is impressive
for semiconductor-based sensor. The proposed technology opens new
avenues for energy harvesting self-powered temperature sensors.