Fast Nitrogen Dioxide Sensing with Ultralow‐Power Nanotube Gas Sensors
Seoho Jung, Cosmin Roman, Christofer Hierold
Abstract
Abstract The study reports fast, ultralow‐power operation of carbon nanotube‐based nitrogen dioxide (NO 2 ) sensors enabled by nanotube self‐heating and transient sensing. The self‐heating effect in the nanotube channel significantly accelerates the desorption of gas molecules, reducing the sensor recovery time to a minute. As gas molecules re‐adsorb on the nanotube after cooling, the initial rate of the sensor transient is used to determine NO 2 concentration within a few minutes. To accelerate and optimize the operation of the sensor, the study considered temperature profiles along the self‐heated carbon nanotube, their effect on different sensing regions, and a physical model‐based fit. As a result, the nanotube‐based NO 2 sensor demonstrates recovery and readout times below 5 min and an extrapolated limit of detection below 10 ppb. The peak power consumption of this operation mode is below 6 µW. The combination of fast readout, fast recovery, low limit of detection, and ultralow power consumption demonstrated in this work shows strong promise of carbon nanotube‐based NO 2 sensors in mobile or Internet‐of‐Things (IoT) applications.