Title :
Sensing mechanisms of high temperature silicon carbide devices for exhaust gas applications
Author :
Tobias, Peter ; Golding, Brage ; Ghosh, Ruby N.
Author_Institution :
Center for Sensor Mater., Michigan State Univ., East Lansing, MI, USA
Abstract :
We show that SiC based metal-insulator-semiconductor (MIS) sensors above 700 K respond to reducing/oxidizing gases by two independent mechanisms: a chemically induced shift in the metal-insulator barrier height and the passivation/creation of charged states at the SiO2-SiC interface. The relative magnitude of the two phenomena is determined by the position of the Fermi energy at the insulator-semiconductor interface, i.e. the capacitor bias. The interface state contribution is much slower than the work function shift. For short response times and high sensor-to-sensor reliability, we find that the optimal operating bias of a gas sensor is near midgap. The combination of photoemission measurements and capacitance measurements can discriminate between the two sensor mechanisms.
Keywords :
Fermi level; MIS devices; air pollution measurement; chemical sensors; interface states; microsensors; passivation; silicon compounds; wide band gap semiconductors; work function; 700 K; Fermi energy; SiO2-SiC; SiO2-SiC interface; capacitance measurements; capacitor bias; charged states; chemically induced shift; exhaust gas applications; high sensor-to-sensor reliability; high temperature SiC devices; metal-insulator-semiconductor sensors; optimal operating bias; photoemission measurements; reducing/oxidizing gases; sensing mechanisms; short response times; work function shift; Capacitance measurement; Capacitors; Chemical sensors; Gases; Insulation; Metal-insulator structures; Passivation; Sensor phenomena and characterization; Silicon carbide; Temperature sensors;
Conference_Titel :
Sensors, 2003. Proceedings of IEEE
Print_ISBN :
0-7803-8133-5
DOI :
10.1109/ICSENS.2003.1279051
