Abstract
Although the employment of n-p heterojunctions is among the most popular strategies to increase the performance of gas sensors, there have been a few systematic studies to determine the optimal composition in n-p heterojunctions. This paper reports the results of a systematic study of (n) xSnO2-(p) (1-x) Co3O4 composite nanofibers (NFs) for gas sensing applications. Composite NFs were synthesized by the electrospinning method followed by annealing at 600°C. For gas sensing studies, several gases at optimal working temperature (350°C) were tested. Depending on the nominal composition, the sensors showed either n-or p-type behavior as well as different responses to the target gases. Furthermore, for all gases tested, the 0·5SnO2-0·5Co3O4 sensor (nominal composition) showed the best gas sensing characteristics. The underlying gas sensing mechanism was examined in detail. The highest response observed in the 0·5SnO2-0·5Co3O4 NFs sensor was primarily attributed to the major role of the p-Co3O4 nanograins as electron reservoir. In addition, the possible substitution of Co+2/Co+3 in Sn+4 sites, the catalytic effect of Co3O4 and generation of defects were likely to be the secondary reasons. This highlights the importance of the optimal composition for achieving the maximum gas-sensing performance in n-p composite NFs.
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