Effects of Particle Size on the Gas Sensitivity and Catalytic Activity of In2O3
- 197 Downloads
Abstract
Nanosized In2O3 powders with different particle sizes were prepared by the microemulsion synthetic method. The effects of particle size on the gas-sensing and catalytic properties of the as-prepared In2O3 were investigated. Reductions in particle size to nanometer levels improved the sensitivity and catalytic activity of In2O3 to i-C4H10 and C2H5OH. The sensitivity of nanosized In2O3 (<42 nm) sensors to i-C4H10, H2 and C2H5OH was 2-4 times higher than that of chemically precipitated In2O3 (130 nm) sensor. A nearly linear relationship was observed between the catalytic activity and specific surface area of In2O3 for the oxidation of i-C4H10 and C2H5OH at 275 °C. The relationship between gas sensitivity and catalytic activity was further discussed. The results of this work reveal that catalytic activity plays a key role in enhancing the sensitivity of gas-sensing materials.
Keywords
catalytic activity gas sensor indium oxide particle sizeNotes
Acknowledgments
This work was supported by the National Key Technology Research and Development Program of China (No.2013BAD17B04). The authors gratefully acknowledge Professor Denggao Jiang and his group in Zhengzhou University for their help in the preparation and determination of the characteristics of In2O3.
References
- 1.M. Gardon and J.M. Guilemany, A Review on Fabrication, Sensing Mechanisms and Performance of Metal Oxide Gas Sensors, J. Mater. Sci. Mater. Electron., 2013, 24, p 1410–1421CrossRefGoogle Scholar
- 2.Z.L. Zhan, L.F. Si, G.W. Li, X.Y. Guo, and Z.Y. Zhou, Improvement of Thermal Stability of Nanometer SnO2 by Surface Chemical Modification with SiO2, J. Funct. Mater., 2013, 44, p 2120–2123Google Scholar
- 3.C.N. Xu, J. Tamaki, N. Miura, and N. Yamazoe, Grain Size Effects on Gas Sensitivity of Porous SnO2-Based Elements, Sens. Actuators B, 1991, 3, p 147–155CrossRefGoogle Scholar
- 4.G.J. Li, X.H. Zhang, and S. Kawi, Relationships Between Sensitivity, Catalytic Activity, and Surface Areas of SnO2 Gas Sensors, Sens. Actuators B, 1999, 60, p 64–70CrossRefGoogle Scholar
- 5.T. Jinkawa, G. Saka, J. Tamaki, N. Miura, and N. Yamazoe, Relationship Between Ethanol Gas Sensitivity and Surface Catalytic Property of Tin Oxide Sensors Modified with Acidic or Basic Oxides, J. Mol. Catal., 2000, A155, p 193–200CrossRefGoogle Scholar
- 6.H. Yamaura, T. Jinkawa, J. Tamaki, K. Moriya, N. Miura, and N. Yamazoe, Indium Oxide-Based Gas Sensor for Selective Detection of CO, Sens. Actuators B, 1996, 36, p 325–332CrossRefGoogle Scholar
- 7.Z.L. Zhan, W.H. Song, and D.G. Jiang, Preparation of Nanometer-Sized In2O3 Particles by a Reverse Microemulsion Method, J. Colloid Interface Sci., 2004, 271, p 366–371CrossRefGoogle Scholar
- 8.Z.L. Zhan, W.N. Wang, L.Y. Zhu, W.J. An, and P. Biswas, Flame Aerosol Reactor Synthesis of Nanostructured SnO2 Thin Films High Gas-Sensing Properties by Control of Morphology, Sens. Actuators B, 2010, 150, p 609–615CrossRefGoogle Scholar
- 9.J.Q. Xu, Q.Y. Pan, Y. Shun, and Z.Z. Tian, Grain Size Control and Gas Sensing Properties of ZnO Gas Sensor, Sens. Actuators B, 2000, 66, p 277–279CrossRefGoogle Scholar
- 10.S.G. Ansari, P. Boroojerdian, S.R. Sainkar, R.N. Karekar, R.C. Aiyer, and S.K. Kulkarni, Grain Size Effects on H2 Gas Sensitivity of Thick Film Resistor Using SnO2 Nanoparticles, Thin Sold Films, 1997, 295, p 271–276CrossRefGoogle Scholar
- 11.G. Avgouropoulos, E. Oikonomopoulos, D. Kanistras, and T. Ioannides, Complete Oxidation of Ethanol Over Alkali-Promoted Pt/Al2O3 Catalysts, Appl. Catal. B, 2006, 65, p 62–69CrossRefGoogle Scholar
- 12.T. Maekawa, J. Tamaki, N. Miura, and N. Yamazoe, Development of SnO2-Based Ethanol Gas Sensor, Sens. Actuators B, 1992, 9, p 63–69CrossRefGoogle Scholar
- 13.N. Yamazoe and K. Shimanoe, Theoretical Approach to the Gas Response of Oxide Semiconductor Film Devices Under Control of Gas Diffusion and Reaction Effects, Sens. Actuators B, 2011, 154, p 277–282CrossRefGoogle Scholar