LPG Gas Sensing Performance of Nanostructured CdSnO₃ Thin Films

• Autorzy: Bari R. H. , Patil S. B. , Chaudhary R. T.

Identyfikatory

DOI

10.18052/www.scipress.com/ILCPA.42.51

• Języki publikacji: EN

Abstrakty

EN

Nanostructured CdSnO₃ thin films were prepared by spray pyrolysis technique. The nanostructured CdSnO3 film showed selectivity for LPG gas over other conventional gases. The maximum LPG response of 1460 for the sample S2 at 350 °C was achieved. The quick response (T_Response = 5 s) and fast recovery (Tsub>Recovery = 11 s) are the main features of this film. Additionally, the stability of the prepared sensor has been studied. As prepared thin films were studied using XRD, FE-SEM, and EDAX to know crystal structure, surface morphology, and elemental composition, respectively. The results are discussed and interpreted.

Słowa kluczowe

EN

Nanostuctured pervoskite CdSnO3; Microstructure property; Conductivity; LPG gas response; stability; Response and recovery of sensor

• Wydawca: Przedsiębiorstwo Wydawnictw Naukowych "DARWIN"
• Czasopismo: International Letters of Chemistry, Physics and Astronomy
• Rocznik: 2015
• Tom: Vol. 42
• Strony: 51--62
• Opis fizyczny: Bibliogr. 22 poz., rys., tab.

Twórcy

autor

Bari R. H.

• Nanomaterials Research Laboratory, Department of Physics, G.D.M. Arts, K.R.N. Commerce and M.D. Science College, Jamner 424 206, India

autor

Patil S. B.

• Nanomaterials Research Laboratory, Department of Physics, G.D.M. Arts, K.R.N. Commerce and M.D. Science College, Jamner 424 206, India

autor

Chaudhary R. T.

• Research Laboratory, Department of Physics, Shri. V.S. Naik, A.C.S. College, Raver, India

Bibliografia

• [1] N. G. Cho, H. S. Woo, J. H. Lee, I. D. Kim, Chem.Commu. 47 (2011) 11300-11302.
• [2] G. H. Jain, L. A. Patil, M. S. Wagh, D. R. Patil, S. A. Patil, D. P. Amalnerkar, Sensors and Actuators B: Chemical 117 (2006) 159-165.
• [3] P. P. Sahay, R. K. Nath, Sensors and Actuators B: Chemical 117 (2006) 159-165.
• [4] B. G. Lewis and D. C. Paine, MRS Bulletin 25 (2000) 22-27.
• [5] X. Li, Timothy A. Gessert, and T. Coutts, Applied Surface Science 223 (2004) 138-143.
• [6] M. M. Islam, M. R. Islam, and J. Podder, Journal of Bangladesh Academy of Science 32 (2008) 97-105.
• [7] J. W. Fergus, Sensors and Actuators B, 123 (2007) 1169-1179.
• [8] A. Kulkarni, F.T. Ciacchi, S. Giddey, C. Munnings, S.P.S. Badwal, J.A. Kimpton, D. Fini, Int. Journal of Hydrogen Energy 37 (2012) 19092-19102.
• [9] J. M. D. Coey, M. Viret; S. Von Molnar, Advances in Physics 48 (1999) 167-293.
• [10] R.D. Shannon, J.L. Gillson, R.J. Bouchard, J. Phys. Chem. Solids 38 (1977) 819-824.
• [11] Y. Li Liua, Y. Xingb, H. Feng Yanga, Z. Min Liua, Y. Yanga, G. Li Shena, R. Qin Yua, Anal. Chim. Acta 527 (2004) 21-26.
• [12] T. S. Zhang, P. Hing, Y. Li, and J. C. Zhang, Sensors and Actuators B 60 (1999) 208-215.
• [13] R. H. Bari, S. B. Patil, A.R. Bari, G. E. Patil, J. Aambekar, Journal of Sensors & Transducers. 140 (2012) 124-132.
• [14] X. H. Wu, Y. D. Wang, Y. F. Li, and Z. L. Zhou, Mater. Chem. Phys. 77 (2002) 588-593.
• [15] T. S. Zhang, Y. S. Shen, R. F. Zhang, and X. Q. Liu, Mater. Lett. 27 (1996) 161-164.
• [16] T. S. Zhang, Y. S. Shen, and R. F. Zhang, Mater. Lett. 23 (1995) 69-71.
• [17] G. E. Patil, D. D. Kajale, S. D. Shinde, N. K. Pawar, V. B. Gaikwad, and G. H. Jain, Journal. of Nanoengeeniring. and Nanomanufacturing 2 (2012) 1.
• [18] L.A. Patil, A.R. Bari, M.D. Shinde, Vinita Deo, Sensors and Actuators B: Chemical, 149 (2010) 79-86.
• [19] V. B. Patil, G. S. Shahane and L. P. Deshmukh, Mate. Chem. and Phys. 80 (2003) 625-632.
• [20] JCPDS card no. 34-0758.
• [21] JCPDS card no. 34-0885.
• [22] Y. Li, W. Wlodarski, K. Galatsis, S. Moslih, J. Cole, S. Russa, N. Rockelmann, Sensors and Actuators B: Chemical 83 (2002) 160-163.