JOURNAL BROWSE
Search
Advanced SearchSearch Tips
Role of Different Oxide to Fuel Ratios in Solution Combustion Synthesis of SnO2 Nanoparticles
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
 Title & Authors
Role of Different Oxide to Fuel Ratios in Solution Combustion Synthesis of SnO2 Nanoparticles
Chavan, Archana U.; Kim, Ji-Hye; Im, Ha-Ni; Song, Sun-Ju;
  PDF(new window)
 Abstract
Tin oxide () nanoparticles have been synthesized by solution combustion method using citric acid as a fuel. The oxide to fuel ratio has been varied to obtain ultrafine nanoparticles with better surface area; such particles will be useful in many applications. With this synthesis method, spherical particles are formed having a particle size in the range of 11-30 nm and BET surface area of ~ . The degree of agglomeration of nanoparticles has been calculated.
 Keywords
;Nanoparticle;Combustion synthesis;
 Language
English
 Cited by
 References
1.
Y. Liu, Y. Jiao, Z. Zhang, F. Qu, A. Umar, and X. Wu, "Hierarchical $SnO_2$ Nanostructures Made of Intermingled Ultrathin Nanosheets for Environmental Remediation, Smart Gas Sensor, and Supercapacitor Applications," ACS Appl. Mater. Interface, 6 2174-84 (2014). crossref(new window)

2.
Q. Zhao, D. Ju, X. Deng, J. Huang, B. Cao, and X. Xu, "Morphology-Modulation of $SnO_2$ Hierarchical Architectures by Zn Doping for Glycol Gas Sensing and Photocatalytic Applications," Sci. Rep., 7874 1-5 (2015).

3.
L. C. Nehru and C. Sanjeeviraja, "Rapid Synthesis of Nanocrystalline $SnO_2$ by a Microwave-Assisted Combustion Method," J. Adv. Ceram., 3 [3] 171-76 (2014). crossref(new window)

4.
Y. Han, X. Wu, G. Shen, B. Dierre, L. Gong, F. Qu, Y. Bando, T. Sekiguchi, F. Filippo, and D. Golberg, "Solution Growth and Cathodoluminescence of Novel $SnO_2$ Core-Shell Homogeneous Microspheres," J. Phys. Chem. C., 114 8235-40 (2010).

5.
H. Taib and C. C. Sorrell, "Preparation of Tin Oxide," J. Aust. Ceram. Soc., 43 [1] 56-61 (2007).

6.
L. M. Sikhwivhilu, S. K. Pillai, and T. K. Hillie, "Influence of Citric Acid on $SnO_2$ Nanoparticles Sythesized by Wet Chemical Processes," J. Nanosci. Nanotech., 11 [6] 4988-94 (2011). crossref(new window)

7.
Y. Cui, A. Yu, H. Pan, X. Zhou, and X. Ding "Catalytic Outgrowth of $SnO_2$ Nanorods from ZnO-$SnO_2$ Nanoparticles Microsphere Core: Combustion Synthesis and Gas-Sensing Properties," Cryst. Eng. Comm., 14 7355-59 (2012). crossref(new window)

8.
A. Ayeshamariam, V. S. Vidhya, T. Sivakumar, R. Mahendran, R. Perumalsamy, N. Sethupathy, and M. Jayachandran "Nanoparticles of $In_2O_3$/$SnO_2$ (90/10) and (80/20) at Two Different Proportions and Its Properties," Open J. Met., 3 1-7 (2013).

9.
M. Bhagwat, P. Shah, and V. Ramaswamy, "Synthesis of Nanocrystalline $SnO_2$ Powder by Amorphous Citrate Route," Mater. Lett., 57 1604-11 (2003). crossref(new window)

10.
S. Banerjee, A. Bumajdad, and P. S. Devi "Nanoparticles of Antimony Doped Tin Dioxide as a Liquid Petroleum Gas Sensor: Effect of Size on Sensitivity," Nanotechnol., 22 [275506] 1-8 (2011).

11.
L. B. Fraigi, D. G. Lamas, and N. E. Wals e de Reca, "Comparison between Two Combustion Routes for the Synthesis of Nanocrystalline $SnO_2$ Powders," Mater. Lett., 47 262-66 (2001). crossref(new window)

12.
A. Bhattacharjee and M. Ahmaruzzaman, "A Green Approach for the Synthesis of $SnO_2$ Nanoparticles and its Application in the Reduction of p-nitrophenol," Mater. Lett., 157 260-64 (2015). crossref(new window)

13.
K. S. W. Sing, D. H. Everett, R. A. W. Haul, L. Moscou, R. A. Pierotti, J. Rouquerol, and T. Siemieniewska, "REPORTING PHYSISORPTION DATA FOR GAS/SOLID SYSTEMS with Special Reference to the Determination of Surface Area and Porosity," Pure Appl. Chem., 57 603-19 (1985).

14.
S. A. Feyzabad, Y. Mortazavi, A. A. Khodadadi, and S. Hemmati, "$Sm_2O_3$ Doped-$SnO_2$ Nanoparticles, Very Selective and Sensitive to Volatile Organic Compounds," Sens. Actuators, B, 181 910-18 (2013). crossref(new window)