Experimental and theoretical studies on noble metal decorated tin oxide flower-like nanorods with high ethanol sensing performance

•This study reports for the facile synthesis of Au and Pd-decorated SnO2 hierarchical nanorods.•The SnO2/noble metal nanocomposites showed high responses towards ethanol at a low temperature of 175°C.•Molecular dynamics simulations was used to study the adsorption of ethanol on SnO2(110). This study...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Chemical, 2015-11, Vol.219, p.83-93
Main Authors: Kaneti, Yusuf V., Yue, Jeffrey, Moriceau, Julien, Chen, Chuyang, Liu, Minsu, Yuan, Yuan, Jiang, Xuchuan, Yu, Aibing
Format: Article
Language:English
Subjects:
Gas sensing
Molecular dynamics simulation
Nanorods
Noble metals
Tin oxide
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Summary:•This study reports for the facile synthesis of Au and Pd-decorated SnO2 hierarchical nanorods.•The SnO2/noble metal nanocomposites showed high responses towards ethanol at a low temperature of 175°C.•Molecular dynamics simulations was used to study the adsorption of ethanol on SnO2(110). This study reports a facile solvothermal method for the synthesis of tin oxide (SnO2) flower-like nanorods with dominant (110) crystal surface, which could be further decorated with varying amounts of noble metals, (gold (Au) and palladium (Pd)) to enhance the gas-sensing properties. Analysis of the gas-sensing results reveal that the decoration of Au and Pd nanoparticles on the surface of the SnO2 nanorods is advantageous in: (i) enhancing the sensitivity towards ethanol (9–15 times); (ii) reducing the response/recovery time (by 15–40s), and (iii) significantly decreasing the optimum operating temperature (from 250 to 175°C). Beyond physical experiments, molecular dynamics (MD) method was also conducted to quantify diffusivity, adsorption and reaction capabilities of ethanol on SnO2(110) plane and to better understand the role of noble metals in enhancing the gas-sensing performance of SnO2. The findings in this study will be useful for future design of metal oxide nanocomposites with specific crystal surface for achieving high performance in surface-governed applications.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2015.04.136