Growth of ordered anodic SnO2 nanochannel layers and their use for H2 gas sensing

A. Palacios-Padrós; M. Altomare; A. Tighineanu; R. Kirchgeorg; N. K. Shrestha; I. Díez-Pérez; F. Caballero-Briones; F. Sanz; P. Schmuki

doi:10.1039/c3ta13704j

Growth of ordered anodic SnO₂ nanochannel layers and their use for H₂ gas sensing

A. Palacios-Padrós, M. Altomare, A. Tighineanu, R. Kirchgeorg, N. K. Shrestha, I. Díez-Pérez, F. Caballero-Briones, F. Sanz, P. Schmuki

Centro de Investigación en Ciencia Aplicada y Tecnología Avanzada (CICATA), Unidad Altamira

Research output: Contribution to journal › Article › peer-review

60 Scopus citations

Abstract

In the current work, we present a new self-organizing anodization approach of metallic Sn layers to obtain vertically aligned tin oxide nanochannel structures. For this, we use a sulphide-containing electrolyte and a set of optimized anodizing parameters. The resulting high aspect ratio nanochannel morphologies can be converted into crystalline SnO₂ by high temperature annealing and show highly promising H₂ sensing properties. We show that these anodic layers can operate at relatively low temperatures (∼80 °C), detecting concentrations as low as 9 ppm, and with extremely fast response and recovery times. This excellent gas-sensing performance is ascribed to the advanced structure, characterized by a crack-free, straight and top-open nanochannel geometry.

Original language	English
Pages (from-to)	915-920
Number of pages	6
Journal	Journal of Materials Chemistry A
Volume	2
Issue number	4
DOIs	https://doi.org/10.1039/c3ta13704j
State	Published - 28 Jan 2014

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title = "Growth of ordered anodic SnO2 nanochannel layers and their use for H2 gas sensing",

abstract = "In the current work, we present a new self-organizing anodization approach of metallic Sn layers to obtain vertically aligned tin oxide nanochannel structures. For this, we use a sulphide-containing electrolyte and a set of optimized anodizing parameters. The resulting high aspect ratio nanochannel morphologies can be converted into crystalline SnO2 by high temperature annealing and show highly promising H2 sensing properties. We show that these anodic layers can operate at relatively low temperatures (∼80 °C), detecting concentrations as low as 9 ppm, and with extremely fast response and recovery times. This excellent gas-sensing performance is ascribed to the advanced structure, characterized by a crack-free, straight and top-open nanochannel geometry.",

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T1 - Growth of ordered anodic SnO2 nanochannel layers and their use for H2 gas sensing

AU - Palacios-Padrós, A.

AU - Altomare, M.

AU - Tighineanu, A.

AU - Kirchgeorg, R.

AU - Shrestha, N. K.

AU - Díez-Pérez, I.

AU - Caballero-Briones, F.

AU - Sanz, F.

AU - Schmuki, P.

PY - 2014/1/28

Y1 - 2014/1/28

N2 - In the current work, we present a new self-organizing anodization approach of metallic Sn layers to obtain vertically aligned tin oxide nanochannel structures. For this, we use a sulphide-containing electrolyte and a set of optimized anodizing parameters. The resulting high aspect ratio nanochannel morphologies can be converted into crystalline SnO2 by high temperature annealing and show highly promising H2 sensing properties. We show that these anodic layers can operate at relatively low temperatures (∼80 °C), detecting concentrations as low as 9 ppm, and with extremely fast response and recovery times. This excellent gas-sensing performance is ascribed to the advanced structure, characterized by a crack-free, straight and top-open nanochannel geometry.

AB - In the current work, we present a new self-organizing anodization approach of metallic Sn layers to obtain vertically aligned tin oxide nanochannel structures. For this, we use a sulphide-containing electrolyte and a set of optimized anodizing parameters. The resulting high aspect ratio nanochannel morphologies can be converted into crystalline SnO2 by high temperature annealing and show highly promising H2 sensing properties. We show that these anodic layers can operate at relatively low temperatures (∼80 °C), detecting concentrations as low as 9 ppm, and with extremely fast response and recovery times. This excellent gas-sensing performance is ascribed to the advanced structure, characterized by a crack-free, straight and top-open nanochannel geometry.

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U2 - 10.1039/c3ta13704j

DO - 10.1039/c3ta13704j

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JO - Journal of Materials Chemistry A

JF - Journal of Materials Chemistry A

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Growth of ordered anodic SnO₂ nanochannel layers and their use for H₂ gas sensing

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