Ultrahigh sensitivity of Au/1D α-Fe2o3 to acetone and the sensing mechanism

Poernomo Gunawan; Lin Mei; Jaclyn Teo; Jianmin Ma; James Highfield; Qiuhong Li; Ziyi Zhong

doi:10.1021/la302590g

Ultrahigh sensitivity of Au/1D α-Fe₂o₃ to acetone and the sensing mechanism

Poernomo Gunawan, Lin Mei, Jaclyn Teo, Jianmin Ma, James Highfield, Qiuhong Li, Ziyi Zhong^*

^*Corresponding author for this work

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

102 Scopus citations

Abstract

Hematite (α-Fe₂O₃) is a nontoxic, stable, versatile material that is widely used in catalysis and sensors. Its functionality in sensing organic molecules such as acetone is of great interest because it can result in potential medical applications. In this report, microwave irradiation is applied in the preparation of one-dimensional (1D) α-FeOOH, thereby simplifying our previous hydrothermal method and reducing the reaction time to just a few minutes. Upon calcination, the sample was converted to porous α-Fe₂O₃ nanorods, which were then decorated homogeneously by fine Au particles, yielding Au/1D α-Fe₂O₃ at nominally 3 wt % Au. After calcination, the sample was tested as a potential sensor for acetone in the parts per million range and compared to a similarly loaded Pt sample and the pure 1D α-Fe₂O₃ support. Gold addition results in a much enhanced response whereas Pt confers little or no improvement. From tests on acetone in the 1-100 ppm range in humid air, Au/1D α-Fe₂O ₃ has a fast response, short recovery time, and an almost linear response to the acetone concentration. The optimum working temperature was found to be 270 °C, which was judged to be a compromise between the thermal activation of lattice oxygen in hematite and the propensity for acetone adsorption. The surface reaction was investigated by diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS), and a possible sensing mechanism is proposed. The presence of Au nanoparticles is believed to promote the dissociation of molecular oxygen better in replenishing O vacancies, thereby increasing the instantaneous supply of lattice oxygen to the oxidation of acetone (to H₂O and CO₂), which proceeds through an adsorbed acetate intermediate. This work contributes to the development of next-generation sensors, which offer ultrahigh detection capabilities for organic molecules.

Original language	English
Pages (from-to)	14090-14099
Number of pages	10
Journal	Langmuir
Volume	28
Issue number	39
DOIs	https://doi.org/10.1021/la302590g
State	Published - 2 Oct 2012
Externally published	Yes

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title = "Ultrahigh sensitivity of Au/1D α-Fe2o3 to acetone and the sensing mechanism",

abstract = "Hematite (α-Fe2O3) is a nontoxic, stable, versatile material that is widely used in catalysis and sensors. Its functionality in sensing organic molecules such as acetone is of great interest because it can result in potential medical applications. In this report, microwave irradiation is applied in the preparation of one-dimensional (1D) α-FeOOH, thereby simplifying our previous hydrothermal method and reducing the reaction time to just a few minutes. Upon calcination, the sample was converted to porous α-Fe2O3 nanorods, which were then decorated homogeneously by fine Au particles, yielding Au/1D α-Fe2O3 at nominally 3 wt % Au. After calcination, the sample was tested as a potential sensor for acetone in the parts per million range and compared to a similarly loaded Pt sample and the pure 1D α-Fe2O3 support. Gold addition results in a much enhanced response whereas Pt confers little or no improvement. From tests on acetone in the 1-100 ppm range in humid air, Au/1D α-Fe2O 3 has a fast response, short recovery time, and an almost linear response to the acetone concentration. The optimum working temperature was found to be 270 °C, which was judged to be a compromise between the thermal activation of lattice oxygen in hematite and the propensity for acetone adsorption. The surface reaction was investigated by diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS), and a possible sensing mechanism is proposed. The presence of Au nanoparticles is believed to promote the dissociation of molecular oxygen better in replenishing O vacancies, thereby increasing the instantaneous supply of lattice oxygen to the oxidation of acetone (to H2O and CO2), which proceeds through an adsorbed acetate intermediate. This work contributes to the development of next-generation sensors, which offer ultrahigh detection capabilities for organic molecules.",

author = "Poernomo Gunawan and Lin Mei and Jaclyn Teo and Jianmin Ma and James Highfield and Qiuhong Li and Ziyi Zhong",

year = "2012",

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AU - Gunawan, Poernomo

AU - Mei, Lin

AU - Teo, Jaclyn

AU - Ma, Jianmin

AU - Highfield, James

AU - Li, Qiuhong

AU - Zhong, Ziyi

PY - 2012/10/2

Y1 - 2012/10/2

N2 - Hematite (α-Fe2O3) is a nontoxic, stable, versatile material that is widely used in catalysis and sensors. Its functionality in sensing organic molecules such as acetone is of great interest because it can result in potential medical applications. In this report, microwave irradiation is applied in the preparation of one-dimensional (1D) α-FeOOH, thereby simplifying our previous hydrothermal method and reducing the reaction time to just a few minutes. Upon calcination, the sample was converted to porous α-Fe2O3 nanorods, which were then decorated homogeneously by fine Au particles, yielding Au/1D α-Fe2O3 at nominally 3 wt % Au. After calcination, the sample was tested as a potential sensor for acetone in the parts per million range and compared to a similarly loaded Pt sample and the pure 1D α-Fe2O3 support. Gold addition results in a much enhanced response whereas Pt confers little or no improvement. From tests on acetone in the 1-100 ppm range in humid air, Au/1D α-Fe2O 3 has a fast response, short recovery time, and an almost linear response to the acetone concentration. The optimum working temperature was found to be 270 °C, which was judged to be a compromise between the thermal activation of lattice oxygen in hematite and the propensity for acetone adsorption. The surface reaction was investigated by diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS), and a possible sensing mechanism is proposed. The presence of Au nanoparticles is believed to promote the dissociation of molecular oxygen better in replenishing O vacancies, thereby increasing the instantaneous supply of lattice oxygen to the oxidation of acetone (to H2O and CO2), which proceeds through an adsorbed acetate intermediate. This work contributes to the development of next-generation sensors, which offer ultrahigh detection capabilities for organic molecules.

AB - Hematite (α-Fe2O3) is a nontoxic, stable, versatile material that is widely used in catalysis and sensors. Its functionality in sensing organic molecules such as acetone is of great interest because it can result in potential medical applications. In this report, microwave irradiation is applied in the preparation of one-dimensional (1D) α-FeOOH, thereby simplifying our previous hydrothermal method and reducing the reaction time to just a few minutes. Upon calcination, the sample was converted to porous α-Fe2O3 nanorods, which were then decorated homogeneously by fine Au particles, yielding Au/1D α-Fe2O3 at nominally 3 wt % Au. After calcination, the sample was tested as a potential sensor for acetone in the parts per million range and compared to a similarly loaded Pt sample and the pure 1D α-Fe2O3 support. Gold addition results in a much enhanced response whereas Pt confers little or no improvement. From tests on acetone in the 1-100 ppm range in humid air, Au/1D α-Fe2O 3 has a fast response, short recovery time, and an almost linear response to the acetone concentration. The optimum working temperature was found to be 270 °C, which was judged to be a compromise between the thermal activation of lattice oxygen in hematite and the propensity for acetone adsorption. The surface reaction was investigated by diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS), and a possible sensing mechanism is proposed. The presence of Au nanoparticles is believed to promote the dissociation of molecular oxygen better in replenishing O vacancies, thereby increasing the instantaneous supply of lattice oxygen to the oxidation of acetone (to H2O and CO2), which proceeds through an adsorbed acetate intermediate. This work contributes to the development of next-generation sensors, which offer ultrahigh detection capabilities for organic molecules.

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DO - 10.1021/la302590g

M3 - 文章

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AN - SCOPUS:84867079786

SN - 0743-7463

VL - 28

SP - 14090

EP - 14099

JO - Langmuir

JF - Langmuir

IS - 39

ER -

Ultrahigh sensitivity of Au/1D α-Fe₂o₃ to acetone and the sensing mechanism

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