Rational Design of Sub-Parts per Million Specific Gas Sensors Array Based on Metal Nanoparticles Decorated Nanowire Enhancement-Mode Transistors

Zou, Xuming; Wang, Jingli; Liu, Xingqiang; Wang, Chunlan; Jiang, Ying; Wang, Yong; Xiao, Xiangheng; Ho, Johnny C.; Li, Jinchai; Jiang, Changzhong; Fang, Ying; Liu, Wei; Liao, Lei

doi:10.1021/nl401498t

Cited by 132 publications

(105 citation statements)

References 46 publications

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“…In this case, E-mode Mg-doped In 2 O 3 nanowire FET arrays were employed as the gas sensing platform and decorated with Au, Ag, and Pt nanoparticles to provide specific selectivity for reducing gases such as CO, C 2 H 5 OH, and H 2 . 177 Figure 58 illustrates an example of a "one lock to one key" sensor system. On the other hand, the metal nanowire channel in the deep Emode FETs decorated with nanoparticles could exhibit unique single-target gas-specific responses.…”

Section: Sensors Based On Functional Materialsmentioning

confidence: 99%

Recent Progress on the Development of Chemosensors for Gases

et al. 2015

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Introduction 7944 2. Chemosensors Based on Fluorescent Molecules 7945 2.1. Sensors for Environment Exhaust Gases 7945 2.1.1. Sensors for CO 2 7945 2.1.2. Sensors for SO 2 7949 2.1.3. Sensors for O 3 7951 2.2. Sensors for Biological Signaling Gases 7952 2.2.1. Sensors for NO 7952 2.2.2. Sensors for CO 7957 2.2.3. Sensors for H 2 S 7958 2.2.4. Sensors for 1 O 2 7962 2.3. Sensors for Highly Toxic Chemical-Warfare Agents 7963 2.3.1. Sensors for Nerve Agents 7963 2.3.2. Sensors for Sulfur Mustard 7967 3. Sensors Based on Functional Materials 7968 3.1. Sensors for Environment Gases 7968 3.1.1. Sensors for CO 2 7968 3.1.2. Sensors for O 2 7969 3.1.3. Sensors for VOCs 7971 3.1.4. Sensors for HCl 7972 3.1.5. Sensors for NH 3 7972 3.1.6. Sensors for Other Gases 7974 3.2. Sensors for High Dangerous Gases 7976 3.2.1. Sensors for Nerve Agents 7976 3.2.2. Sensors for Explosives 7976 4. Chemosensors Based on Metal Oxide Semiconductor 7978 4.1. Sensors for Environmental Gases 7978 4.1.1. Sensors for VOCs 7978 4.1.2. Sensors for CO 2 7985 4.1.3. Sensors for NO 2 7985 4.1.4. Sensors for SO 2 7987 4.1.5. Sensors for Other Gases 4.2. Sensors for Highly Toxic Gases 4.2.1. Sensors for CO 4.2.2. Sensors for H 2 S 4.2.3. Sensors for O 3 5. Conclusions and Future Perspectives Author Information

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Section: Sensors Based On Functional Materialsmentioning

confidence: 99%

Recent Progress on the Development of Chemosensors for Gases

et al. 2015

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“…Ho et al used Mg-doped In 2 O 3 nanowire enhanced-mode field-effect sensor arrays decorated with various discrete metal nanoparticles ( i.e. , Au, Ag and Pt), to selectively distinguish among three reducing gases (e.g., CO, C 2 H 5 OH and H 2 ), with high sensitivity [8]. The deep enhanced-mode FET could not detect the reducing or oxidizing gases, which provided an ideal platform to introduce the gas selectivity and sensitivity into the nanowire surface by decorating various metal nanoparticles.…”

Section: Progress Of Micro/nanoscaled Single Crystals Field-effect Sementioning

confidence: 99%

“…The surface of nanowires was decorated with Au, Ag, and Pt nanoparticles, respectively; ( b ) Optical (top left) and SEM (right) image of the chemical sensor arrays. High magnification SEM (bottom left) image of Au decorated Mg-doped In 2 O 3 nanowire; ( c ) The transfer curves for the sensors with and without the metal decoration; ( d – f ) The output curves for Au, Ag and Pt decorated enhanced-mode FETs toward the gas specific detection of O 2 , H 2 , C 2 H 5 OH, and CO [8]. …”

Section: Figurementioning

confidence: 99%

One-Dimensional Nanostructure Field-Effect Sensors for Gas Detection

Zhao

Cai

Tang

et al. 2014

Sensors

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Recently; one-dimensional (1D) nanostructure field-effect transistors (FETs) have attracted much attention because of their potential application in gas sensing. Micro/nanoscaled field-effect sensors combine the advantages of 1D nanostructures and the characteristic of field modulation. 1D nanostructures provide a large surface area-volume ratio; which is an outstanding advantage for gas sensors with high sensitivity and fast response. In addition; the nature of the single crystals is favorable for the studies of the response mechanism. On the other hand; one main merit of the field-effect sensors is to provide an extra gate electrode to realize the current modulation; so that the sensitivity can be dramatically enhanced by changing the conductivity when operating the sensors in the subthreshold regime. This article reviews the recent developments in the field of 1D nanostructure FET for gas detection. The sensor configuration; the performance as well as their sensing mechanism are evaluated.

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“…Nanomaterials have been extensively investigated for developing new gas sensors with high sensitivities and low working temperatures in the past decades. Various MOS nanostructures, including nanotubes [3,4], nanowires [5,6], and nanobelts [7], have been synthesized and explored for preparing such gas sensors. Although their sensitivities have been dramatically increased and their working temperatures have been considerably lowered even down to room temperature, all those sensors have not been commercialized for practical applications up to date due to some shortcomings inherent in low dimensional MOSs, such as low thermal stability and mechanical strength [8,9], strong adsorption of moisture [10], and difficulty in mass production.…”

Section: Introductionmentioning

confidence: 99%

Gas sensing capabilities of TiO2 porous nanoceramics prepared through premature sintering

et al. 2015

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Pure and noble metal (Pt, Pd, and Au) doped TiO 2 nanoceramics have been prepared from TiO 2 nanoparticles through traditional pressing and sintering. For those samples sintered at 550 ℃, a typical premature sintering occurred, which led to the formation of a highly porous microstructure with a Brunauer-Emmett-Teller (BET) specific surface area of 23 m 2 /g. At room temperature, only Pt-doped samples showed obvious response to hydrogen, with sensitivities as high as ~500 for 1000 ppm H 2 in N 2 ; at 300 ℃, all samples showed obvious responses to CO, while the responses of noble metal doped samples were much higher than that of the undoped ones. The mechanism for the observed sensing capabilities has been discussed, in which the catalytic effect of Pt for hydrogen is believed responsible for the room-temperature hydrogen sensing capabilities, and the absence of glass frit as commonly used in commercial thick-film metal oxide gas sensors is related to the high sensitivities. It is proposed that much attention should be paid to metal oxide porous nanoceramics in developing gas sensors with high sensitivities and low working temperatures.

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Rational Design of Sub-Parts per Million Specific Gas Sensors Array Based on Metal Nanoparticles Decorated Nanowire Enhancement-Mode Transistors

Cited by 132 publications

References 46 publications

Recent Progress on the Development of Chemosensors for Gases

Recent Progress on the Development of Chemosensors for Gases

One-Dimensional Nanostructure Field-Effect Sensors for Gas Detection

Gas sensing capabilities of TiO2 porous nanoceramics prepared through premature sintering

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