The fabrication and gas sensing application of a fast-responding m-CP-PVP composite film/potassium ion-exchanged glass optical waveguide

Min Zhu; Nuerguli Kari; Yin Yan; Abliz Yimit

doi:10.1039/c7ay01541k

Gas Sensing Properties of Porous ZnO Nano-Platelet Films

MRS Proceedings ◽

10.1557/proc-1035-l11-07 ◽

2007 ◽

Vol 1035 ◽

Author(s):

Amandeep Saluja ◽

Jie Pan ◽

Lei Kerr ◽

Eunjung Cho ◽

Seth Hubbard

Keyword(s):

Gas Flow ◽

Room Temperature ◽

Gas Sensing ◽

Electrode Spacing ◽

Porous Films ◽

Gas Sensitivity ◽

Gas Sensing Properties ◽

Recovery Times ◽

Response And Recovery ◽

Carrier Gas Flow

AbstractIn this work, various ZnO nanostructures were synthesized and a detailed study on the effect of different process parameters such as temperature, carrier gas flow, inter-electrode spacing, gas concentration and material properties on gas sensitivity was conducted. Initial ZnO nanoparticles were prepared by a simple solution chemical process and characterized by Secondary Electron Microscopy (SEM) and Brunauer, Emmet and Teller (BET) Sorptometer to demonstrate the morphology and surface area respectively. Sensitivity of nano-platelets and porous films was measured for different concentrations of the analytes (H2, CO). High response was observed at room temperature for H2 gas with sensitivities in excess 80% for 60ppm and about 55% for 80ppm of H2 gas at room temperature were observed for the nano-platelets and the porous films respectively with short response and recovery times of about 200 seconds. The sensitivity of the nano-platelets to CO gas was also measured and found to be about near 90% for 80 ppm CO at operating temperatures of 200 °C.

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A Room-Temperature CNT/Fe3O4 Based Passive Wireless Gas Sensor

Sensors ◽

10.3390/s18103542 ◽

2018 ◽

Vol 18 (10) ◽

pp. 3542 ◽

Cited By ~ 5

Author(s):

Tao Guo ◽

Tianhao Zhou ◽

Qiulin Tan ◽

Qianqian Guo ◽

Fengxiang Lu ◽

...

Keyword(s):

Carbon Nanotube ◽

Gas Sensor ◽

Room Temperature ◽

Gas Sensing ◽

Low Cost ◽

Fast Response ◽

Sensing Material ◽

Recovery Times ◽

Response And Recovery ◽

Good Repeatability

A carbon nanotube/Fe3O4 thin film-based wireless passive gas sensor with better performance is proposed. The sensitive test mechanism of LC (Inductance and capacitance resonant) wireless sensors is analyzed and the reason for choosing Fe3O4 as a gas sensing material is explained. The design and fabrication process of the sensor and the testing method are introduced. Experimental results reveal that the proposed carbon nanotube (CNT)/Fe3O4 based sensor performs well on sensing ammonia (NH3) at room temperature. The sensor exhibits not only an excellent response, good selectivity, and fast response and recovery times at room temperature, but is also characterized by good repeatability and low cost. The results for the wireless gas sensor’s performance for different NH3 gas concentrations are presented. The developed device is promising for the establishment of wireless gas sensors in harsh environments.

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Room Temperature Hydrogen Gas Sensing via Reversible Hydrogenation of Electrochemically Deposited Polycarbazole on Interdigitated Pt Transducers

Sensors ◽

10.3390/s19051098 ◽

2019 ◽

Vol 19 (5) ◽

pp. 1098

Author(s):

Agnieszka Stolarczyk ◽

Tomasz Jarosz ◽

Marcin Procek

Keyword(s):

Room Temperature ◽

Gas Sensing ◽

Hydrogen Gas ◽

Hydrogen Sensors ◽

Receptor Structure ◽

Pt Electrodes ◽

Electrochemically Deposited ◽

Recovery Times ◽

Response And Recovery ◽

Cost Efficient

In this study, polycarbazole (PCz) is presented as a receptor structure for chemoresistive hydrogen sensors. The fabrication of the proposed sensors via electropolymerisation of PCz on interdigitated Pt electrodes is an inexpensive, cost-efficient, and repeatable method. Preliminary results presented in this work show that PCz-based sensors are sensitive to hydrogen gas in the range of 1–4% in air at room temperature. Notably, responses are both relatively high (from approximately 280% for 1% of H2) and rapid (response and recovery times for 1% H2 from 5 s and up to 32 s, respectively). Results of PCz structures on Pt and Au electrodes prove that the application of Pt electrodes is crucial for observation of sensing effect. A sensing mechanism based on reversible hydrogenation of PCz is proposed to explain the sensor operating principles.

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Zinc Oxide/Reduced Graphene Oxide Nanocomposites for Rapid Detection of Toluene Gas at Room Temperature

Sensor Letters ◽

10.1166/sl.2020.4288 ◽

2020 ◽

Vol 18 (10) ◽

pp. 745-749

Author(s):

Chih-Chia Wang ◽

Chiu-Hung Liu ◽

Hsuan-Hua Hsieh ◽

Chih-Wei Tang ◽

Chen-Bin Wang

Keyword(s):

Zinc Oxide ◽

Graphene Oxide ◽

Reduced Graphene Oxide ◽

Room Temperature ◽

Gas Sensing ◽

Fast Response ◽

Reduced Graphene ◽

New Strategy ◽

Recovery Times ◽

Response And Recovery

In this study, a nanostructured zinc oxide/reduced graphene oxide (ZnO/rGO) composite was deposited on a quartz crystal microbalance (QCM) as a toluene gas sensor at room temperature. A series of ZnO, rGO and ZnO/rGO sensing materials was fabricated and characterized by X-ray diffraction (XRD), scanning electron microscope (SEM), and Raman spectroscopy. There was significant efficiency of the ZnO/rGO composite on the sensing performance for toluene. For specific gas fluxes, the nanostructured ZnO/rGO offered sufficient paths and region for vapor diffusion and adsorption. The sensing test results illustrated that the nanostructured ZnO/rGO composite showed significant enhancement in the frequency shifts (△f) for toluene comparing to pure ZnO and rGO. Also, the ZnO/rGO-coated QCM sensor displayed a fast response (both the response and recovery times < 30 s) and reproducibility for sensing toluene gas at room temperature. We believe that the novel insights on ambient temperature gas sensing on nanostructured ZnO/rGO composite could provide a new strategy for preparing a highly efficient sensing materials.

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Formaldehyde Detection Based on P3HT/InSnO Composite Thin Film Transistor

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.875-877.82 ◽

2014 ◽

Vol 875-877 ◽

pp. 82-86

Author(s):

Xian Li ◽

Ya Dong Jiang ◽

Hui Ling Tai ◽

Guang Zhong Xie ◽

Wen Chao Dan

Keyword(s):

Thin Film ◽

Composite Film ◽

Thin Film Transistors ◽

Room Temperature ◽

Thin Film Transistor ◽

Organic Thin Film Transistors ◽

Composite Thin Film ◽

Organic Thin Film ◽

Response And Recovery

Formaldehyde, a colorless and pungent-smelling gas, had been confirmed be a huge threat to people health. The detection of formaldehyde was necessary and important at room temperature. Sprayed P3HT/InSnO composite film based on organic thin film transistors (OTFT) was fabricated to detect formaldehyde at room temperature in this paper. The results showed that P3HT/ InSnO-OTFT showed better response and recovery to HCHO compared with P3HT-OTFT at room temperature.

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Xylene-sensing of Fe2(MoO4)3 nanoplates prepared via a hydrothermal method

Functional Materials Letters ◽

10.1142/s1793604717500229 ◽

2017 ◽

Vol 10 (03) ◽

pp. 1750022 ◽

Cited By ~ 5

Author(s):

Mengying Xu ◽

Zhidong Lin ◽

Wenying Guo ◽

Yuyuan Hong ◽

Ping Fu ◽

...

Keyword(s):

Gas Sensors ◽

Gas Sensing ◽

Operating Temperature ◽

Hydrothermal Process ◽

Optimum Operating ◽

Average Crystalline Size ◽

Optimum Operating Temperature ◽

Recovery Times ◽

Response And Recovery ◽

Simple Hydrothermal Process

Fe2(MoO4)3 nanoplates were prepared via a simple hydrothermal process. The average crystalline size of these nanoplates is 85.8[Formula: see text]nm. The sensor based on Fe2(MoO4)3 shows a high gas sensing performance to xylene. The response of Fe2(MoO4)3 sensor is 25.9–100[Formula: see text]ppm xylene at optimum operating temperature of 340[Formula: see text]C. The response and recovery times to 100[Formula: see text]ppm xylene are 4 and 10[Formula: see text]s, respectively. Furthermore, the Fe2(MoO4)3 sensor exhibits remarkable selectivity detection of xylene gas with negligible responses to toluene and benzene. Therefore, the Fe2(MoO4)3 is a promising material for the detection of xylene gas sensors.

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Fabrication of TiO2 sensor using rapid breakdown anodization method to measure pressure, humidity and sense gases at room temperature

Iraqi Journal of Science ◽

10.24996/ijs.2019.60.8.6 ◽

2019 ◽

pp. 1694-1703

Author(s):

Reem Saadi Khaleel ◽

Mustafa Shakir Hashim

Keyword(s):

Room Temperature ◽

Average Pressure ◽

Spherical Nanoparticles ◽

X Ray Diffraction ◽

X Ray ◽

Recovery Times ◽

Sensitivity And Selectivity ◽

Response And Recovery ◽

Anodization Method ◽

Rapid Breakdown Anodization

Rapid breakdown anodization (RBA) process was used to fabricate TiO2 sensor to measure pressure and humidity and sense gases at room temperature. This chemical process transformed Ti to its oxide (TiO2) as a powder with amorphous phase as X ray diffraction (XRD) technique confirmed. This oxide consisted from semi spherical nanoparticles and titania nanotubes (TNTs) as Scanning electron microscope (SEM) technique showed. TiO2 powder was deposited on Ti substrates by using electrophoretic deposition (EPD) method. Average pressure sensitivity was 0.34 MÎ©/bar and hysteresis area was 1.4 MÎ© .bar. Resistance of TiO2 decreased exponentially with the increasing of relative humidity (RH%). The sensitivity% of TiO2 for RH% was greater than 70% in the range of (50-95). TiO2 was tested as a sensor for Ammonia, Ethanol and Methanol. Its sensitivity and selectivity towards Ammonia were the greatest but the shortest response and recovery times were recorded toward Methanol.

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Nanostructured SmFeO3 Gas Sensors: Investigation of the Gas Sensing Performance Reproducibility for Colorectal Cancer Screening

Sensors ◽

10.3390/s20205910 ◽

2020 ◽

Vol 20 (20) ◽

pp. 5910

Author(s):

Andrea Gaiardo ◽

Giulia Zonta ◽

Sandro Gherardi ◽

Cesare Malagù ◽

Barbara Fabbri ◽

...

Keyword(s):

Colorectal Cancer ◽

Gas Sensors ◽

Process Development ◽

Gas Sensing ◽

Diagnostic Tools ◽

Fecal Samples ◽

Recovery Times ◽

Medical Diagnostic ◽

Response And Recovery ◽

Sensing Performance

Among the various chemoresistive gas sensing properties studied so far, the sensing response reproducibility, i.e., the capability to reproduce a device with the same sensing performance, has been poorly investigated. However, the reproducibility of the gas sensing performance is of fundamental importance for the employment of these devices in on-field applications, and to demonstrate the reliability of the process development. This sensor property became crucial for the preparation of medical diagnostic tools, in which the use of specific chemoresistive gas sensors along with a dedicated algorithm can be used for screening diseases. In this work, the reproducibility of SmFeO3 perovskite-based gas sensors has been investigated. A set of four SmFeO3 devices, obtained from the same screen-printing deposition, have been tested in laboratory with both controlled concentrations of CO and biological fecal samples. The fecal samples tested were employed in the clinical validation protocol of a prototype for non-invasive colorectal cancer prescreening. Sensors showed a high reproducibility degree, with an error lower than 2% of the response value for the test with CO and lower than 6% for fecal samples. Finally, the reproducibility of the SmFeO3 sensor response and recovery times for fecal samples was also evaluated.

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Gas-sensing features of nanostructured tellurium thin films

Beilstein Journal of Nanotechnology ◽

10.3762/bjnano.11.85 ◽

2020 ◽

Vol 11 ◽

pp. 1010-1018

Author(s):

Dumitru Tsiulyanu

Keyword(s):

Thin Films ◽

Gas Sensing ◽

Operating Temperature ◽

Active Surface ◽

Active Surface Area ◽

Gas Sensitivity ◽

Nanocrystalline And Amorphous ◽

Recovery Times ◽

Order Of Magnitude ◽

Response And Recovery

Nanocrystalline and amorphous nanostructured tellurium (Te) thin films were grown and their gas-sensing properties were investigated at different operating temperatures with respect to scanning electron microscopy and X-ray diffraction analyses. It was shown that both types of films interacted with nitrogen dioxide, which resulted in a decrease of electrical conductivity. The gas sensitivity, as well as the response and recovery times, differed between these two nanostructured films. It is worth mentioning that these properties also depend on the operating temperature and the applied gas concentration on the films. An increase in the operating temperature decreased not only the response and recovery times but also the gas sensitivity of the nanocrystalline films. This shortcoming could be solved by using the amorphous nanostructured Te films which, even at 22 °C, exhibited higher gas sensitivity and shorter response and recovery times by more than one order of magnitude in comparison to the nanocrystalline Te films. These results were interpreted in terms of an increase in disorder (amorphization), leading to an increase in the surface chemical activity of chalcogenides, as well as an increase in the active surface area due to substrate porosity.

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A Formaldehyde Gas Sensor Based on Zinc Doped Lanthanum Ferrite

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.873.304 ◽

2013 ◽

Vol 873 ◽

pp. 304-310 ◽

Cited By ~ 1

Author(s):

Jin Zhang ◽

Yu Min Zhang ◽

Chang Yi Hu ◽

Zhong Qi Zhu ◽

Qing Ju Liu

Keyword(s):

Gas Sensing ◽

Sol Gel ◽

X Ray Diffraction ◽

Sensing Properties ◽

Transmission Electron ◽

Lanthanum Ferrite ◽

Gas Sensing Properties ◽

Recovery Times ◽

Response And Recovery ◽

Sensing Characteristics

The gas-sensing properties of zinc doped lanthanum ferrite (Zn-LaFeO3) compounds for formaldehyde were investigated in this paper. Zn-LaFeO3 powders were prepared using sol-gel method combined with microwave chemical synthesis. The powders were characterized by X-ray diffraction (XRD) and transmission electron microscopy (TEM), respectively. The formaldehyde gas-sensing characteristics for the sample were examined. The experimental results indicate that the sensor based on the sample Zn-LaFeO3 shows excellent gas-sensing properties to formaldehyde gas. At the optimal operating temperature of 250°C, the sensitivity of the sensor based on LaFe0.7Zn0.3O3 to 100ppm formaldehyde is 38, while to other test gases, the sensitivity is all lower than 20. The response and recovery times for the sample to formaldehyde gas are 100s and 100s, respectively.

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