Design and engineering of ionization gas sensor based on Mn nano-flower sculptured thin film as cathode and a stainless steel ball as anode

Savari, Rojan; Savaloni, Hadi; Abbasi, Salar; Placido, Frank

doi:10.1016/j.snb.2018.03.172

Cited by 63 publications

(19 citation statements)

References 35 publications

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“…Field gas ionization system is capable of ionizing the gas molecules by loading a low voltage on the electrodes and is favorable for many potential applications, for example, sensors, , environmental remediation, spectrometry, − and biomedicine . Among them, ionization gas sensors have attracted extensive interest for their advantages like high selectivity and fast response/recovery. , Ionization gas sensing is substantially based on the separation of the positive and negative charges of a gas molecule. , By ionizing the target gas, a specific current–voltage characteristic can be generated as the “fingerprint” of the gas component. , The main disadvantages of traditional bulky ionization gas sensors, for example, high power consumption and risky high operation voltage, hinder their practical application. − Therefore, one-dimensional nanomaterials with ultrasharp tips, for example, carbon nanotubes, as well as ZnO, Si, or CuO nanowires (NWs), − are equipped onto the traditional macroscopic electrodes in order to lower both the operation voltage and the current. Then, intensive studies of decorating the thin film or nanoparticles have been conducted on these nanoelectrodes to further decrease the gas ionization voltages. − However, in contrast to these approaches of additional manufacturing, the study of structural evolution of these microscopic electrodes themselves during the gas ionization is still challenging, and it is worthwhile devoting effort to it, which is strongly associated with the sensing properties of current–voltage ( I – V ) characteristics, repeatability, and stability …”

Section: Introductionmentioning

confidence: 99%

Crystalline-to-Amorphous Phase Transformation in CuO Nanowires for Gaseous Ionization and Sensing Application

et al. 2021

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We report a dramatic reduction of operation voltage of a CuO nanowire-based ionization gas sensor due to the crystalline-to-amorphous phase transformation. The structural change is attributed to the ion bombardment and heating effect during the initial discharge, which brings about the formation of abundant nanocrystallites and surface states favoring gaseous ionization. The gas-sensing properties of the CuO nanowire sensor are confirmed by differentiating various types or concentrations of volatile organic compounds diluted in nitrogen, with a low detection limit at the ppm level. Moreover, a sensing mechanism is proposed on the basis of charge redistribution by electron-gas collision related to the specific ionization energy. The insightful study of the electrode microstructure delivers an exploratory investigation to the effect of gas ionization toward the discharge system, which provides new approaches to develop advanced ionization gas sensors.

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Section: Introductionmentioning

confidence: 99%

Crystalline-to-Amorphous Phase Transformation in CuO Nanowires for Gaseous Ionization and Sensing Application

et al. 2021

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“…Further, it is argued that the ionization gas sensor with micronanoscale materials is a feasible solution to the response saturation and high operating temperature in the technical route above-mentioned . As proposed by Modi’s group and the relevant researches, ,− a typical micro ionization gas sensor (IGS) consists of a micro- or nanostructured electrode and another parallel metal electrode, which could obtain the distinct breakdown voltage ( V b ) to fingerprint the ionization characteristics of gas species under a stepwise voltage sweep. Furthermore, the discharge current in the breakdown region is used to determine the concentration of the target gas. , As for the gas-sensing parameter, V b is intended to be studied mostly in the inorganic gases and their mixtures ,, instead of organic vapors.…”

Section: Introductionmentioning

confidence: 99%

“…As proposed by Modi’s group and the relevant researches, ,− a typical micro ionization gas sensor (IGS) consists of a micro- or nanostructured electrode and another parallel metal electrode, which could obtain the distinct breakdown voltage ( V b ) to fingerprint the ionization characteristics of gas species under a stepwise voltage sweep. Furthermore, the discharge current in the breakdown region is used to determine the concentration of the target gas. , As for the gas-sensing parameter, V b is intended to be studied mostly in the inorganic gases and their mixtures ,, instead of organic vapors. The breakdown process suffering from the degradation and oxidation of electrode materials , might be less suitable for the dynamic detection of the temporal variation of target gases.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, the discharge current in the breakdown region is used to determine the concentration of the target gas. 7,11 As for the gas-sensing parameter, V b is intended to be studied mostly in the inorganic gases and their mixtures 9,10,12 instead of organic vapors. The breakdown process suffering from the degradation and oxidation of electrode materials 13,14 might be less suitable for the dynamic detection of the temporal variation of target gases.…”

Section: ■ Introductionmentioning

confidence: 99%

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MEMS-Based Ionization Gas Sensors for VOCs with Array of Nanostructured Silicon Needles

Wang

Dong

et al. 2020

ACS Sens.

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Although volatile organic compound samples can be detected by gas nanosensors in adsorption principles, extreme concentrations of target gases imply the excessive adsorption, which would lead to a long recovery time and even a shortened lifetime. Herein, we report the observations of the ionization current sensing behavior on the volatile organic compounds in an ionization gas sensor with silicon-based nanostructures. The micro ionization gas sensor consists of a pair of silicon microneedle array electrodes covered by nanolayer structures and a microdischarge gas gap. The dynamic response behaviors of the sensors to the exposure of ethanol, acetone, and 2-chloroethyl ethyl sulfide have been carefully scrutinized. The sensor exhibits sound performances to the high-concentration volatile organic compounds with a fast-recovery property and could generate effective responses well at 36 V, namely, the safety operation voltages. It could be well understood by the Jesse effect where small proportion of impurities in gases could lead to an intensive increase in the overall ionization probability. Besides, the reproducibility, recovery time, sensitivity, and selectivity properties have been systematically characterized.

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“…In these devices, the physical or chemical variation of gases should be measurable by electrical or optical signals [1,2]. On these bases different mechanisms may be used for detection of gases in gas sensors which can be classified as: semiconductor (metal oxide) sensors [3,4], optical sensors [5], field-effect transistor sensors [6], oscillation sensors [7], and sensors whose performance is based on the gas electrical breakdown [8][9][10][11][12][13][14]. The latter sensors are one of the physical sensors whose response depends on the geometrical and physical conditions of the sensor and the gas.…”

Section: Introductionmentioning

confidence: 99%

Design and engineering of Mn conical sculptured thin films as both electrodes for a gas sensor: ionization and field emission studies

Chahshouri¹,

Savaloni²,

Khani³

et al. 2020

J. Micromech. Microeng.

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Paschen’s law and deviation from Paschen’s law are studied in a face to face gas sensor based on Mn helical sculptured thin films with conical shape as cathode and anode electrodes. The sensor’s performance was investigated at dynamic pressures ranging from 0.1 to 1000 mbar and 3 to 200 μm gaps between the two electrodes and for nitrogen, air and carbon monoxide gases. Results showed that at distances more than 10 μm the Paschen’s law is satisfied but at lower than 10 μm distances between the two electrodes and pressures more than 250 mbar deviations occur from the Paschen’s law. Selectivity results of the sensor showed that under all conditions studied in this work and for all gases there is a good resolution between the results and this enhances with gas pressure. Comparison of the results of the present sensor with those reported in the literature showed higher sensitivity of the present work for different gases investigated.

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Design and engineering of ionization gas sensor based on Mn nano-flower sculptured thin film as cathode and a stainless steel ball as anode

Cited by 63 publications

References 35 publications

Crystalline-to-Amorphous Phase Transformation in CuO Nanowires for Gaseous Ionization and Sensing Application

Crystalline-to-Amorphous Phase Transformation in CuO Nanowires for Gaseous Ionization and Sensing Application

MEMS-Based Ionization Gas Sensors for VOCs with Array of Nanostructured Silicon Needles

Design and engineering of Mn conical sculptured thin films as both electrodes for a gas sensor: ionization and field emission studies

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