Recent Progress in Chemiresistive Gas Sensing Technology Based on Molybdenum and Tungsten Chalcogenide Nanostructures

Jha, RM; Bhat, Navakanta

doi:10.1002/admi.201901992

Cited by 42 publications

(24 citation statements)

References 277 publications

(235 reference statements)

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“…CNTs, graphene or reduced graphene oxides (rGOs), transition metal dichalcogenides (TMDs), and 2D early-transition metal carbides and nitrides (MXenes) are emerging chemiresistors that can be used in artificial olfaction in the future. Because there have been many reviews on the sensing mechanisms and applications of gas sensors using CNTs, [448][449][450][451] graphene-based materials, [451][452][453][454][455][456][457][458][459][460][461] and TMDs, [452,458,[460][461][462][463] the main focus of this section will be placed on the control of gas selectivity and the design of artificial olfaction. The target gases and the operation temperatures of pristine, noble-metal-loaded, and metaloxide-loaded sensors using CNTs, graphene-based materials, and TMDs are analyzed based on recent publications in the literature (Figure 15) (sensors using graphene and rGO: publications since 2016, sensors using CNTs and TMDs: publications since 2010).…”

Section: Emerging Sensing Materials For Artificial Olfactionmentioning

confidence: 99%

Rational Design of Semiconductor‐Based Chemiresistors and their Libraries for Next‐Generation Artificial Olfaction

2020

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With rapid progress in device integration and computing power, the realization of highly miniaturized one-chip artificial olfaction with superior performance is close and should be further supported by the rational design of chemical sensors and chemical sensing materials. The number of gas sensors tends to increase in order to sniff more complex odors with the progress of civilization. This explains the evolution from a single chemical sensor to complicated artificial olfaction using sensor arrays. At the advent of oxide chemiresistive gas sensors in the 1960s and 1970s, a single gas sensor was widely used to detect toxic, explosive, dangerous, and harmful gases, such as CO, C 3 H 8 , CH 4 , H 2 S, and NO 2 , in a selective manner. [26,27] However, a single sensor is often insufficient for recognizing most of the natural odors encountered in daily life, which consist of hundreds to thousands of different chemicals. [28] In the mammalian olfactory system, odorants are initially detected by olfactory receptors (ORs) covering the surface of the cilia projected from olfactory sensory neurons (OSNs), which are located in the olfactory epithelium lining the nasal cavity. These signals are transmitted to the glomeruli in the olfactory bulb, where a high degree of signal integration happens (Figure 1a). [29] Finally, the signals are sent through mitral cells to a higher brain region (olfactory cortex), and the signals are subsequently combined or modified in a variety of ways by parallel processing for analysis and interpretation (Figure 1b). [30] Each OR can detect various kinds of odorants, and similarly, each odorant can also be recognized by a number of ORs. That is, the olfactory system determines multiple odorants from various combinations of ORs (Figure 1c). [31] For better olfaction, both OSNs and ORs should be abundant. A larger number of OSNs is advantageous for detecting trace concentrations of analytes and ligands. [32] For instance, dogs with more OSNs are better than humans at detecting explosives, searching and rescuing, diagnosing disease, and assessing agricultural products. [33] If a mammal can detect larger numbers of faint gas components within odors, he can perceive and identify the odors more accurately. From this perspective, gas sensors with lower detection limits would be assembled to the stronger artificial olfaction. Kinds of ORs are also important. Mammals are known to have ≈1000 different kinds of ORs, and combinations of dissimilar ORs enable the discrimination of a myriad of odorants. [29] To mimic this, sensor arrays consisting of small number (5-20) of sensors that show Artificial olfaction based on gas sensor arrays aims to substitute for, support, and surpass human olfaction. Like mammalian olfaction, a larger number of sensors and more signal processing are crucial for strengthening artificial olfaction. Due to rapid progress in computing capabilities and machinelearning algorithms, on-demand high-performance artificial olfaction that can eclipse human olfaction becomes inevitable onc...

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Section: Emerging Sensing Materials For Artificial Olfactionmentioning

confidence: 99%

Rational Design of Semiconductor‐Based Chemiresistors and their Libraries for Next‐Generation Artificial Olfaction

2020

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“…), chalcogenides (MoSe2, WS2, WSe2, etc. ), and a few perovskite-like crystals have been acknowledged for sensing applications 33,142,143 . The 2-D materials are strong adsorbents to organic molecules, and at high temperatures, they tend to partially lose oxygen to become oxygen-deficient and so are considered as the most suitable candidates in VOCs sensing 144 .…”

Section: Two-dimensional (2-d) Moo3 Nanostructures For Gas Sensormentioning

confidence: 99%

Advances in the designs and mechanisms of MoO₃ nanostructures for gas sensors: a holistic review

2021

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“…TMCs are promising candidates for a wide range of applications such as nanoelectronics, sensors, and energy applications. [1,[11][12][13][14][15][16][17][18][19] In particular, sulfides and selenides of Group 6 elements (e.g., molybdenum and tungsten) with semiconducting properties have been widely investigated for application in nanoelectronics and sensors. [15,16,[20][21][22] The unique bandgap transition achieved by changing the number of 2D layers has drawn significant attention and ignited extensive research interest in various optoelectronic applications.…”

Section: Introductionmentioning

confidence: 99%

Atomic‐Layer‐Deposition‐Based 2D Transition Metal Chalcogenides: Synthesis, Modulation, and Applications

et al. 2021

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V, Fe, Co, and Ni chalcogenides exhibit diverse stoichiometric phases with different electrical properties. [28][29][30] For example, TiS 3 is a semiconductor, while TiS 2 exhibits metallic properties. [30,31] Owing to their electrical conductivity, metallic TMCs can be used for energy conversion (including the hydrogen evolution reaction (HER) and oxygen evolution reaction (OER)) and energy storage (Li-ion batteries (LIBs), Na-ion batteries (NIBs), and supercapacitors). [29,32] Industrially compatible synthesis methods and applications are of key importance in the research of new materials. Therefore, atomic layer deposition (ALD)-based 2D TMC materials, which are applicable in industries, have been investigated. [33][34][35][36] Initially, 2D TMCs were mechanically exfoliated to determine their single-crystal characteristics. [11,20] However, the large-area synthesis and control of the layer number of TMCs are crucial. [2,37] ALD, which is a suitable synthesis method for 2D TMCs, is based on the surface reactions of the alternately supplied vapor-phase precursors. [38,39] Because it is one of the most powerful deposition methods for synthesizing uniform thin films on large areas, the next-generation low-power/ high-efficiency electronic and energy applications of materials synthesized/modified by ALD processes have been studied. [38,39] For industrial applications, the electrical, optical, and physical properties of 2D TMCs need to be improved. [18,[40][41][42][43] In addition to the synthesis of 2D TMCs, the ALD method can be used to modify 2D TMCs. In particular, the performance of 2D TMCs can be improved by depositing other materials on 2D TMCs via ALD. [44] By depositing metal oxide thin films or metal nanoparticles on 2D TMCs by ALD, the electrical properties of 2D TMC materials can be precisely controlled, the catalyst efficiency can be modulated, and strain can be induced to change the physical properties of the 2D TMCs. [45][46][47] However, because of their unique structures, ALD on 2D TMCs is quite challenging. For example, the film growth behavior on 2D TMCS is significantly different from the film growth behavior on 3D materials during ALD because of the absence of chemical sites on 2D TMCs. [48][49][50][51] Therefore, for thin film deposition on 2D TMCs by ALD, researchers have focused on improving the uniformity of thin films or synthesizing low-dimensional nanomaterials on 2D TMCs.Herein, the synthesis of 2D TMCs by ALD is reviewed and the synthesis methods are classified based on different types of ALD methods. The synthesis of TMCs by the ALD of transition Transition metal chalcogenides (TMCs) are a large family of 2D materials with different properties, and are promising candidates for a wide range of applications such as nanoelectronics, sensors, energy conversion, and energy storage. In the research of new materials, the development and investigation of industry-compatible synthesis techniques is of key importance. In this respect, it is important to study 2D TMC materials synthesized by th...

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Recent Progress in Chemiresistive Gas Sensing Technology Based on Molybdenum and Tungsten Chalcogenide Nanostructures

Cited by 42 publications

References 277 publications

Rational Design of Semiconductor‐Based Chemiresistors and their Libraries for Next‐Generation Artificial Olfaction

Rational Design of Semiconductor‐Based Chemiresistors and their Libraries for Next‐Generation Artificial Olfaction

Advances in the designs and mechanisms of MoO₃ nanostructures for gas sensors: a holistic review

Atomic‐Layer‐Deposition‐Based 2D Transition Metal Chalcogenides: Synthesis, Modulation, and Applications

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Recent Progress in Chemiresistive Gas Sensing Technology Based on Molybdenum and Tungsten Chalcogenide Nanostructures

Cited by 42 publications

References 277 publications

Rational Design of Semiconductor‐Based Chemiresistors and their Libraries for Next‐Generation Artificial Olfaction

Rational Design of Semiconductor‐Based Chemiresistors and their Libraries for Next‐Generation Artificial Olfaction

Advances in the designs and mechanisms of MoO3 nanostructures for gas sensors: a holistic review

Atomic‐Layer‐Deposition‐Based 2D Transition Metal Chalcogenides: Synthesis, Modulation, and Applications

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Advances in the designs and mechanisms of MoO₃ nanostructures for gas sensors: a holistic review