Molybdenum Trioxide (α-MoO<sub>3</sub>) Nanoribbons for Ultrasensitive Ammonia (NH<sub>3</sub>) Gas Detection: Integrated Experimental and Density Functional Theory Simulation Studies

Kwak, Dongwook; Wang, Mengjing; Koski, Kristie J.; Zhang, Liang; Sokol, Henry J.; Marić, Radenka; Lei, Yu

doi:10.1021/acsami.8b20502

Cited by 178 publications

(79 citation statements)

References 67 publications

(80 reference statements)

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“…The response time (15 s) and recovery time (50 s) of the device was less than a minute for 1 ppm TMA in adverse condition (55% RH) at this optimal temperature, which indicates its practical application in TMA sensing. Kwak et al synthesized α‐MoO 3 nanoribbons via a hydrothermal route (as shown in Figure a,b) and found it highly sensitive (sensitivity = 0.72 at 50 ppb ammonia) toward ammonia gas at an optimal temperature of 450 °C 121. The response characteristic of the device (with a 1 V biasing voltage) to wide range of ammonia concentration (50 ppb–10 ppm) is shown in Figure 8c and a theoretical LOD was estimated to be as low as 280 ppt at a signal‐to‐noise ratio of 3.…”

Section: Molybdenum Chalcogenides and Their Sensing Applicationsmentioning

confidence: 99%

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

Jha

Bhat

2020

Adv Materials Inter

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bonding of transition metal and chalcogen atom and their crystal structure. Interestingly, all these compounds exist as layered material except tungsten oxide (WO 3 ) whose hydrated crystal (WO 3 .H 2 O) is layered in nature. [2,3] Each of these chalcogenides possesses unique features. Several micro and nanostructures of these chalcogenides have been synthesized in literature for various applications including gas sensors, biosensors, batteries, supercapacitor, photoelectrochemical and electrochromic devices. However, this review article will focus on gas sensing applications of these materials.Gas sensors play a crucial role in our life as they find applications ranging from monitoring indoor air quality to detecting highly toxic gases. Two important components of a gas sensing device are receptor and transducer. The receptor enables the chemical interaction with the target analyte molecule, which is further converted into analytical signal by the transducer. There are several transduction techniques available in gas sensing based on the physical or chemical change being measured. Broadly, they can be classified into six different classes based on sensing principles which is listed in Table 1.Chemiresistive devices have several advantages over other existing techniques. For example, the structure of these types of devices is very simple and it can be integrated with the current complementary metal oxide semiconductor (CMOS) technology. Even though, several advances have been made over last few years to improve sensing performance, the search for reliable and repeatable gas sensing element is an ongoing endeavor with lots of expectation from tungsten and molybdenum chalcogenides.After the rise of graphene, other layered materials have emerged as important functional materials for various applications of highest scientific values. Among these, layered transition metal dichalcogenides (TMDs) have a special presence as they cover whole class of materials, i.e., ranging from pure insulators to true metals. W and Mo chalcogenides are mostly semiconducting in ambient conditions and therefore, suitable for electronic application such as chemiresistive gas sensors. Though, layered TMDs (MX 2 M = Mo, and W and X = S, Se, and Te) have evolved expeditiously in a very short time, we simply cannot ignore metal oxide (particularly Mo-and W-based Chalcogens are oxygen family elements with oxygen having distinct properties than the other group members like sulfur, selenium, and tellurium. Tungsten and molybdenum chalcogenides that include mainly metal oxides (MO 3 ; M = Mo, and W) and metal dichalcogenides (MX 2 ; X = S, Se, and Te) are the most exciting class of inorganic materials. They have been widely investigated in various applications including lithium and sodium ion storage, supercapacitors, gas sensors, biosensors etc. due to their fascinating surface properties and ease of fabrication. Different class of nanostructures including 0D (nanoparticles, quantum dots), 1D (nanowires, nanotubes, nanoribbons, nanobelts etc.), a...

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Section: Molybdenum Chalcogenides and Their Sensing Applicationsmentioning

confidence: 99%

Section: Molybdenum Chalcogenides and Their Sensing Applicationsmentioning

confidence: 99%

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

Jha

Bhat

2020

Adv Materials Inter

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“…[ 4 ] Recently, MoO 3 nanoribbons based sensors led to a low detection limit of 280 ppt for NH 3 with 72% response at 50 ppb, a short recovery time of 216.9 s and 21 repeatable cycles at an elevated temperature of 450 °C. [ 5 ] MoO 3 /Si nanoparticles based sensors could detect 1 ppm NH 3 with 22% response, and had a detection limit of 400 ppb and 7 min recovery time at 400 °C without repeatability and stability reported. [ 6 ] Pd nanoparticles decorated graphene sensors showed high selectivity toward 100 ppm NH 3 with incomplete recovery even after 25 min at 150 °C.…”

Section: Introductionmentioning

confidence: 99%

“…Most of the sensors above were prepared via lithography, etching, and evaporation processes [ 8,10,12 ] or only their electrodes were prepared by a shadow mask approach. [ 7,9,13 ] Furthermore, their sensing performances for NH 3 were improved by different degrees by extra heating, [ 2–9 ] light illumination [ 10,11 ] or so on, which would undoubtedly cause great inconvenience and/or increase fabrication cost. More unfortunately, use of these extra sources cannot even realize the simultaneous enhancement of overall sensing performances.…”

Section: Introductionmentioning

confidence: 99%

Ultrathin MoO_x/Graphene Hybrid Field Effect Transistor Sensors Prepared Simply by a Shadow Mask Approach for Selective ppb‐Level NH₃ Sensing with Simultaneous Superior Response and Fast Recovery

Falak

Tian

Yan

et al. 2020

Adv Materials Inter

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approaches compatible with the conventional semiconductor processes include patterning, etching, and evaporation, which would give rise to the contamination, the structural and chemical changes, and the damages of the sensing chip surface of sensors due to the unavoidable resist residues and/or thermal and radiative effects during fabrication processes. In sharp contrast, shadow mask approach may be adopted as an alternative of sensor fabrication like gas sensors etc. that could protect the sensing chip surface against the contamination, the unwanted structural and chemical changes, and the damages, which would guarantee a clean sensing chip surface with good enough reactivity with the gas molecules, particularly the one with a weak charge transfer nature like NH 3 . NH 3 , a kind of weak electron donor air pollutant, released as an industrial and combustion waste, is a serious threat to the human health and environment. [1] Many diversified gas sensors based on metal oxides, graphene/reduced graphene oxide (RGO), transition metal dichalcogenides and their reasonable hybrids etc., fabricated in chemiresistor or/and field effect transistor (FET) configurations have been reported for NH 3 detection. For instance, a gas sensor based on atomic layers of MoS 2 shows Both simultaneous achievement of high response, low limit of detection, and full recovery at room temperature (RT) for weak reducing gases like NH 3 and facile and batchable fabrication approach are quite challenging for sensors. Herein, ultrathin MoO x layers are hybridized with mono layer graphene with different coverage percentages, into MoO x /GFET (graphene field effect transistor) devices for selective NH 3 sensing fabricated by a facile, cost effective, and contamination-free shadow mask approach instead of conventional lithography processes. A response of −18.10% for 12 ppm NH 3 with full recovery of 356 s, superior repeatability, low detection limit of 310 ppb, and strong selectivity is simultaneously achieved for MoO x /GFET sensors at RT. The superior sensing and recovery performance of MoO x /GFET sensors is predominantly attributed to the effective tuning of Schottky barrier height and the Coulomb interaction between charged polar donor molecules and positively polarized surface enhanced by the positive bias voltage. The energy band diagrams well explain the sensing mechanism for reducing/oxidizing gases. The idea proposed in this study offers a feasible solution for highly selective sensing of different gases by oxides/graphene hybrid FET based gas sensors with superior RT performances fabricated by a facile, contamination-free, batchable, and generalized approach.A. Falak

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“…Specifically, gas sensor response disturbance towards ammonia is caused by NO x compounds, formed during NH 3 oxidation on the surface of metal oxides . The use of MoO 3 ‐based materials has been proposed for ammonia detection, but considerable sensitivity towards organic compounds has been reported for such systems . Application of Ru‐modification for SnO 2 allows to significantly increase sensor response towards ammonia, but catalytic effect of Ru component also leads to the increase of response towards reducing gases, such as acetone .…”

Section: Introductionmentioning

confidence: 99%

Enhancement of Lewis Acidity of Cr‐Doped Nanocrystalline SnO₂: Effect on Surface NH₃ Oxidation and Sensory Detection Pattern

et al. 2019

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Understanding ammonia oxidation over metal oxide surfaces is crucial for improving its detection with resistive type gas sensors. Formation of NOx during this process makes sensor response and calibration unstable. Cr‐doping of nanocrystalline metal oxides has been reported to suppress NO2 sensitivity and improve response towards NH3, however the exact mechanism of such chromium action remained unknown. Herein, by using EPR spectroscopy we demonstrate formation of Cr(VI) lattice defects on the surface of nanocrystalline Cr‐doped SnO2. Enhancement of Cr‐doped SnO2 surface acidity and ammonia adsorption as a result has been revealed by using in situ IR spectroscopy. Moreover, a decrease in concentration of free electrons in the conduction band has been shown as a result of substitutional Cr(III) defects formation. Weaker NOx chemisorption during ammonia oxidation over SnO2 surface after Cr doping has been found with the use of mass‐spectrometry assisted NH3 thermo‐programmed desorption. The given example of surface acidity adjustment and electronic configuration by means of doping may find use in the design of new gas‐sensing metal oxide materials.

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Molybdenum Trioxide (α-MoO₃) Nanoribbons for Ultrasensitive Ammonia (NH₃) Gas Detection: Integrated Experimental and Density Functional Theory Simulation Studies

Cited by 178 publications

References 67 publications

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

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

Ultrathin MoO_x/Graphene Hybrid Field Effect Transistor Sensors Prepared Simply by a Shadow Mask Approach for Selective ppb‐Level NH₃ Sensing with Simultaneous Superior Response and Fast Recovery

Enhancement of Lewis Acidity of Cr‐Doped Nanocrystalline SnO₂: Effect on Surface NH₃ Oxidation and Sensory Detection Pattern

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Molybdenum Trioxide (α-MoO3) Nanoribbons for Ultrasensitive Ammonia (NH3) Gas Detection: Integrated Experimental and Density Functional Theory Simulation Studies

Cited by 178 publications

References 67 publications

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

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

Ultrathin MoOx/Graphene Hybrid Field Effect Transistor Sensors Prepared Simply by a Shadow Mask Approach for Selective ppb‐Level NH3 Sensing with Simultaneous Superior Response and Fast Recovery

Enhancement of Lewis Acidity of Cr‐Doped Nanocrystalline SnO2: Effect on Surface NH3 Oxidation and Sensory Detection Pattern

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Molybdenum Trioxide (α-MoO₃) Nanoribbons for Ultrasensitive Ammonia (NH₃) Gas Detection: Integrated Experimental and Density Functional Theory Simulation Studies

Ultrathin MoO_x/Graphene Hybrid Field Effect Transistor Sensors Prepared Simply by a Shadow Mask Approach for Selective ppb‐Level NH₃ Sensing with Simultaneous Superior Response and Fast Recovery

Enhancement of Lewis Acidity of Cr‐Doped Nanocrystalline SnO₂: Effect on Surface NH₃ Oxidation and Sensory Detection Pattern