Molybdenum Carbide MXenes as Efficient Nanosensors toward Selected Chemical Warfare Agents

Panigrahi, Puspamitra; Pal, Yash; Kaewmaraya, Thanayut; Bae, Hyeonhu; Nasiri, Noushin; Hussain, Tanveer

doi:10.1021/acsanm.3c00686

Cited by 7 publications

(4 citation statements)

References 65 publications

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“…MXenes are two-dimensional (2D) metal carbides, nitrides, and carbonitrides with the general formula M n +1 X n T x , where M is an early transition metal, such as Ti, Mo, V, Nb, and Ta; X denotes carbon and/or nitrogen; T x represents surface functional groups (such as −OH, =O, and −F); and n = 1–4. − MXenes are derived from three-dimensional (3D) M n +1 AX n (MAX)-phase crystals by selective chemical etching of “A” elements such as Al, Si, or Ga under strongly acidic or basic conditions. ,− MXenes exhibit a unique combination of properties, such as excellent metallic conductivity, − strong hydrophilicity, ,, considerable flexibility, , tunable surface chemistry, and adjustable electronic characteristics. − Consequently, they are promising materials for various applications including energy storage and conversion, , − electromagnetic interference shielding, − water purification, , catalysis, − thermoelectricity generation, , and sensing. − …”

Section: Introductionmentioning

confidence: 99%

Oxidation of Molybdenum-Based Single-Metallic/bimetallic Carbide MXenes in Aqueous Suspensions: Mechanistic Insights

Hussain,

Chae,

Iqbal

et al. 2024

Langmuir

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Molybdenum carbide MXenes have garnered considerable attention in electronics, energy storage, and catalysis. However, they are prone to oxidative degradation, but the associated mechanisms have not been systematically explored. Therefore, the oxidation mechanisms of Mo-based single-metallic/ bimetallic carbide MXenes including Mo 2 CT x , Mo 2 TiC 2 T x , and Mo 2 Ti 2 C 3 T x in aqueous suspensions were investigated for the first time in this study. Similar to Ti 3 C 2 T x MXene, Mo-based MXenes were found to undergo oxidative degradation in their aqueous dispersions, leading to the disruption of their crystal structure and subsequent loss of optical and electronic properties. Notably, the Mo 2 CT x MXene deviated from this typical oxidation behavior as it produced an amorphous product with Mo ions instead of highly crystalline Mo-oxides during oxidation. Similarly, the Mo 2 TiC 2 T x and Mo 2 Ti 2 C 3 T x MXenes did not yield crystalline Mo-oxides; instead, they produced highly crystalline anatase TiO 2 and a Mo-ion-containing amorphous product simultaneously. Furthermore, high-temperature annealing of the oxidized Mo 2 CT x MXene powder at 800 °C transformed the amorphous Mo-containing product into highly crystalline MoO 2 crystals. These findings highlight the unconventional oxidation behavior of Mo-based MXenes, which suggests that the formation of crystalline Mo-based oxides requires a higher activation energy during oxidation than that of TiO 2 . The unique oxidative pathway reported herein can help elucidate the oxidation mechanisms of Mo-based MXene dispersions and their products. The insights from this study can pave the way for fundamental studies in academia as well as broaden the applications of Mo-based MXenes in various industries.

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Section: Introductionmentioning

confidence: 99%

Oxidation of Molybdenum-Based Single-Metallic/bimetallic Carbide MXenes in Aqueous Suspensions: Mechanistic Insights

Hussain,

Chae,

Iqbal

et al. 2024

Langmuir

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“…Bestowed with unique electrical, electronic, optical, and transport properties, two-dimensional (2D) nanostructures have emerged as promising candidates in numerous scientific fields, including nanoelectronics, optoelectronics, spintronics, battery-energy materials, sensing, and even in biomedical applications. − These single to few atom thick layered 2D structures, with high aspect ratios, tuned band gaps, and high surface reactivities are the most attractive candidates for sensing various toxic gas molecules, VOCs, chemical warfare agents (CWAs), and various biological molecules. , Various graphene-like 2D materials with tweaked electronic properties are being reported as efficient materials for sensing toxic gases. , Besides, beyond graphene with high carrier mobility and ionic conductivity, , various 2D transition metal dichalcogenides, − and the modeled sheets from group 15 materials like bismuthene, phosphorene, and arsenene, are investigated progressively for their sensing propensity toward various toxic gases and biomolecules.…”

Section: Introductionmentioning

confidence: 99%

Identification of Lung Cancer Biomarkers by Nanosensors Based on Titanium Carbide (Ti₃C₂T_x) MXenes

Panigrahi,

Vovusha,

Pal

et al. 2023

ACS Appl. Nano Mater.

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Inspired by the importance of early diagnosis of lung cancer, which is responsible for the most cancer-related deaths worldwide, we propose a nanosensor based on titanium carbide MXenes (Ti3C2T x ; T x = O, S, F, and OH) capable of detecting selected volatile organic compounds (VOCs) from human breath. A set of representative VOCs, such as 2,3,4-trimethylhexane (C9H20), aniline (C6H7N), ethylbenzene (C8H10), isoprene (C5H8), and o-toluidine (C7H9N), are selected and their adsorption mechanism with Ti3C2T x has been studied comprehensively by means of first-principles density functional theory calculations. Van der Waals-induced simulations reveal the range of adsorption energies of C9H20 (−0.766 to −0.878) C6H7N (−0.663 to −1.02), C8H10 (−0.653 to −0.877), C5H8 (−0.505 to −3.49), and C7H9N (−0.691 to −1.15 eV) on Ti3C2F2, Ti3C2O2, Ti3C2(OH)2, and Ti3C2S2, respectively. Intrinsic mechanisms of VOCs adsorption and the corresponding changes in the electronic properties of Ti3C2T x are studied through charge analysis, density of states, electrostatic potentials, and work function calculations. Further, the sensing behavior of the VOCs with Ti3C2T x has been explored through statistical thermodynamic analysis for practical applications. Our results clearly show that Ti3C2T x MXenes hold great potential as efficient nanosensors for the detection of VOCs related to lung cancer diagnosis at an early stage.

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“…Different from the accordion-like structure of other MXenes, the as-fabricated Mo 2 C MXene with a hexagonal crystal structure is consisted of thick lamellae stacked together by Van der Waals forces. [56][57][58] Thus, additional exfoliation procedure is necessary to obtain dispersed single-layer Mo 2 C MXene (Figure 1B). [59,60] Generally, the as-obtained Mo 2 C MXene is composed of the gathered Mo-C-Mo layers through the interlinked Mo-C bonds, which endows Mo 2 C MXene with a typical nanosheet structure with superior physical character.…”

Section: Introductionmentioning

confidence: 99%

2D Molybdenum Carbide MXene Cocatalyst: Synthesis, Modification, and Photocatalysis

Ke,

Pan,

Liu

et al. 2023

Solar RRL

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Photocatalytic technology is considered as one of effective approaches to address increasingly serious problems of environment and energy. To boost the photocatalytic efficiency, the innovative cocatalysts have been extensively explored and investigated in recent years. Mo2C MXene as a new two‐dimensional (2D) layer cocatalyst is gained increasing attentions for promoting photocatalytic performance owing to high specific surface area, excellent hydrophilic surface, outstanding metallic conductivity, and flexible adjustability of Mo sites. However, compared with the traditional Ti3C2 MXene cocatalyst, Mo2C MXene has not been fully investigated and systematically summarized in the published articles in the photocatalytic field. In this review, the recent advances about synthesis, modification, photocatalytic applications and our outlook of the Mo2C MXene cocatalyst are comprehensively summarized. First, the synthetic methods of Mo2C MXene are introduced, including top‐down route and down‐top route. Moreover, four modification strategies (constructing heterojunction, doping heteroatom, controlling morphology, and modifying termination) of Mo2C MXene are illustrated. Subsequently, the photocatalytic applications of Mo2C MXene cocatalyst in H2 production, CO2 reduction, and pollutants degradation are thoroughly discussed. Finally, the crucial challenges and important outlooks of Mo2C MXene cocatalysts for photocatalytic solar‐to‐fuel conversion are proposed to deliver novel insights and design high‐efficiency Mo2C MXene cocatalyst‐modified photocatalysts.This article is protected by copyright. All rights reserved.

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Molybdenum Carbide MXenes as Efficient Nanosensors toward Selected Chemical Warfare Agents

Cited by 7 publications

References 65 publications

Oxidation of Molybdenum-Based Single-Metallic/bimetallic Carbide MXenes in Aqueous Suspensions: Mechanistic Insights

Oxidation of Molybdenum-Based Single-Metallic/bimetallic Carbide MXenes in Aqueous Suspensions: Mechanistic Insights

Identification of Lung Cancer Biomarkers by Nanosensors Based on Titanium Carbide (Ti₃C₂T_x) MXenes

2D Molybdenum Carbide MXene Cocatalyst: Synthesis, Modification, and Photocatalysis

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Molybdenum Carbide MXenes as Efficient Nanosensors toward Selected Chemical Warfare Agents

Cited by 7 publications

References 65 publications

Oxidation of Molybdenum-Based Single-Metallic/bimetallic Carbide MXenes in Aqueous Suspensions: Mechanistic Insights

Oxidation of Molybdenum-Based Single-Metallic/bimetallic Carbide MXenes in Aqueous Suspensions: Mechanistic Insights

Identification of Lung Cancer Biomarkers by Nanosensors Based on Titanium Carbide (Ti3C2Tx) MXenes

2D Molybdenum Carbide MXene Cocatalyst: Synthesis, Modification, and Photocatalysis

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Identification of Lung Cancer Biomarkers by Nanosensors Based on Titanium Carbide (Ti₃C₂T_x) MXenes