Investigation on visible light assisted gas sensing ability of multi-walled carbon nanotubes coated with pyrene based organic molecules

Elakia, Manoharan; Marappan, Gobinath; Sivalingam, Yuvaraj; Elumalai, Palani; Ghosh, Soumyajit; Venkatramaiah, N.; Surya, Velappa Jayaraman

doi:10.1016/j.physe.2020.114232

Cited by 19 publications

(19 citation statements)

References 42 publications

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“…6 Elakia and co-workers have investigated the gas sensing properties of pyrene containing −COOH functionality coated on multiwalled carbon nanotubes under visible light and observed that−COOH groups in pyrene show strong intermolecular hydrogen bonding through D−A interaction, thus furnishing a high selectivity for TEA with good response and recovery. 7 Recently, we have reported on the polymorphism-induced gas adsorption on the surface of the naphthalic dimide adorned phenothiazine unit, demonstrating that surface morphology and interaction sites induce selective photoresponse toward VOCs. 8 Tuning the D− A architecture with different donor and acceptors with better overlapping of electron density leads to a selective response to the VOCs, and fast recovery is attainable.…”

Section: Introductionmentioning

confidence: 99%

“…Marappan et al have demonstrated that the gas adsorption behavior of naphthalene appended DPP molecules functionalized with ZnO nanostructures prepared at different pHs (pH 9 and 11) showed a higher photoresponse toward 1-hexanol at pH 11 . Elakia and co-workers have investigated the gas sensing properties of pyrene containing −COOH functionality coated on multiwalled carbon nanotubes under visible light and observed that–COOH groups in pyrene show strong intermolecular hydrogen bonding through D–A interaction, thus furnishing a high selectivity for TEA with good response and recovery . Recently, we have reported on the polymorphism-induced gas adsorption on the surface of the naphthalic dimide adorned phenothiazine unit, demonstrating that surface morphology and interaction sites induce selective photoresponse toward VOCs .…”

Section: Introductionmentioning

confidence: 99%

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Tuning the π-Conjugation of 2-Thiohydantoins toward a Rigorously Defined Detection of Volatile Organic Compounds by Surface Photovoltage

Gawas

Bora

Reji

et al. 2022

ACS Appl. Electron. Mater.

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The design of portable devices by immobilization of sensory probes using donor−acceptor (D−A) architectures enables the visual detection and onsite analysis of volatile organic compounds (VOCs). In this work, we have reported on the synthesis of different D−A architectures of 2-thiohydantoin (2TH) derivatives by extending the conjugation with phenyl (Ph-2TH), naphthalene (Naptha-2TH), and anthracene (Anthra-2TH) moieties at the C 5 position. Single-crystal X-ray analysis reveals that extending the conjugation leads to variation in the molecular arrangement in the crystal lattice. Ph-2TH and Naptha-2TH show ribbon-like self-assembled layered arrangements, whereas Anthra-2TH crystallized in herringbone packing in the crystal lattice. The C−S•••H interactions were varied with interatomic distances of 2.67, 2.63, and 2.27 Å, respectively, for phenyl, naphthalene, and anthracene. The photophysical and excited-state gas-phase interactions using scanning kelvin probe studies reveal that 2TH ensembles alter their surface photovoltages toward recognition of different VOCs (like ethanol, acetone, toluene, triethylamine, nonanal, and chloroform) depending on their donor and acceptor nature. All three 2TH derivatives showed n-type behavior with high selectivity toward nonanal, and Anthra-2TH exhibited high response (91.02%) within 278 s as well as recovery (92.83%) in surface photovoltages in 647 s. Combined experimental and computational studies demonstrate that the aromatic moieties appended 2TH ensembles would be an efficient D−A ensemble for the detection of VOCs containing carbonyl and alcohol functionalities aiding strong intermolecular interactions.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tuning the π-Conjugation of 2-Thiohydantoins toward a Rigorously Defined Detection of Volatile Organic Compounds by Surface Photovoltage

Gawas

Bora

Reji

et al. 2022

ACS Appl. Electron. Mater.

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“…The schematic illustration of SKP measurement setup is shown in figure 2a. The complete principle and working of SKP system is explained in our previous papers [18][19][20]. There are changes in CPD based on VOCs adsorption on the substrate (Fig.…”

Section: Resultsmentioning

confidence: 99%

Graphene Oxide based Gas Sensor for Triethylamine Detection at Room Temperature

Abbas

Marappan

Chidabaram

et al. 2022

IOP Conf. Ser.: Mater. Sci. Eng.

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We have developed a graphene oxide (GO) based sensor to detect triethylamine at room temperature. GO is synthesized by modified Hummer’s method and spin-coated on fluorine-doped tin oxide (FTO) substrate. Structural and morphological characterizations of GO are done by XRD and FE-SEM. Sheet-like morphology of GO is observed in FESEM images. The existence of defects is confirmed by Raman spectra with a ID/IG ratio ∼ 0.94. Gas adsorption studies are carried out using scanning Kelvin probe system with various volatile organic compounds (VOCs) like ethanol, acetone, n-hexane and triethylamine. Among them, GO shows more contact potential difference (CPD) response towards triethylamine. Then, a gas sensor device is fabricated using GO and its electrical characterization is done by I-V measurements. The device shows ohmic behavior with a resistance of ∼ 50 MΩ. Thereafter, the sensor is exposed to triethylamine from 19 to 151 ppm and the sensitivity is 1.39 x 10−4 ppm−1. Interestingly, a fast response time of 11 sec is achieved at room temperature.

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“…These materials have been shown to be more effective in producing higher VOC sensors. − Three steps commonly take place in gas sensors manufactured using CNMs for VOC detection: (i) trapping of VOC gas, (ii) their interaction with the sensing active site, and (iii) dispersing of the VOC gas. Focusing on the complex interactions between the VOC gas and the active center that detects them, CNMs have been used to create a range of VOC gas sensors, including optical ,− and microgravimetric ones. − Regarding optical sensors, spectrometric or colorimetric variations in the sensing materials are brought on by the intermolecular interactions among VOC samples and the active center ,− and resistance-based sensors. ,,− …”

Section: Sensing Of Vocsmentioning

confidence: 99%

“…The presence of π-electron conjugation results in high charge transfer in carbon-based materials . Generally, the detection of VOCs is governed by their interaction with carbon-based materials by diffusion and sensed by the active center of carbon-based materials, − microgravimetric sensors, − and resistive sensors. − When a molecule species interacts with the sidewalls of carbon-based or any semiconductor materials during gas detection, changes in conductance , (due to charge transfer or mobility change) or capacitance (from inherent or induced dipole moments) occur. − The interaction between the VOCs and carbon-based compounds (rGO, CNTs, and CDs) depends strongly on the architecture and design of the composites or materials which may have a larger contact area, thus allowing greater sensitivity. The CNT has two variables, SWCNT and MWCNT.…”

Section: Sp2-hybridized Electronic Behavior For Sensingmentioning

confidence: 99%

Carbon Nanostructure Embedded Novel Sensor Implementation for Detection of Aromatic Volatile Organic Compounds: An Organized Review

Nath

Kumar

Chakroborty³

et al. 2023

ACS Omega

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For field-like environmental gas monitoring and noninvasive illness diagnostics, effective sensing materials with exceptional sensing capabilities of sensitive, quick detection of volatile organic compounds (VOCs) are required. Carbon-based nanomaterials (CNMs), like CNTs, graphene, carbon dots (Cdots), and others, have recently drawn a lot of interest for their future application as an elevated-performance sensor for the detection of VOCs. CNMs have a greater potential for developing selective sensors that target VOCs due to their tunable chemical and surface properties. Additionally, the mechanical versatility of CNMs enables the development of novel gas sensors and places them ahead of other sensing materials for wearable applications. An overview of the latest advancements in the study of CNM-based sensors is given in this comprehensive organized review.

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Investigation on visible light assisted gas sensing ability of multi-walled carbon nanotubes coated with pyrene based organic molecules

Cited by 19 publications

References 42 publications

Tuning the π-Conjugation of 2-Thiohydantoins toward a Rigorously Defined Detection of Volatile Organic Compounds by Surface Photovoltage

Tuning the π-Conjugation of 2-Thiohydantoins toward a Rigorously Defined Detection of Volatile Organic Compounds by Surface Photovoltage

Graphene Oxide based Gas Sensor for Triethylamine Detection at Room Temperature

Carbon Nanostructure Embedded Novel Sensor Implementation for Detection of Aromatic Volatile Organic Compounds: An Organized Review

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