Reduced Graphene Oxide nano-composites layer on fiber optic tip sensor reflectance response for sensing of aqueous ethanol

Rosli, M. A. A.; Arasu, P. Thillai; Noor, A. S. M.; Lim, Hong Ngee; Huang, Nay Ming

doi:10.1186/s41476-016-0024-6

Cited by 9 publications

(5 citation statements)

References 21 publications

(24 reference statements)

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“…The positions of D-and G-band are significantly dependent on the defects, edges, disorder, grain size and microstructure of the graphene materials. The D-band of graphene indicates to the defects and G-band represents the sp 2 atomic arrangement of carbon atoms of graphene layers [26,27]. The relative intensity ratio ID / IG for rGO was found to be 1.295 indicates the presence of defects in rGO film [28].…”

Section: Methodsmentioning

confidence: 97%

Graphene derivative coated QCM-based gas sensor for volatile organic compound (VOC) detection at room temperature

Gupta

Athirah

Hawari

2020

IJEECS

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<span>Volatile organic compounds (VOCs) affect our daily life through their emission from very common sources such as plants, building materials, paints, pesticides, and fossil fuel burning. The detection of VOCs at room temperature is a prime requirement. The graphene-based gas sensor has the potential to detect these VOC gases due to its attractive features such as high mobility and large surface area. In this work, a graphene-derivative is prepared as a sensing material in order to detect acetone. The thin film of graphene-derivative is prepared by a drop-cast method on a quartz crystal microbalance (QCM) sensor followed by drying in the room environment conditions. The prepared graphene-derivative and thin films are characterized structurally and morphologically by standard microscopic techniques such as FESEM, EDX, and Raman spectroscopy. The electrical parameters such as mobility and resistivity are measured using Hall-effect measurements at room temperature. The response and recovery time of the graphene-derivative based 10 MHz QCM sensor are found to be 23 s and 20 s, respectively. This highly sensitive graphene-based gas sensor with good reversibility can be employed for human health and environment safety applications. </span>

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Section: Methodsmentioning

confidence: 97%

Graphene derivative coated QCM-based gas sensor for volatile organic compound (VOC) detection at room temperature

Gupta

Athirah

Hawari

2020

IJEECS

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“…The S3 peak on the other hand arises from incomplete activated phonon groups [31]. The final peak at 950 cm −1 can be attributed to the second-order Raman scattering effect of silicon [31,32]. The silicon peak is present due to the silicon substrate base which was used during the characterization of the rGO sample, though it has no effect on this work.…”

Section: Characterization Of Reduced Graphene Oxidementioning

confidence: 90%

“…These are identified as the 2D and S3 peaks respectively, with the 2D peak being an overtone of the D peak, and arising due to the sp 2 hybridization of the carbon atoms (C-C) in the graphene nanostructure [30]. The S3 peak on the other hand arises from incomplete activated phonon groups [31]. The final peak at 950 cm −1 can be attributed to the second-order Raman scattering effect of silicon [31,32].…”

Section: Characterization Of Reduced Graphene Oxidementioning

confidence: 99%

Passively Q-switched erbium-doped fiber laser using coated reduced graphene oxide on arc-shaped single mode optical fiber as a saturable absorber

2018

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A passively Q-switched erbium-doped fiber laser is demonstrated using saturable absorbers based on the evanescent light field interaction of reduced graphene oxide deposited on ground arc-shaped fiber. The Q-switched operation started at 32.42 mW with a lowest repetition rate of 34.48 kHz and a pulse width of 5.05 µs. A Q-switched pulse is obtained at different levels of pump power with corresponding repetition rates and pulse widths. From the obtained results, the repetition rate increases from 34.48 kHz to 54.10 kHz; in contrast, the pulse width decreases from 5.01 µs to 2.01 µs. The average output power and pulse energy are increased by enhancing pump power from 32.42 mW to 119.5 mW. Additionally, the fundamental frequency is maintained over time with the signal-to-noise ratio of ~55 dB, thus indicating the Q-switched process is stable over a period of 90 min.

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“…The fiber tips were coated with rGO by drop casting and acted as the sensing layer for ethanol. The reflectance response of the rGO coated fiber tip reduced linearly, upon exposure to ethanol concentrations ranging between 20–80% [ 101 ]. Zhang et al reported a polymer optical fiber with graphene film deposited on the distal end of the optical fiber as an acetone sensor [ 102 ].…”

Section: Graphene-based Optical Sensorsmentioning

confidence: 99%

Graphene-Based Environmental Sensors: Electrical and Optical Devices

Kitadai

Meng

et al. 2021

Molecules

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In this review paper, we summarized the recent progress of using graphene as a sensing platform for environmental applications. Especially, we highlight the electrical and optical sensing devices developed based on graphene and its derivatives. We discussed the role of graphene in these devices, the sensing mechanisms, and the advantages and disadvantages of specific devices. The approaches to improve the sensitivity and selectivity are also discussed.

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Reduced Graphene Oxide nano-composites layer on fiber optic tip sensor reflectance response for sensing of aqueous ethanol

Cited by 9 publications

References 21 publications

Graphene derivative coated QCM-based gas sensor for volatile organic compound (VOC) detection at room temperature

Graphene derivative coated QCM-based gas sensor for volatile organic compound (VOC) detection at room temperature

Passively Q-switched erbium-doped fiber laser using coated reduced graphene oxide on arc-shaped single mode optical fiber as a saturable absorber

Graphene-Based Environmental Sensors: Electrical and Optical Devices

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