Impact of Oxygen Functional Groups on Reduced Graphene Oxide-Based Sensors for Ammonia and Toluene Detection at Room Temperature

Minitha, Cherukutty Ramakrishnan; Anithaa, V. S.; Vijayakumar, S.; Kumar, Ramasamy Thangavelu Rajendra

doi:10.1021/acsomega.7b02085

Cited by 68 publications

(37 citation statements)

References 29 publications

(57 reference statements)

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“…The reason for this may be the structural dominance of graphene sheets over the disordered areas, which causes lowering of the intensity of D-band. 42−45 For GO batch prepared using Marcano’s approach, the I D / I G ratio was determined as 1.18, which is lower compared to the I D / I G ratio for the GO (6 h) batch.…”

Section: Resultsmentioning

confidence: 99%

Simple Synthesis of Large Graphene Oxide Sheets via Electrochemical Method Coupled with Oxidation Process

2018

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In this paper, we report a simple two-step approach for the synthesis of large graphene oxide (GO) sheets with lateral dimensions of ≈10 μm or greater. The first step is a pretreatment step involving electrochemical exfoliation of graphite electrode to produce graphene in a mixture of H 2 SO 4 and H 3 PO 4 . The second step is the oxidation step, where oxidation of exfoliated graphene sheets was performed using KMnO 4 as the oxidizing agent. The oxidation was carried out for different times ranging from 1 to 12 h at ∼60 °C. Prepared GO batches were characterized using a number of spectroscopy and microscopy techniques such as X-ray diffraction (XRD), field emission scanning electron microscopy (FE-SEM), transmission electron microscopy (TEM), Fourier-transform infrared spectroscopy (FTIR), and UV–visible spectroscopy. Raman and thermogravimetric analysis techniques were used to study the degree of oxidation in the as-synthesized GO batches. The UV–visible absorption spectrum showed an intense peak at 230 nm and an adjacent band at 300 nm corresponding to π–π* and n−π* transitions in all samples. Normalized FTIR plots were used to calculate the relative percentages of oxygen-containing functional groups, which were found to be maximum in GO (6 h). Boehm titration was used to quantify the functional groups present on the GO surface. Overall GO sheets obtained after 6 h of oxidation, GO (6 h), were found to be the best. XRD pattern of GO (6 h) revealed a characteristic peak at 2θ = 8.88°, with the corresponding interplanar spacing between the layers being 0.995 nm, which is among the best with respect to the previous methods reported in the literature. Raman spectroscopy showed that the degree of defect ( I D / I G ) area ratio for GO (6 h) was 1.24, which is higher than that obtained for GO (1.18) prepared by widely used Marcano’s approach.

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Section: Resultsmentioning

confidence: 99%

Simple Synthesis of Large Graphene Oxide Sheets via Electrochemical Method Coupled with Oxidation Process

2018

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“…Defect sites on graphene and graphene oxide act as suitable adsorption sites for various analytes, and it was reported that an increase in the I D /I G ratio generally results in improved gas sensing ability for graphene-based sensors. [20,49,50] The interplanar distance of the stacked GO sheets was determined by X-ray diffraction (XRD) as shown in Figure 4b. The 1.5 h GO has a slightly larger interplanar distance of 0.887 nm compared to 0.845 nm of the 1 h GO.…”

Section: Resultsmentioning

confidence: 99%

Nanomechanical Gas Sensing with Laser Treated 2D Nanomaterials

Mistry

Ibrahim

Novodchuk

et al. 2020

Adv Materials Technologies

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which is reflected in the sheer number of review articles on the topic. [1-9] Detection of VOCs in exhaled breath has been particularly useful for the diagnosis of a broad range of diseases such as diabetes, liver and lung disorders, and different forms of cancer. [10] 2D nanomaterials such as graphene oxide (GO), molybdenum disulfide (MoS 2), and tungsten disulfide (WS 2) are viable candidates for use in chemical gas sensors due to their large specific surface area that can be tailored for analyte adsorption. 2D nanomaterials have been primarily used for the detection of toxic gasses and pollutants such as nitrogen dioxide (NO 2), hydrogen disulfide (H 2 S), carbon monoxide (CO), and carbon dioxide (CO 2), [1-3,11] while the detection of VOCs by these materials has been limited. GO, [12,13] MoS 2 , [14,15] and WS 2 [16,17] have all shown a response to water vapor or relative humidity changes. Without the aid of other compounds or dopants, graphene oxide has shown a response to ethanol [18,19] and toluene vapors. [20] Similarly, MoS 2 and WS 2 have shown a response to vapors of ethanol, acetone, hexane, toluene, and benzene. [21-23] In most of these reports, the sensing material is casted over a set of interdigitated electrodes to form a chemoresistive sensor. The interaction between analyte vapors and the sensing material (i.e., through

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“…(28) The advantage of rGO over monolayer defect-free graphene is the presence of dangling oxygen functional groups on the graphene surface and edges. (65) Both theoretical and experimental results revealed that tuning of the oxygen functional groups on rGO plays a vital role in the detection of several organic compounds. Experimentally, oxygen functional groups can be tuned by adjusting the reduction time, the type of reducing agent, and the environment of reduction.…”

Section: Chemical Oxidation-reduction Methods For Graphitementioning

confidence: 99%

“…As reported by Minitha et al, the concentration of oxygen functional groups of rGO can be controlled by the aging time during the reduction process with hydrazine hydrate. (65) A higher concentration of oxygen functional groups yields a higher sensing response but poor recovery of the sensor. The sensor has difficulty in recovering its initial state since there are now more anchored functional groups in the graphene sheet, thus the recovery treatment should be several times higher.…”

Section: Detection Of Common Organic Vaporsmentioning

confidence: 99%

Graphene-based Materials in Gas Sensor Applications: A Review

Demon¹,

Kamisan²,

Abdullah³

et al. 2020

Sensors and Materials

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Graphene and chemically modified graphene can be fabricated via numerous routes each with its own merits concerning ease of processability, cost-effectiveness for large-scale production, and also health and safety. One of the promising applications of graphene-based composites is gas sensing, which is mainly useful for environmental monitoring. We review some of the significant findings on graphene-based sensing materials for the detection of organic vapors, toxic gases, and chemical warfare agent simulants using an electrochemical method. Electrochemical sensing can be performed by inducing interactions between gas molecules and a graphene layer, such as charge transfer that gives a change in an electrical signal. The intrinsic properties of graphene and its role in some gas sensing applications will be discussed. Graphene and graphene oxide (GO) work as continuous conductive networks with a large number of surface adsorption sites for many gas molecules. Hybrid graphene devices incorporate semiconductors, metals, and molecular binders to enhance the capabilities of solidstate gas sensors. This article also addresses current approaches to the commercialization of graphene-based gas sensors.

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Impact of Oxygen Functional Groups on Reduced Graphene Oxide-Based Sensors for Ammonia and Toluene Detection at Room Temperature

Cited by 68 publications

References 29 publications

Simple Synthesis of Large Graphene Oxide Sheets via Electrochemical Method Coupled with Oxidation Process

Simple Synthesis of Large Graphene Oxide Sheets via Electrochemical Method Coupled with Oxidation Process

Nanomechanical Gas Sensing with Laser Treated 2D Nanomaterials

Graphene-based Materials in Gas Sensor Applications: A Review

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