Graphene-enhanced Raman scattering on single layer and bilayers of pristine and hydrogenated graphene

Valeš, Václav; Drogowska-Horná, Karolina; Guerra, Valentino L. P.; Kalbáč, Martin

doi:10.1038/s41598-020-60857-y

Cited by 22 publications

(15 citation statements)

References 54 publications

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“…Material Synthesis: As reported previously, SLG was grown via the standard CVD method. [19] In brief, a copper foil was at 1000 °C for 30 min under a 50 sccm hydrogen flow. Subsequently, CH 4 (1 sccm) was introduced into the chamber for 20 min.…”

Section: Methodsmentioning

confidence: 99%

“…Partially hydrogenated graphene samples were prepared in a high‐pressure autoclave as described in an earlier study. [ 19 ] The autoclave was flushed several times with hydrogen to remove the air. Then, the autoclave was filled with hydrogen at a pressure of 5 bar.…”

Section: Methodsmentioning

confidence: 99%

“…Quite recently, we have shown different GERS enhancements utilizing chemically modified graphene, which have different levels of doping. [ 19 ] However, graphene possesses a tunable work function with the application of external potential. [ 20 ] Utilizing this property, an electrochemical GERS sensor has huge potential to circumvent the rigid energy‐specific basis of the enhancement.…”

Section: Introductionmentioning

confidence: 99%

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Toward Graphene‐Enhanced Spectroelectrochemical Sensors

Kaushik

Sonia

Haider

et al. 2022

Adv Materials Inter

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The SERS effect arises mainly from electromagnetic (EM) and chemical (CM) enhancement of the Raman signal. [3] The EM enhancement is on the order of ≈|E| 4 , amplifying signals >10 8 , where E is the intensity of the EM field. On the other hand, CM enhancement has been shown to enhance the signal ≈10-100×. Nevertheless, SERS enhancement is contingent on the quality of the substrate. Preparation of a suitable substrate requires rigorous micro/nanofabrication processes, such as electrochemical or high vacuum deposition of noble metals (e.g., Ag, Au, Cu) or the selfassembly of size-controlled colloidal noble metal nanoparticles, which are very complex, contaminated, and not homogenous, leading to a lowered SERS effect. Moreover, when metal-based rough substrates, such as Ag or Cu, are used for SERS, they tend to oxidize, which prevents their use in some applications. Additionally, noble metals have relatively poor biological compatibility, hindering their use in biomedical applications.Recently, graphene-enhanced Raman spectroscopy (GERS) has emerged as a novel technique where graphene-based ultra-smooth substrates exhibit strong Raman enhancement from adsorbed molecules. [4][5][6] Graphene is cheap, easy to produce, and remains stable even in relatively harsh conditions. The flat and chemically inert surface and environmentally friendly nature of graphene make it compatible for widespread use including biosensing, biomedical, and environmental applications. [7][8][9] The GERS technique is associated with the CM enhancement mechanism, where the charge transfer occurs between adsorbed molecules and the substrate. [4,10] As the surface plasmon on graphene is in the terahertz range rather than the visible range, graphene does not support EM enhancement by the excitation of visible energy photons. [11] Chemical mechanism-initiated GERS facilitates molecular selectivity, enhancing the charge transfer between the molecules and the graphene. The high stability and reproducibility of the Raman enhanced spectra from graphene makes GERS more suitable for applications than SERS. [12] It has been previously reported that the enhancement from GERS on nitrogen-doped graphene was about ten times higher than SERS with the same probe molecules, while for pristine graphene, it was five times higher. [13] Different molecules have been probed with GERS, making it an effective approach for sensing. [14,15] Theoretical and experimental studies have been conducted to obtain more insight into the mechanism

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Toward Graphene‐Enhanced Spectroelectrochemical Sensors

Kaushik

Sonia

Haider

et al. 2022

Adv Materials Inter

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“…Additionally, graphene enhanced LSPR devices have been modelled, fabricated and characterized, but there is limited published data on implementation in bio-sensing. Graphene has also been incorporated into SERS, a 2020 paper by Valeš (Valeš et al, 2020) on Graphene-enhanced Raman scattering (GERS) studied mono and bilayer pristine graphene partially hydrogenated to enhance the Raman signal whilst improving the quench photoluminescence simultaneously. This work highlights the change of Raman signal bands of rhodamine 6 G (R6G) when using hydrogenated and pristine graphene.…”

Section: Challenges To Graphene-based Optical Sensors For Detecting F...mentioning

confidence: 99%

Emerging graphene-based sensors for the detection of food adulterants and toxicants – A review

et al. 2021

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“…The aforementioned properties of graphene thus eliminate the problems of irreproducibility and spectral instability that are commonly encountered in SERS . Additionally the chemical enhancement in GERS can be fine-tuned by controlling the interaction distance between the analyte and graphene, the applied-voltage dependent Fermi-level shift of graphene, , the type of chemical doping, − the size of the graphitic domains and the molecular structure and energy levels of the analyte …”

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confidence: 99%

Ultrasensitive Detection and In Situ Imaging of Analytes on Graphene Oxide Analogues Using Enhanced Raman Spectroscopy

et al. 2021

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We demonstrate how algorithm-improved confocal Raman microscopy (ai-CRM), in combination with chemical enhancement by two-dimensional substrates, can be used as an ultrasensitive detection method for rhodamine (R6G) molecules adsorbed from aqueous solutions. After developing a protocol for laser-induced reduction of graphene oxide, followed by noninvasive Raman imaging, a limit of detection (LOD) of 5 × 10 –10 M R6G was achieved using ai-CRM. An equivalent subnanomolar LOD was also achieved on another graphene oxide analogue −UV/ozone-oxidized graphene. These record-breaking detection capabilities also enabled us to study the adsorption kinetics and image the spatial distribution of the adsorbed R6G. These findings indicate a strong potential for algorithm-improved graphene-enhanced Raman spectroscopy as a facile method for detecting, imaging, and quantifying trace amounts of adsorbing molecules on a variety of 2D substrates.

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Graphene-enhanced Raman scattering on single layer and bilayers of pristine and hydrogenated graphene

Cited by 22 publications

References 54 publications

Toward Graphene‐Enhanced Spectroelectrochemical Sensors

Toward Graphene‐Enhanced Spectroelectrochemical Sensors

Emerging graphene-based sensors for the detection of food adulterants and toxicants – A review

Ultrasensitive Detection and In Situ Imaging of Analytes on Graphene Oxide Analogues Using Enhanced Raman Spectroscopy

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