Chemical Stability of Graphene Fluoride Produced by Exposure to XeF<sub>2</sub>

Stine, Rory; Lee, Woo‐Kyung; Whitener, Keith E.; Robinson, Jeremy T.; Sheehan, Paul E.

doi:10.1021/nl4021039

Cited by 113 publications

(129 citation statements)

References 30 publications

Supporting

Mentioning

117

Contrasting

Order By: Relevance

“…We find that after fluorination of CVD graphene on Ni/ Cu substrates, its subsequent transfer by traditional poly(methyl methacrylate) (PMMA) method [21] and patterning alter its insulating properties. XPS measurement on the transferred FG ( Figure 1c) shows a strong decrease in the intensity of F1s peak, indicating a loss of F content [18] (from 24.5% in as-prepared FG on Cu foil to 4.4%). We attribute this to the loss of the insulating properties of transferred FG.…”

Section: Resultsmentioning

confidence: 99%

“…[12] The binding of F radicals to graphene leads to surface activation and band gap opening, [11][12][13] rendering the resultant FG useful for applications ranging from as a seed layer for dielectric deposition [14,15] to as a growth precursor for synthesis of new 2D materials [16] and a building block for 2D heterostructures. [17] While FG, like some of the other functionalized graphene forms, holds great promises as a complementary material for next generation graphene-based electronics, it can readily defluorinate under humid conditions or when in contact with acetone [7,18] Such a phenomenon, considering acetone an important solvent for FG transfer and patterning process, can seriously undermine the potential of FG for widespread applications. This is because even a marginal change in the degree of fluorine coverage on graphene can turn FG from an insulator to a semiconductor or even a conductor, drastically changing the function and performance of electronic devices.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Solvent‐Based Soft‐Patterning of Graphene Lateral Heterostructures for Broadband High‐Speed Metal–Semiconductor–Metal Photodetectors

Ali

Shehzad

et al. 2016

Adv Materials Technologies

View full text Add to dashboard Cite

Solvents are essential in synthesis, transfer, and device fabrication of 2D materials and their functionalized forms. Controllable tuning of the structure and properties of these materials using common solvents can pave new and exciting pathways to fabricate high-performance devices. However, this is yet to be materialized as solvent effects on 2D materials are far from well understood. Using fluorine functionalized chemical vapor deposited graphene (FG) as an example, and in contrast to traditional "hard-patterning" method of plasma etching, the authors demonstrate a solvent-based "softpatterning" strategy to enable its selective defluorination for the fabrication of graphene-FG lateral heterostructures with resolution down to 50 nm. In this strategy, the oxygen plasma etching process of patterning after graphene transfer is avoided and high quality surfaces are preserved through a physically continuous atomically thin sheet, which is critical for high performance photodetection, especially in the high-speed domain. The fabricated lateral graphene heterostructures are further employed to demonstrate a high speed metal-semiconductor-metal photodetector (<10 ns response time), with a broadband response from deep-UV (200 nm) to near-infrared (1100 nm) range. Thanks to the high quality surface with much less defects due to the "soft-patterning" strategy, the authors achieve a high deep-UV region photoresponsivity as well as the ultrafast time response. The strategy offers a unique and scalable method to realize continuous 2D lateral heterostructures and underscores the significance of inspiring future designs for high speed optoelectronic devices.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Solvent‐Based Soft‐Patterning of Graphene Lateral Heterostructures for Broadband High‐Speed Metal–Semiconductor–Metal Photodetectors

Ali

Shehzad

et al. 2016

Adv Materials Technologies

View full text Add to dashboard Cite

show abstract

“…[[qv: 4a]],[[qv: 12a]],[[qv: 22c]] The removal of both C and F atoms in fluorographene was observed by a prolonged annealing time at high temperature (≈450 °C). [[qv: 4a]] In addition, according to XPS data, fluorinated graphene, prepared using XeF 2 gas on SiO 2 , Au, and Cu substrates, lost approximately 50–80% of the initial F/C ratios over 10 days until the F/C ratios were not changed 61. The change in C‐F bonds by annealing at different temperatures was also demonstrated by an increase in electrical conductivity (Figure 10b).…”

Section: Propertiesmentioning

confidence: 97%

Two‐Dimensional Fluorinated Graphene: Synthesis, Structures, Properties and Applications

et al. 2016

View full text Add to dashboard Cite

Fluorinated graphene, an up‐rising member of the graphene family, combines a two‐dimensional layer‐structure, a wide bandgap, and high stability and attracts significant attention because of its unique nanostructure and carbon–fluorine bonds. Here, we give an extensive review of recent progress on synthetic methods and C–F bonding; additionally, we present the optical, electrical and electronic properties of fluorinated graphene and its electrochemical/biological applications. Fluorinated graphene exhibits various types of C–F bonds (covalent, semi‐ionic, and ionic bonds), tunable F/C ratios, and different configurations controlled by synthetic methods including direct fluorination and exfoliation methods. The relationship between the types/amounts of C–F bonds and specific properties, such as opened bandgap, high thermal and chemical stability, dispersibility, semiconducting/insulating nature, magnetic, self‐lubricating and mechanical properties and thermal conductivity, is discussed comprehensively. By optimizing the C–F bonding character and F/C ratios, fluorinated graphene can be utilized for energy conversion and storage devices, bioapplications, electrochemical sensors and amphiphobicity. Based on current progress, we propose potential problems of fluorinated graphene as well as the future challenge on the synthetic methods and C‐F bonding character. This review will provide guidance for controlling C–F bonds, developing fluorine‐related effects and promoting the application of fluorinated graphene.

show abstract

“…20 However, fluorine adatoms on graphene are not very stable and any fluorinated areas must be capped to prevent decomposition. 21 Hydrogenation of graphene, accomplished using a wet chemical Birch reduction process, discussed elsewhere in detail, 22 is much more stable. Although hydrogenation can also be accomplished using low energy hydrogen plasmas, 23,24 the Birch reduction process does not introduce defects.…”

Section: Resultsmentioning

confidence: 99%

Homoepitaxial graphene tunnel barriers for spin transport

et al. 2016

Self Cite

View full text Add to dashboard Cite

Tunnel barriers are key elements for both charge-and spin-based electronics, offering devices with reduced power consumption and new paradigms for information processing. Such devices require mating dissimilar materials, raising issues of heteroepitaxy, interface stability, and electronic states that severely complicate fabrication and compromise performance. Graphene is the perfect tunnel barrier. It is an insulator out-of-plane, possesses a defect-free, linear habit, and is impervious to interdiffusion. Nonetheless, true tunneling between two stacked graphene layers is not possible in environmental conditions usable for electronics applications. However, two stacked graphene layers can be decoupled using chemical functionalization. Here, we demonstrate that hydrogenation or fluorination of graphene can be used to create a tunnel barrier. We demonstrate successful tunneling by measuring non-linear IV curves and a weakly temperature dependent zero-bias resistance. We demonstrate lateral transport of spin currents in non-local spin-valve structures, and determine spin lifetimes with the non-local Hanle effect. We compare the results for hydrogenated and fluorinated tunnel and we discuss the possibility that ferromagnetic moments in the hydrogenated graphene tunnel barrier affect the spin transport of our devices.

show abstract

Chemical Stability of Graphene Fluoride Produced by Exposure to XeF₂

Cited by 113 publications

References 30 publications

Solvent‐Based Soft‐Patterning of Graphene Lateral Heterostructures for Broadband High‐Speed Metal–Semiconductor–Metal Photodetectors

Solvent‐Based Soft‐Patterning of Graphene Lateral Heterostructures for Broadband High‐Speed Metal–Semiconductor–Metal Photodetectors

Two‐Dimensional Fluorinated Graphene: Synthesis, Structures, Properties and Applications

Homoepitaxial graphene tunnel barriers for spin transport

Contact Info

Product

Resources

About

Chemical Stability of Graphene Fluoride Produced by Exposure to XeF2

Cited by 113 publications

References 30 publications

Solvent‐Based Soft‐Patterning of Graphene Lateral Heterostructures for Broadband High‐Speed Metal–Semiconductor–Metal Photodetectors

Solvent‐Based Soft‐Patterning of Graphene Lateral Heterostructures for Broadband High‐Speed Metal–Semiconductor–Metal Photodetectors

Two‐Dimensional Fluorinated Graphene: Synthesis, Structures, Properties and Applications

Homoepitaxial graphene tunnel barriers for spin transport

Contact Info

Product

Resources

About

Chemical Stability of Graphene Fluoride Produced by Exposure to XeF₂