Highly selective covalent organic functionalization of epitaxial graphene

Bueno, Rebeca; Martínez, José I.; Luccas, R. F.; Árbol, Nerea Ruíz del; Munuera, Carmen; Palacio, Irene; Palomares, F. J.; Lauwaet, Koen; Thakur, Sangeeta; Baranowski, J. M.; Strupiński, Włodek; López, María Francisca; Mompeán, F. J.; Garcı́a-Hernández, M.

doi:10.1038/ncomms15306

Cited by 46 publications

(53 citation statements)

References 56 publications

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“…This finding demonstrates that high quality grafting can be achieved in a set-up with growth conditions less demanding with respect to UHV-related methods 36 , therefore disclosing the possibility to apply photoemission techniques to systems prepared on the basis of similar electrochemical methods 37 , and ultimately enabling a scalable pathway for the production of functionalized graphene layers.…”

Section: Discussionmentioning

confidence: 82%

Interface Chemistry of Graphene/Cu Grafted By 3,4,5-Tri-Methoxyphenyl

Ambrosio

Drera

Santo

et al. 2020

Sci Rep

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Chemical reaction with diazonium molecules has revealed to be a powerful method for the surface chemical modification of graphite, carbon nanotubes and recently also of graphene. Graphene electronic structure modification using diazonium molecules is strongly influenced by graphene growth and by the supporting materials. Here, carrying on a detailed study of core levels and valence band photoemission measurements, we are able to reconstruct the interface chemistry of trimethoxybenzenediazonium-based molecules electrochemically grafted on graphene on copper. The band energy alignment at the molecule-graphene interface has been traced revealing the energy position of the HOMO band with respect to the Fermi level.

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Section: Discussionmentioning

confidence: 82%

Interface Chemistry of Graphene/Cu Grafted By 3,4,5-Tri-Methoxyphenyl

Ambrosio

Drera

Santo

et al. 2020

Sci Rep

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“…FG was reacted with hydroxylamine (NH 2 OH) at 130 °C in dimethylformamide (DMF), avoiding high‐temperature treatment or highly reactive reagents, used previously . The Supporting Information presents a detailed characterization of pNG and the mechanism of its formation, which involves: i) the defluorination of FG and its transformation into highly N‐doped (9.8 at.%) graphene (see Figure S4A–D in the Supporting Information); ii) the decomposition of hydroxylamine into ammonia, (identified by trapping the byproducts of the reaction, as described in Figure S4E in the Supporting Information), which undergoes dehydrogenation at vacancies and is thus a source of the atomic nitrogen that becomes doped into the graphene lattice; iii) the in situ formation of lattice vacancies in FG (see Figure S5A,B in the Supporting Information); and iv) the formation of a predominantly sp 2 architecture (Figure S5C,D, Supporting Information). Atomic force microscopy (AFM) and transmission electron microscopy (TEM) indicated that pNG consisted mainly of nanosized flakes ( Figure A; Figure S6, Supporting Information).…”

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confidence: 99%

Microwave Energy Drives “On–Off–On” Spin‐Switch Behavior in Nitrogen‐Doped Graphene

et al. 2019

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over traditional semiconductor-based alternatives, including higher data processing speeds, lower power consumption, nonvolatility, and higher integration densities. [2] A central goal of spintronics is to identify materials exhibiting spindependent effects, which are required for the occurrence of spintronic processes. [1] Graphene was recently suggested to be an attractive platform for spintronic applications [3][4][5] because it exhibits several spin-related phenomena including tunnel magnetoresistance, [6] enhancement of spin-injection efficiency, [7] the Rashba effect, [8] the quantum spin Hall effect, [9] and large perpendicular magnetic anisotropy. [10] It also exhibits several properties useful in spintronics, including ballistic charge transport, [11] long spin lifetimes and spin-diffusion lengths, [12,13] limited hyperfine interactions, [14] gate-tunable magnetic order, [15] and weak spin-orbit coupling. [3] Due to its exceptionally long spin lifetime of ≈10 ns (corresponding to a spin-diffusion length of several micrometers at room temperature), graphene has an intriguing spin-conserving potential. It is thus regarded as a promising material for spin transport in spin-valve architectures, enabling faithful transmission of information encoded in a carrier's spin across a device. [4] However, because of its diamagnetism and weak spin-orbit coupling, [16] it exhibits only weak transport-current-induced spin densities and weakly spin-polarized currents. Pristine graphene cannot function as a spin generator or an injector of spin-polarized carriers, [4] but strain induced in the material arising from surface corrugation and lattice mismatch between graphene layers and underlying substrates can severely change the electronic, magnetic, and transport properties. [17,18] Strain effects are known to promote modification of the graphene bandgap and can induce spin gap asymmetry and spin-polarization effects, locally or even extended over the 2D carbon network; [17,19] thus the "strain engineering" approach bears great potential for its application in graphene-based nanofabrication technologies. [18,20] For example, Yan et al. have shown that cooperativity between strain and out-of-plane distortion in the graphene wrinkles provide valley-polarized sites with significant energy gaps, a property that offers the ground for realization of hightemperature "zero-field" quantum valley Hall effects. [21] Liu et al., upon interfacing graphene with orthorhombic black phosphorus (BP), demonstrated that both lattices can be mutuallyThe established application of graphene in organic/inorganic spin-valve spintronic assemblies is as a spin-transport channel for spin-polarized electrons injected from ferromagnetic substrates. To generate and control spin injection without such substrates, the graphene backbone must be imprinted with spin-polarized states and itinerant-like spins. Computations suggest that such states should emerge in graphene derivatives incorporating pyridinic nitrogen. The synthesis and electronic properties o...

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“…Organic covalent functionalization reactions of graphene include two general routes: (a) the formation of covalent bonds between free radicals or dienophiles and C═C bonds of pristine graphene and (b) the formation of covalent bonds between organic functional groups and the oxygen groups of GO (Georgakilas et al, 2012). Characteristic of these processes are the presence of carbonyl, hydroxyl and carboxyl groups (resulting from the oxidation of graphite itself by the Hummers method); nevertheless, functional moieties, such as amines (Wanjeri et al, 2018;Bueno et al, 2017), amides (Ahmed and Kim, 2017;Mrlík et al, 2016), nitro (Begum et al, 2017), thio-compounds (Mahmoodi et al, 2017;Cai and Larese-Casanova, 2016), carbene cycloaddition (Zan, 2014), among others, can be chemically added to the carbon plane edges and surface. Within the covalent routes, a functionalizing group, such as thionyl, can replace the hydroxyl groups that form on the graphene surface after oxidation (Cai and Larese-Casanova, 2016).…”

Section: Functionalization Of Graphene and Its Derivativesmentioning

confidence: 99%

“…The functionalization of graphene or graphene oxide (GO) nanosheets confers specific properties to the composites, e.g., their chemical selectiveness, solubility, thermal and electronic conductivity (Bueno et al, 2017;Xiang et al, 2016). Such enhancement allows the employment of functionalized graphenebased materials in several fields, such as chemistry and catalysis (Ye et al, 2018;Rana and Jonnalagadda, 2017), biomedicine (Kenry et al, 2018;Yu et al, 2018;Zeng et al, 2017), electronics (Scidà et al, 2018;Gevaerd et al, 2018;Chiu et al, 2017;Zhao et al, 2017), energy (Li and Zhi, 2018;Sadri et al, 2017) and environmental sciences and technologies (Ren et al, 2018;Othman et al, 2018;Khurana et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Modified graphene has also been tested as gatekeepers for several chiral molecules, many of them with bioactive and toxic properties (Hauser et al, 2014). Among the advantages of employing functionalization processes on graphene and graphene oxide nanosheets, it can be cited: increase of sorbent selectivity towards specific classes of pollutants (Lazarevic-Pasti et al, 2018;Shrivas et al, 2017); outstanding adsorption performance in terms of capacity and high recoverability (Suo et al 2018;Nodeh et al, 2015;Zhao and Liu, 2014); unlimited possibilities of functionalization, oftentimes by using the same reactant (Wanjeri et al, 2018;Bueno et al, 2017); some non-covalent functionalization can be reversed by non-aggressive methods (McCoy et al 2015); functionalization routes can be developed by using bio and ecofriendly compounds, such as amino acids, wood extracts, chitosan, etc. (Cobos et al, 2018;Xue et al, 2018;Wang et al, 2017b;Wang et al, 2016b).…”

Section: Introductionmentioning

confidence: 99%

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Functionalized Graphene-Based Materials as Innovative Adsorbents of Organic Pollutants: A Concise Overview

Fraga

Carvalho

Ghislandi

et al. 2019

Braz. J. Chem. Eng.

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The functionalization of graphene nanosheets is the cutting edge of materials sciences nowadays. Such research promotes the development of innovative, low cost and highly capable sorbents. This review article aims to assemble the available information on functionalized graphene used for the adsorption of organic pollutants and establishes a critical comparison between the data reported in the literature. Various optimal experimental conditions (pH, temperature, contact time, adsorbent dosage) and adsorbent characterization methods (FTIR, Raman, XPS spectra, XRD, TEM and AFM) have been listed to enlighten adsorption mechanisms, capacity and limiting aspects. Moreover, adsorption isotherms, kinetics and thermodynamic data of different functionalized graphene-based materials towards a wide range of organic pollutants were analyzed and tabulated. In each evaluation topic, environmental and human health protection is subject for discussion, as well as the scientific breakthrough works available in high impact journals in the field.

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Highly selective covalent organic functionalization of epitaxial graphene

Cited by 46 publications

References 56 publications

Interface Chemistry of Graphene/Cu Grafted By 3,4,5-Tri-Methoxyphenyl

Interface Chemistry of Graphene/Cu Grafted By 3,4,5-Tri-Methoxyphenyl

Microwave Energy Drives “On–Off–On” Spin‐Switch Behavior in Nitrogen‐Doped Graphene

Functionalized Graphene-Based Materials as Innovative Adsorbents of Organic Pollutants: A Concise Overview

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