Understanding and controlling the substrate effect on graphene electron-transfer chemistry via reactivity imprint lithography

Wang, Qing Hua; Jin, Zhong; Kim, Ki Kang; Hilmer, Andrew J.; Paulus, Geraldine L.C.; Shih, Chih‐Jen; Ham, Moon Ho; Sanchez-Yamagishi, Javier; Watanabe, Kenji; Taniguchi, Takashi; Kong, Jing; Jarillo‐Herrero, Pablo; Strano, Michael S.

doi:10.1038/nchem.1421

Cited by 467 publications

(509 citation statements)

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“…Instead of providing an extensive list of the methods available to induce such modifications, we will continue with discussing a grafting strategy, frequently applied to covalently attach chemical moieties to graphene surface (or edges) via free-radical reactions. [27,28,109,121,[122][123][124][125] Graphene grafting uses alkyl or aryl diazonium salts as grafting agents, where the diazonium salt precursor is first chemically or electrochemically reduced (liberating nitrogen gas), to form a reactive alkyl or aryl radical that reacts with the aromatic system of the graphene sheet (the conductive channel of the transistor device fabricated on a 200 nm SiO 2 /highly doped Si substrate as shown in Fig. 3c).…”

Section: Covalent Functionalizationsmentioning

confidence: 99%

“…II). The reaction efficiency depends on several parameters: the number of graphene layers, [122] the electrostatic environment, [123] and the defect density on the graphene surface. [124] A previous study exploited the graphene reactivity, induced by electrostatic charge doping on different substrates using reactivity imprint lithography (RIL).…”

Section: Covalent Functionalizationsmentioning

confidence: 99%

“…[124] A previous study exploited the graphene reactivity, induced by electrostatic charge doping on different substrates using reactivity imprint lithography (RIL). [123] The RIL technique made use of a polydimethylsiloxane (PDMS) stamp to pattern octadecyltrichlorosilane (OTS) lines on a SiO 2 /Si substrate (Fig. 3d).…”

Section: Covalent Functionalizationsmentioning

confidence: 99%

“…OTS increases the distance between the graphene sheet and the charged impurities in the SiO 2 substrate, rendering the portion of graphene resting on it less reactive to the 4-NBD. [123] Similarly, in case of GO (or rGO), grafting chemistries are best represented by localized reactivity of the carboxyl, carbonyl, and other oxygen-containing groups by substitution reactions. [124] …”

Section: Covalent Functionalizationsmentioning

confidence: 99%

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Sensing at the Surface of Graphene Field‐Effect Transistors

et al. 2016

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Abstract. 10Recent research trends now offer new opportunities for developing the next generations of label-free biochemical sensors using graphene and other two-dimensional materials. While the physics of graphene transistors operated in electrolyte is well grounded, important chemical challenges still remain to be addressed, namely the impact of the chemical functionalizations of graphene on the key electrical parameters and the sensing performances. In fact, graphene -at least ideal graphene -is highly chemically inert. The 15 functionalizations and chemical alterations of the graphene surface -both covalently and non-covalently -are crucial steps that define the sensitivity of graphene. The presence, reactivity, adsorption of gas and ions, proteins, DNA, cells and tissues on graphene have been successfully monitored with graphene. This review aims to unify most of the work done so far on biochemical sensing at the surface of a (chemically functionalized) graphene field-effect transistor and the challenges that lie ahead. We are convinced that graphene biochemical sensors 20 hold great promises to meet the ever-increasing demand for sensitivity, especially looking at the recent progresses suggesting that the obstacle of Debye screening can be overcome.2

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Section: Covalent Functionalizationsmentioning

confidence: 99%

Section: Covalent Functionalizationsmentioning

confidence: 99%

Section: Covalent Functionalizationsmentioning

confidence: 99%

Section: Covalent Functionalizationsmentioning

confidence: 99%

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Sensing at the Surface of Graphene Field‐Effect Transistors

et al. 2016

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“…The asymmetry between the conduction band () and the valence band (), which is especially pronounced in the vicinity of the point, which is attributed to the non-zero overlap parameter . However, the electronic band structure of graphene can be simply altered by applying electric field [6,57–61] or providing substrates [62,63], and precisely engineered by introducing disorders into the hexagonal lattice [64–68], which will be discussed in detail in later sections.…”

Section: The Structure Of Graphenementioning

confidence: 99%

Structure of graphene and its disorders: a review

Gao

Lee

et al. 2018

Science and Technology of Advanced Materials

438

173

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Monolayer graphene exhibits extraordinary properties owing to the unique, regular arrangement of atoms in it. However, graphene is usually modified for specific applications, which introduces disorder. This article presents details of graphene structure, including sp2 hybridization, critical parameters of the unit cell, formation of σ and π bonds, electronic band structure, edge orientations, and the number and stacking order of graphene layers. We also discuss topics related to the creation and configuration of disorders in graphene, such as corrugations, topological defects, vacancies, adatoms and sp3-defects. The effects of these disorders on the electrical, thermal, chemical and mechanical properties of graphene are analyzed subsequently. Finally, we review previous work on the modulation of structural defects in graphene for specific applications.

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