Fast Electron Transfer Kinetics at an Isolated Graphene Edge Nanoelectrode with and without Nanoparticles: Implications for Sensing Electroactive Species

Yadav, Anur; Wehrhold, Michel; Neubert, Tilmann J; Iost, Rodrigo M.; Balasubramanian, Kannan

doi:10.1021/acsanm.0c02171

Cited by 18 publications

(49 citation statements)

References 71 publications

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“…It is known in carbon research that the preparation of the electrode has a strong effect on the ensuing electrochemical characteristics. 17,24,25 This is in contrast to non-crystalline metal electrodes, where polycrystalline or amorphous planar electrodes give similar electrochemical behavior rather independent of the preparation strategy. This work underlines the necessity to perform sample preparation carefully in order to assess the maximum achievable performance.…”

Section: Discussionmentioning

confidence: 95%

Highly Durable Graphene Monolayer Electrode on Insulating Substrate under Long-term Hydrogen Evolution Cycling

Wehrhold¹,

Neubert²,

Grosser³

et al. 2022

Preprint

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Electrochemical hydrogen evolution reaction (HER) at single graphene sheets has been investigated widely either in its pristine form or after chemical modification. One important challenge is the long-term stability of single graphene sheets on Si/SiO2 substrates under HER. Previous reports have found that due to stress developing under gas evolution, the sheets tend to break apart, with a very low lifetime limited to just a few cycles of HER. Here, we show through appropriate electrode preparation that it is possible to achieve highly durable single graphene electrodes on insulating substrates, which can survive several hundreds of HER cycles with virtually no damage to the sp2-carbon framework. Through systematic investigations including atomic force microscopy, Raman spectroscopy and electroanalysis, we show that even after so many cycles, the sheet is physically intact and the electron transfer capability of the electrodes remain unaffected. This extremely high stability of a single atomic sheet of carbon, when combined with appropriate chemical modification strategies, will pave way for the realization of novel 2D electrocatalysts.

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Section: Discussionmentioning

confidence: 95%

Highly Durable Graphene Monolayer Electrode on Insulating Substrate under Long-term Hydrogen Evolution Cycling

Wehrhold¹,

Neubert²,

Grosser³

et al. 2022

Preprint

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“…Monolayer graphene electrodes on Si/SiO 2 substrates with pre‐patterned metal contacts were prepared as outlined in our earlier works [3a,d] . (see Figure S1 in supporting information (SI) and experimental section for details).…”

Section: Resultsmentioning

confidence: 99%

“…However, the potential range on the cathodic side is limited due to oxygen reduction and hydrogen evolution reactions at the carbon surface. Chemical modification of graphene is being widely pursued to modify the electrochemical characteristics [3a,6] . For example, deposition of metal nanoparticles may impart improved electrocatalytic activity in carbon electrodes [7] .…”

Section: Introductionmentioning

confidence: 99%

Graphene‐Mercury‐Graphene Sandwich Electrode for Electroanalysis

et al. 2021

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We present a new class of hybrid 2D electrodes, where mercury is incorporated between two graphene monolayers, prepared by bottom‐up assembly. First, the bottom graphene layer is electrochemically modified leading to the creation of fine mercury nanodroplets of variable size on the graphene surface. Although such electrodes show good sensitivity to heavy metal ions, their stability is limited due to the outgassing of mercury over time. After coverage with a top monolayer, the graphene surface is rendered with the favorable properties of mercury such as the high overpotential for hydrogen evolution, the ability to work at a broader cathodic potential range and higher sensitivity towards heavy metal ions such as Cd2+ and Pb2+. Most importantly, the outgassing of mercury is completely hindered by the top layer, which yields a stable mercury‐like electrode but with a carbonaceous non‐toxic interface. We attribute the favorable properties of the sandwich electrode to the subsurface mercury present below the top graphene sheet, which renders it with new electrochemical properties.

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“…8,[20][21][22] The specialized nature of the monolayer graphene edge has been in the focus of several recent investigations. [23][24][25][26][27][28][29] Since it is not feasible to obtain a free-standing atomic carbon edge, a certain portion of the basal plane needs to be present in order to support the edge. For electrochemical studies in a liquid environment, the capability to address the edge of a single graphene sheet exclusively has been demonstrated in a few occasions.…”

Section: Introductionmentioning

confidence: 99%

pH sensitivity of edge-gated graphene field-effect devices with covalent edge-functionalization

Neubert

Krieg

Yadav

et al. 2022

Preprint

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We present here a new strategy for a field-effect device, termed graphene edge field-effect transistor (GrEdge-FET), where a micron-wide graphene monolayer is gated exclusively through its edge in an aqueous environment. This is achieved by passivating the basal plane selectively using photolithography. We observe a field-effect behavior in buffer solutions with an ON/OFF ratio of nearly 10 in a small gate-voltage range (+/- 0.5 V) without any need for complex nanofabrication or specialized electrolytes. We attribute this effect to the electrical double layer capacitance at the edge-electrolyte interface, which efficiently gates the entire graphene sheet although it acts only at the edge. We demonstrate that GrEdge-FET devices find applications as pH sensors. Through diazonium electrochemistry, the edges are functionalized persistently with substituted phenyl moieties, which renders the devices with a higher pH sensitivity than classical graphene FETs. Moreover, since only the edge is modified, the favorable field-effect behavior is preserved, despite the covalent nature of attachment of the functional groups.

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Fast Electron Transfer Kinetics at an Isolated Graphene Edge Nanoelectrode with and without Nanoparticles: Implications for Sensing Electroactive Species

Cited by 18 publications

References 71 publications

Highly Durable Graphene Monolayer Electrode on Insulating Substrate under Long-term Hydrogen Evolution Cycling

Highly Durable Graphene Monolayer Electrode on Insulating Substrate under Long-term Hydrogen Evolution Cycling

Graphene‐Mercury‐Graphene Sandwich Electrode for Electroanalysis

pH sensitivity of edge-gated graphene field-effect devices with covalent edge-functionalization

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