Electronic Transport of MoS<sub>2</sub> Monolayered Flakes Investigated by Scanning Electrochemical Microscopy

Henrotte, Olivier; Bottein, Thomas; Casademont, Hugo; Jaouen, Kévin; Bourgeteau, Tiphaine; Campidelli, Stéphane; Derycke, Vincent; Jousselme, Bruno; Cornut, Renaud

doi:10.1002/cphc.201700343

Cited by 9 publications

(13 citation statements)

References 24 publications

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“…The reason for this blockage is that during the anodic polarization of the MoS 2 the number of available charge carriers in the material (electrons), is reduced, which results in lower exchange currents. High contact resistance, which is a general problem in device fabrication, also plays a role by limiting the charge carrier injection and subsequently the electron transport through the 2D material . This might also be the reason why we have not observed any deposition at the sites which could potentially become electrochemically active, particularly, the edges and defective sites where molybdenum atoms are exposed to the solution .…”

Section: Resultsmentioning

confidence: 87%

“…There are two main reasons why the PPO deposition does not occur on the MoS 2 : the semiconducting nature of MoS 2 (in this case n‐type semiconductor), and the nonefficient charge injection into the 2D material due to the high contact resistance at the electrode–2D material interface. It has been observed that in n‐type MoS 2 the heterogeneous electron transfer (HET) rate decreases with more positive potentials . For redox couples that have relatively positive redox potentials, such as Fe 3+/2+ , the HET readily occurs only in the cathodic direction (reduction), while the anodic reaction (oxidation) gets partially or completely blocked .…”

Section: Resultsmentioning

confidence: 99%

“…The potential range in which the MoS 2 crystal is electrochemically stable is between −1.2 and 1.3 V toward the Ag|AgCl electrode . Since the rate of electron transfer between the n‐type semiconductor and the species in solution is extremely slow at positive potentials, this anodic window before the threshold potential for material oxidation could be utilized for the selective coating of electrodes contacting MoS 2 . One of the polymers which can be electrochemically deposited in this anodic region, and shows excellent insulating properties, is poly(phenylene oxide) (PPO) .…”

Section: Introductionmentioning

confidence: 99%

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Nanoscale Selective Passivation of Electrodes Contacting a 2D Semiconductor

Lihter

Gräf

Iveković

et al. 2019

Adv Funct Materials

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2D semiconducting materials have become the central component of various nanoelectronic devices and sensors. For sensors operating in liquid, it is crucial to efficiently block the electron transfer that occurs between the electrodes contacting the 2D material and the interfering redox species. This reduces current leakages and preserves a good signal-to-noise ratio. Here, a simple electrochemical method is presented for passivating the electrodes contacting a monolayer of MoS 2 , a representative of transition metal dichalcogenide semiconductors. The method is based on blocking the electrode surface by a thin and compact layer of electronically nonconductive poly(phenylene oxide), PPO, formed by electrochemical polymerization of phenol. Since the phenol polymerization occurs in the potential window where MoS 2 is electrochemically inactive, the PPO deposition is area-selective, limited to the electrode surface. The deposited PPO film is characterized by electrochemical, X-ray photoelectron spectroscopy, scanning electron microscopy, and atomic force microscopy techniques. The applicability of this method is demonstrated by coating the electrodes of a MoS 2based field-effect transistor coupled with a nanopore. The highly selective deposition, the simple approach, and the compatibility with MoS 2 makes this method a good strategy for efficient insulation of micro-and nanoelectrodes contacting 2D semiconductor-based devices.

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Section: Resultsmentioning

confidence: 87%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Nanoscale Selective Passivation of Electrodes Contacting a 2D Semiconductor

Lihter

Gräf

Iveković

et al. 2019

Adv Funct Materials

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“…The small detector ring (MiniPET) camera (also known as small animal PET camera) is applied for imaging of the positron-emitter labeled compounds with high 1.2 mm spatial resolution compared to bigger, human PET camera with 4-5 mm resolution. [35] In the previous works the PET imaging was already effectively used in molecular imaging of liquid chromatography and heterogeneous catalysis processes. [36][37][38] In the present work the 11 C-radiolabeled methanol as a tracing fuel compound (labeled by 11 C-positronemitter isotope) and its 11 C-derivatives (their collective name 11 C-adsorbates) were determined in terms of chemical property on the reactive surface area along the layers of the fuel cell.…”

Section: Introductionmentioning

confidence: 99%

Compound‐Specific Imaging of Methanol Fuel Cell for Performance and Degradation Studies Using a Mini Positron Emission Tomograph

et al. 2021

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Direct methanol fuel cell is a promising electrical energy source. Performance improvements, such as higher energy density and improved electrocatalyst are hot topics in fuel cell research. The goal of this study is the introduction of the Positron Emission Tomography (PET) as molecular imaging technique in the visualization of the methanol fuel cell process. The compound specific imaging method, using a small PET camera and radiolabeled 11 C methanol, can visualize the electrocatalytic processes, the coverage degree and the distribution of the methanol and its derivatives on the total electrocatalyst surface. The undesirable methanol crossover effect was also detected by imaging the additional layers of the cell. The fuel cell layers were studied in different conditions, such as well-functioning and temporarily or permanently degraded, during short-and long-term operations. The experimental results confirmed the PET imaging method is applicable in the methanol fuel cell development.

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“…7,11,20 Scanning electrochemical microscopy (SECM) 27 showed that strain enhances the hydrogen evolution reaction (HER) at MoS 2 28 and that the conductivity of MoS 2 flakes varies widely depending on the nature of the contact. 29 Other applications of SECM include measuring the HER kinetics and hydrogen adsorption at amorphous MoS 2 on gold 30 and mapping the HER at MoS 2 /graphene oxide composites 31 although spatial differences in the active MoS 2 areas is unclear due to the high probe currents in the SECM images. Likewise, scanning electrochemical cell microscopy (SECCM) demonstrated that the HER at MoS 2 proceeds at the basal planes albeit at much lower rates than edge sites.…”

Section: Introductionmentioning

confidence: 99%

Mapping Electron Transfer at MoS₂ Using Scanning Electrochemical Microscopy

Ritzert

Szalai²,

Moffat³

2018

Langmuir

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Understanding the role of macroscopic and atomic defects in the interfacial electron transfer properties of layered transition metal dichalcogenides is important in optimizing their performance in energy conversion and electronic devices. Means of determining the heterogeneous electron transfer rate constant, k, have relied on deliberate exposure of specific electrode regions or additional surface characterization to correlate proposed active sites to voltammetric features. Few studies have investigated the electrochemical activity of surface features of layered dichalcogenides under the same experimental conditions. Herein, MoS2 flakes with well-defined features were mapped using scanning electrochemical microscopy (SECM). At visually flat areas of MoS2, k of hexacyanoferrate(III) ([Fe(CN)6]3−) and hexacyanoferrate(II) ([Fe(CN)6]4−) was typically smaller and spanned a larger range than that of hexaammineruthenium(III) ([Ru(NH3)6]3+), congruent with current literature. However, in contrast to previous studies, reduction of [Fe(CN)6]3− and oxidation of [Fe(CN)6]4− exhibited similar rate constants, attributed to the dominance of charge transfer through surface states. Comparison of SECM with optical and atomic force microscopy images revealed that while most of the flake was electroactive, edge sites associated with freshly exposed areas that include both macrosteps consisting of several monolayers and recessed areas exhibited the highest reactivity, consistent with reported results.

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Electronic Transport of MoS₂ Monolayered Flakes Investigated by Scanning Electrochemical Microscopy

Cited by 9 publications

References 24 publications

Nanoscale Selective Passivation of Electrodes Contacting a 2D Semiconductor

Nanoscale Selective Passivation of Electrodes Contacting a 2D Semiconductor

Compound‐Specific Imaging of Methanol Fuel Cell for Performance and Degradation Studies Using a Mini Positron Emission Tomograph

Mapping Electron Transfer at MoS₂ Using Scanning Electrochemical Microscopy

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Electronic Transport of MoS2 Monolayered Flakes Investigated by Scanning Electrochemical Microscopy

Cited by 9 publications

References 24 publications

Nanoscale Selective Passivation of Electrodes Contacting a 2D Semiconductor

Nanoscale Selective Passivation of Electrodes Contacting a 2D Semiconductor

Compound‐Specific Imaging of Methanol Fuel Cell for Performance and Degradation Studies Using a Mini Positron Emission Tomograph

Mapping Electron Transfer at MoS2 Using Scanning Electrochemical Microscopy

Contact Info

Product

Resources

About

Electronic Transport of MoS₂ Monolayered Flakes Investigated by Scanning Electrochemical Microscopy

Mapping Electron Transfer at MoS₂ Using Scanning Electrochemical Microscopy