Probing Exfoliated Graphene Layers and Their Lithiation with Microfocused X-rays

Zielinski, Patrik; Kühne, Matthias; Kärcher, Daniel; Paolucci, Federico; Wochner, P.; Fecher, Sven; Drnec, Jakub; Felici, Roberto; Smet, J. H.

doi:10.1021/acs.nanolett.9b00654

Cited by 13 publications

(15 citation statements)

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“…For the further development of this key technology a thorough understanding of the processes at the atomic level is highly desired. Studying the intercalation at the 2D level allows to follow the electrochemical intercalation process by various techniques in situ such as XRD, 161 Hall measurements 22,93 and also to follow the process by optical microscopy 89,162 and even transmission electron microscopy at atomic resolution. 15,93,163 TEM imaging not only allows to optically follow the intercalation and deintercalation of the ions into the few-layered 2DM, but also identies areas of varying crystallinity and grain sizes (Fig.…”

Section: Energy Storagementioning

confidence: 99%

Emerging field of few-layered intercalated 2D materials

et al. 2021

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Section: Energy Storagementioning

confidence: 99%

Emerging field of few-layered intercalated 2D materials

et al. 2021

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Section: Monitoring the Intercalation Process By In Situ Techniquesmentioning

confidence: 99%

“…Given that the structural evolution of host materials can be achieved by the ion intercalation, it is advantageous for X‐ray absorption/reflection to probe the intercalation of foreign species. [ 50,51 ] As shown in Figure 3d,e, combining microfocused X‐ray reflection (XRR) with an electrochemical cell for intercalation, Zielinski et al. demonstrated the structural evolution of lithiated bilayer and multilayer graphene.…”

Section: Monitoring the Intercalation Process By In Situ Techniquesmentioning

confidence: 99%

“…demonstrated the structural evolution of lithiated bilayer and multilayer graphene. [ 50 ] By applying a gate voltage, Li ions from the gel‐like electrolyte intercalate into the few‐layer graphene covered by the electrolyte, and then diffuse into the uncovered area of the flake driven by concentration gradients of Li ions within the flake. By focusing the incident X‐ray beam onto the uncovered part of the flake filled with Li ions, the structural evolution induced by ions intercalation has been in situ probed by X‐ray reflectivity.…”

Section: Monitoring the Intercalation Process By In Situ Techniquesmentioning

confidence: 99%

“…Hexagonal boron nitride ( h ‐BN) is a layered insulator with excellent chemical inertness, which can be used to eliminate parasitic surface side reactions during electrochemical intercalation process. As mentioned before, Kim's group reported an electrochemical strategy to controllably intercalate lithium ions into BN/graphene/BN and BN/bigraphene/BN heterostructures, [ 49–56 ] and the intercalation stages and carrier density of graphene are in situ monitored by Hall measurements and Raman/PL spectra. The electron density in graphene/h‐BN heterointerface and graphene/graphene homointerface are determined to be about 7 × 10 13 cm −2 and 4.8 × 10 14 cm −2 , respectively, suggesting that more Li ions reside in the graphene/graphene homointerface than that in the h‐BN/graphene interface.…”

Section: Multifunctionalities Of Intercalated Devicesmentioning

confidence: 99%

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Electrochemical Intercalation in Atomically Thin van der Waals Materials for Structural Phase Transition and Device Applications

Hao

et al. 2020

Advanced Materials

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In van der Waals (vdWs) materials and heterostructures, the interlayers are bonded by weak vdWs interactions due to the lack of dangling bonds. The vdWs gap at the homo‐ or heterointerface provides great freedom to enrich the tunability of electronic structures by external intercalation of foreign ions or atoms at the interface, leading to the discovery of new physics and functionalities. Herein, the recent progress on electrochemical intercalation of foreign species into atomically thin vdWs materials for structural phase transition and device applications is reviewed and future opportunities are discussed. First, several kinds of electrochemical intercalation platforms to achieve the intercalation in vdWs materials and heterostructures are introduced. Next, the in situ characterization of electrochemical intercalation dynamics by state‐of‐the‐art techniques is summarized, including optical techniques, scanning probe techniques, and electrical transport. Moreover, particular attention is paid on the experimentally reported phase transition and multifunctional applications of intercalated devices. Finally, future applications and challenges of intercalation in vdWs materials and heterostructures are proposed, including the intrinsic intercalation mechanism of solid ion conductors, exact identification of intercalated foreign species by near‐field optical techniques, and the tunability of intercalation kinetics for ultrafast switching.

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Exploring Interfaces Through Synchrotron Radiation Characterization Techniques: A Graphene Case

Ding

Shi

Zeng

et al. 2022

Adv Funct Materials

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Recently, many breakthroughs have been made in graphene research, allowing scientists to explore and understand the material world from a two‐dimensional (2D) perspective. The interface issue of graphene is the most important, because all of its atoms are exposed to the interface for this atomically thin material. The 2D nature necessitates a sensitive and non‐destructive interface probe to detect the structure and properties. Synchrotron radiation (SR) characterization techniques, with the ultra‐high resolution and extremely wide energy range, have been utilized with increasing frequency to explore the challenging interface sciences. In this review, these interface characterization techniques based on SR and how they monitor the structure evolution of graphene in different interfaces such as graphene–substrate and graphene–graphene interface are first introduced. Graphene's layer number, interlayer spacing, and stacking order are governed by these interfaces, determining the final properties. Then, the property detection and modulation in different interfaces of graphene are also discussed. Finally, the current challenges and outlook on the future development for SR techniques to characterize graphene interface are presented.

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Probing Exfoliated Graphene Layers and Their Lithiation with Microfocused X-rays

Cited by 13 publications

References 45 publications

Emerging field of few-layered intercalated 2D materials

Emerging field of few-layered intercalated 2D materials

Electrochemical Intercalation in Atomically Thin van der Waals Materials for Structural Phase Transition and Device Applications

Exploring Interfaces Through Synchrotron Radiation Characterization Techniques: A Graphene Case

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