Spatially Coherent Tip-Enhanced Raman Spectroscopy Measurements of Electron–Phonon Interaction in a Graphene Device

Nadas, Rafael; Gadelha, Andreij C.; Barbosa, Tiago Campolina; Rabelo, Cassiano; Vasconcelos, Thiago L.; Monken, Vitor; Portes, Ary V. R.; Watanabe, Kenji; Taniguchi, Takashi; Ramirez, Jhonattan C.; Campos, Leonardo; Saito, Riichiro; Cançado, Luiz Gustavo; Jório, Ado

doi:10.1021/acs.nanolett.3c00851

Cited by 7 publications

(10 citation statements)

References 39 publications

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“…Nevertheless, debate persists whether the measured coherence length (L C ) is governed by the phonon coherence length or the electron coherence length. As deliberated in [60], the phonon interpretation aligns with the theory of spatially coherent TERS [29][30][31]. However, it necessitates an exceptionally high optical phonon group velocity for graphene in the ballistic regime.…”

Section: Ters Coherence and The Kohn Anomalymentioning

confidence: 74%

“…Similar to graphene, the depletion region at the interface between two differently doped regions of MoS 2 has been successfully imaged, as depicted in figures 5(a) and (c) [60]. Intriguingly, while charge oscillations observed in graphene extend over 50 nm across the junction region (figure 5(b)), in MoS 2 , this phenomenon appears to be twice as large (figure 5(c)).…”

Section: Mos 2 Homojunctionsmentioning

confidence: 85%

“…Through analysis, it is observed that the coherence length (L C ) varies with carrier concentration, manipulated by adjusting the gate voltage (see figure 7(c)). Notably, high values of L C (∼40 nm) [30,31], indicative of doped graphene, are recorded, while L C reaches a minimum at the charge neutrality point [60]. This phenomenon is attributed to Kohn anomaly, wherein the lifetime G-band phonis due to electron-phonon interaction that excites electron-hole pair near the Fermi energy [61,62].…”

Section: Ters Coherence and The Kohn Anomalymentioning

confidence: 96%

“…In graphene devices (figure 7(a)), altering the Fermi energy [59][60][61][62] leads to changes in the Raman intensity of both the G and 2D bands, correlating with the tip-sample distance from 5 nm to 50 nm (figure 7(b)). Through analysis, it is observed that the coherence length (L C ) varies with carrier concentration, manipulated by adjusting the gate voltage (see figure 7(c)).…”

Section: Ters Coherence and The Kohn Anomalymentioning

confidence: 99%

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Nano-Raman spectroscopy of 2D materials

Jorio,

Nadas,

Pereira

et al. 2024

2D Mater.

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The use of nano-Raman spectroscopy to study two-dimensional (2D) systems is presented here. The nano (tip-enhanced) Raman spectroscopy (TERS) technique is briefly introduced, addressing some new theoretical aspects for Raman spectroscopy in the near-field regime, including field coherence, field distribution and the relevance of atomic description and quenching effects. State-of-the-art results in graphene and transition metal dichalcogenides are presented, exploring the connection between micro- and nano-Raman metrology. Various aspects such as defects, homojunctions, twisted-bilayer structures, localized emissions at bubbles, wrinkles, and borders, as well as substrate and coherence effects are addressed in detail. The paper concludes by outlining the perspectives for nano-Raman spectroscopy in 2D systems, highlighting its potential for advancing our understanding of nanoscale phenomena and facilitating further breakthroughs in materials science and characterization.

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Section: Ters Coherence and The Kohn Anomalymentioning

confidence: 74%

Section: Mos 2 Homojunctionsmentioning

confidence: 85%

Section: Ters Coherence and The Kohn Anomalymentioning

confidence: 96%

Section: Ters Coherence and The Kohn Anomalymentioning

confidence: 99%

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Nano-Raman spectroscopy of 2D materials

Jorio,

Nadas,

Pereira

et al. 2024

2D Mater.

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“…Combining SERS and scanning tunneling microscopy (STM) to reveal the origin of ORR activity is essential to address this issue. Ultrahigh vacuum tip enhanced Raman spectroscopy (UHVTERS) is a valuable method to combine the chemical information on SERS with the ultrahigh spatial resolution of STM. − UHVTERS can provide not only chemical information at subnanometer spatial resolution but adsorption-geometry information under controlled environments. , …”

Section: Activity Origin and Catalytic Mechanismsmentioning

confidence: 99%

Activity Origin and Catalytic Mechanism of the M–N–C Catalysts for the Oxygen Reduction Reaction

Ye,

Zhang,

Shen

2024

ACS Materials Lett.

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Oxygen reduction reaction (ORR), involving either a two-electron (2e − ) pathway or a four-electron (4e − ) pathway, is an important reaction in energy conversion and storage systems. It is well-known that metal−nitrogen−carbon (M−N−C) catalysts, as emerging state-of-the-art electrocatalysts, are applied to fuel cells via the 4e − pathway (e.g., Fe−N−C) while generating hydrogen peroxide via the 2e − pathway (e.g., Co−N−C). However, the effects of the MN x and C−N species on the catalytic activity of ORR require thorough clarification. Especially, the real active sites of the M− N−C configuration are a long-standing conundrum. In this review, the latest advanced M−N−C catalysts were categorized according to the ORR pathways and MN x moieties. Then, the effects of coordination atoms, N-coordinated structures, and pH on the activity of the M−N−C catalysts were discussed. The detection and quantification of the active sites of M−N−C catalysts by in situ Raman spectroscopy and electrochemical techniques were summarized. Finally, the opportunities and challenges for the M−N−C catalysts with efficient activity were highlighted.

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