Graphene Electrode for Studying CO<sub>2</sub> Electroreduction Nanocatalysts under Realistic Conditions in Microcells

Toleukhanova, Saltanat; Shen, Tzu‐Hsien; Chang, Chen; Swathilakshmi, Swathilakshmi; Bottinelli Montandon, Tecla; Tileli, Vasiliki

doi:10.1002/adma.202311133

Cited by 2 publications

(1 citation statement)

References 38 publications

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“…, graphene) is proposed. For liquid-cell TEM applications, common encapsulation materials include silicon nitride (SiN x ), , silicon oxide (SiO x ), graphene, − and TMDCs . These materials exhibit distinct physical and chemical properties, along with variations in processability and scalability.…”

Section: Challenges and Efforts On Snr Improvementmentioning

confidence: 99%

Advances and Opportunities in Closed Gas-Cell Transmission Electron Microscopy

Koo,

Liu,

Cheng

et al. 2024

Chem. Mater.

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Direct in situ characterizations of the solid–fluid interface on the nanoscale can provide profound implications for addressing bulk-scale enigmas. The advent of closed-cell environmental transmission electron microscopy (E-TEM) enables the implementation of a confined nanoscopic reactor within the high-vacuum microscope. With the encapsulations of reactant fluids and solid species under various stimuli, the whole reaction process can be observed with atomic precision and high temporal resolution. This experimental technique has been adopted widely throughout the field of nanoscience, with applications extending to the synthesis of low-dimensional materials, gas-phase catalysis, and modifications of nanomaterials, where Professor C. N. R. Rao has made substantial contributions over six decades. Here, we delve into the recent representative applications and enhancement strategies of the close gas-cell E-TEM methodology from the early development stages to the latest up-to-date ultrathin (UT) SiN x technique. Remarkable advancements in the capabilities of multimodal data acquisition, including the quantitative electron diffraction, on-site spatiotemporal mapping of the gas molecules, and atomic-resolution real-space imaging in the gas cell E-TEM, are demonstrated. Furthermore, the integration of machine learning (ML)-assisted data acquisition and analysis is anticipated to represent the next major breakthrough, significantly expanding the applicability of gas-cell E-TEM across a wide range of research fields.

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Section: Challenges and Efforts On Snr Improvementmentioning

confidence: 99%

Advances and Opportunities in Closed Gas-Cell Transmission Electron Microscopy

Koo,

Liu,

Cheng

et al. 2024

Chem. Mater.

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Electrochemical Liquid Phase TEM in Aqueous Electrolytes for Energy Applications: the Role of Liquid Flow Configuration

Bejtka,

Fontana,

Gho

et al. 2024

Small Methods

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Electrochemical liquid phase transmission electron microscopy (EC‐LPTEM) is an invaluable tool for investigating the structural and morphological properties of functional materials in electrochemical systems for energy transition. Despite its potential, standardized experimental protocols and a consensus on data interpretation are lacking, due to a variety of commercial and customized electrical and microfluidic configurations. Given the small size of a typical electrochemical cell used in these experiments, frequent electrolyte renewal is crucial to minimize local chemical alterations from reactions and radiolysis. This study explores the effects of modifying the flow configuration within the liquid cell under experimental conditions relevant for energy applications in aqueous‐based electrolytes, revealing how changes in mass transport dynamics drastically influence the electrochemical response of the cell. Two different cell designs are compared: convection‐ and diffusion–governed. Ex situ and in situ comparative flow experiments show that the diffusion cell mitigates gas bubbles formation and improves removal of gaseous products. The electrodeposition of Zn nanostructures and the characterization of a Cu‐based catalyst are presented as proof‐of‐concept experiments for energy storage and CO2 reduction reaction (CO2RR) applications, respectively. The reported findings demonstrate that controlling mass transport in the liquid cell setup is crucial to obtain reliable operando experimental electrochemical conditions.

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Graphene Electrode for Studying CO₂ Electroreduction Nanocatalysts under Realistic Conditions in Microcells

Cited by 2 publications

References 38 publications

Advances and Opportunities in Closed Gas-Cell Transmission Electron Microscopy

Advances and Opportunities in Closed Gas-Cell Transmission Electron Microscopy

Electrochemical Liquid Phase TEM in Aqueous Electrolytes for Energy Applications: the Role of Liquid Flow Configuration

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Graphene Electrode for Studying CO2 Electroreduction Nanocatalysts under Realistic Conditions in Microcells

Cited by 2 publications

References 38 publications

Advances and Opportunities in Closed Gas-Cell Transmission Electron Microscopy

Advances and Opportunities in Closed Gas-Cell Transmission Electron Microscopy

Electrochemical Liquid Phase TEM in Aqueous Electrolytes for Energy Applications: the Role of Liquid Flow Configuration

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Product

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Graphene Electrode for Studying CO₂ Electroreduction Nanocatalysts under Realistic Conditions in Microcells