The Atomic Drill Bit: Precision Controlled Atomic Fabrication of 2D Materials

Boebinger, Matthew G.; Brea, Courtney; Ding, Liping; Misra, Sudhajit; Olunloyo, Olugbenga; Yu, Yiling; Xiao, Kai; Lupini, Andrew R.; Ding, Feng; Hu, Guoxiang; Ganesh, Panchapakesan; Jesse, Stephen; Unocic, Raymond R.

doi:10.1002/adma.202210116

Cited by 11 publications

(5 citation statements)

References 66 publications

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“…Second, there are also differences in the core loss regime among the different classes. Here, the NW edge reconstruction is highlighted; these have also been predicted to exhibit metallic behavior ( 42 , 43 ), and their formation through electron beam irradiation and in situ thermal annealing has been extensively investigated ( 44 , 45 ). The EELS structure near 260 eV is most apparent, where the edge is stronger (positive slope, seen in Fig.…”

Section: Discussionmentioning

confidence: 99%

Dynamic STEM-EELS for single-atom and defect measurement during electron beam transformations

Roccapriore,

Torsi,

Robinson

et al. 2024

Sci. Adv.

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This study introduces the integration of dynamic computer vision–enabled imaging with electron energy loss spectroscopy (EELS) in scanning transmission electron microscopy (STEM). This approach involves real-time discovery and analysis of atomic structures as they form, allowing us to observe the evolution of material properties at the atomic level, capturing transient states traditional techniques often miss. Rapid object detection and action system enhances the efficiency and accuracy of STEM-EELS by autonomously identifying and targeting only areas of interest. This machine learning (ML)–based approach differs from classical ML in that it must be executed on the fly, not using static data. We apply this technology to V-doped MoS 2 , uncovering insights into defect formation and evolution under electron beam exposure. This approach opens uncharted avenues for exploring and characterizing materials in dynamic states, offering a pathway to increase our understanding of dynamic phenomena in materials under thermal, chemical, and beam stimuli.

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Section: Discussionmentioning

confidence: 99%

Dynamic STEM-EELS for single-atom and defect measurement during electron beam transformations

Roccapriore,

Torsi,

Robinson

et al. 2024

Sci. Adv.

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“…Cleavage or thinning of the bulk materials to their 2D forms [346] may result in various thin slab to host the cross-dimensional activation strategies. The constant development of nanotechniques further enables the control the variant of 2D materials at an atomic level [347]. Combining them and developing the mass-productions of the 2D-based photocatalysts will bolster materials bases for photocatalytic hydrogen evolution and pollutant removals.…”

Section: Challenges and Outlookmentioning

confidence: 99%

Activating two-dimensional semiconductors for photocatalysis: a cross-dimensional strategy

Botella,

Cao,

Celis

et al. 2024

J. Phys.: Condens. Matter

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The emerging 2D semiconductors substantially extend materials bases for versatile applications such as semiconductor photocatalysis demanding semiconductive matrices and large surface areas. The dimensionality, while endowing 2D semiconductors the unique properties to host photocatalytic functionality of pollutant removal and hydrogen evolution, hurdles the activation paths to form heterogenous photocatalysts where the photochemical processes are normally superior over these on the mono-compositional counterparts. In this perspective, we present a cross-dimensional strategy to employ the nD (n=0-2) clusters or nanomaterials as activation partners to boost the photocatalytic activities of the 2D semiconductors. The formation principles of heterogenous photocatalysts are illustrated specifically for the 2D matrices, followed by selection criteria of them among the vast 2D database. The computer investigations are illustrated in the density functional theory route and machine learning benefitted from the vast samples in the 2D library. Synthetic realizations and characterizations of the 2D heterogenous systems are introduced with an emphasis on chemical methods and advanced techniques to understand materials and mechanistic studies. The perspective outlooks cross-dimensional activation strategies of the 2D materials for other applications such as CO2 removal, and materials matrices in other dimensions which may inspire incoming research within these fields.

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“…STEM was subsequently used as an atomic drill bit for targeted synthesis of specific edge-patterns in 2D TMDs. (Boebinger et al, 2023). Nevertheless, a scalable approach to engineer edges in 2D materials is still lacking, but has significant potential in achieving high HER in TMDs with earth-abundant elements and without involving any critical materials.…”

Section: Energy Conversion: Electrocatalytic Green Hydrogen Productionmentioning

confidence: 99%

Defects go green: using defects in nanomaterials for renewable energy and environmental sustainability

Fuhr,

Sumpter,

Ganesh

2023

Front. Nanotechnol.

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Induction of point defects in nanomaterials can bestow upon them entirely new physics or augment their pre-existing physical properties, thereby expanding their potential use in green energy technology. Predicting structure-property relationships for defects a priori is challenging, and developing methods for precise control of defect type, density, or structural distribution during synthesis is an even more formidable task. Hence, tuning the defect structure to tailor nanomaterials for enhanced device performance remains an underutilized tool in materials design. We review here the state of nanomaterial design through the lens of computational prediction of defect properties for green energy technology, and synthesis methods to control defect formation for optimal performance. We illustrate the efficacy of defect-focused approaches for refining nanomaterial physics by describing several specific applications where these techniques hold potential. Most notably, we focus on quantum dots for reabsorption-free solar windows and net-zero emission buildings, oxide cathodes for high energy density lithium-ion batteries and electric vehicles, and transition metal dichalcogenides for electrocatalytic green hydrogen production and carbon-free fuels.

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The Atomic Drill Bit: Precision Controlled Atomic Fabrication of 2D Materials

Cited by 11 publications

References 66 publications

Dynamic STEM-EELS for single-atom and defect measurement during electron beam transformations

Dynamic STEM-EELS for single-atom and defect measurement during electron beam transformations

Activating two-dimensional semiconductors for photocatalysis: a cross-dimensional strategy

Defects go green: using defects in nanomaterials for renewable energy and environmental sustainability

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