Critical differences in 3D atomic structure of individual ligand-protected nanocrystals in solution

Kim, Byung Hyo; Heo, Jun-Young; Kim, Sungin; Reboul, Cyril; Chun, Hoje; Kang, Dohun; Bae, Hyeonhu; Hyun, Hyejeong; Lim, Jongwoo; Lee, Hoonkyung; Han, Byungchan; Hyeon, Taeghwan; Alivisatos, A. Paul; Ercius, Peter; Elmlund, Hans; Park, Jung Won

doi:10.1126/science.aax3233

Cited by 123 publications

(156 citation statements)

References 42 publications

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“…[12] One of the most effective methods to side-step this problem is to encapsulate the liquid between sheets of 2D materials, [18][19][20] simultaneously reducing the window and liquid thicknesses while also allowing the material of interest to comprise a much higher volumetric fraction of the liquid cell. The advent of graphene and boron-nitride liquid cells (GLCs an BNLCs respectively) has resulted in an outpouring of atomistic structural analysis of dynamic processes in colloidal nanoparticles, [16,[21][22][23][24][25] the compositional analysis of hydrated biological specimens and soft matter outside of cryogenic conditions, [26][27][28][29][30][31][32] and the direct analysis of liquids and their various phases. [15,30,[33][34][35] Perhaps the most critical advantage of the nanoscopic volume of supporting material in the 2D layer liquid cells is the opportunity to use low-dose techniques to mitigate and control beam damage and radiolysis in liquid cells.…”

Section: -D Window-layer Cells For High Spatial/energy Resolutionmentioning

confidence: 99%

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Chemical and bonding analysis of liquids using liquid cell electron microscopy

Ercius¹,

Hachtel²,

Klie³

2020

MRS Bull.

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Section: -D Window-layer Cells For High Spatial/energy Resolutionmentioning

confidence: 99%

“…[21] Recently, utilizing modern DEDs and improvements in reconstruction algorithms allowed the team to achieve true atomic resolution imaging in 3D to determine the coordinates of 9 Pt nanoparticles with approximately 2 nm diameters. [22] A nearly perfect NP and a NP with a defect are shown in Figure 4C…”

Section: Tomographymentioning

confidence: 99%

Chemical and bonding analysis of liquids using liquid cell electron microscopy

Ercius¹,

Hachtel²,

Klie³

2020

MRS Bull.

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“…[11][12][13][14][15][16][17][18] To date, transmission electron microscopy (TEM) remains the most reliable and widely used method for characterizing the morphology of NPs, for which rapid advancement in automated highthroughput electron microscopy has drastically increased both the acquisition rate and the quality of TEM data. [19][20][21][22][23] Increased efficiency in TEM data acquisition now enables the scale of NP shape characterization to increase from tens or hundreds of particles to orders of magnitude more, extracting information at the level of more informative statistical distributions. The information from TEM data at such a scale far exceeds the capability of a human analyst, and hence the development of automated methods for TEM image analysis is imperative.…”

Section: Introductionmentioning

confidence: 99%

AutoDetect-mNP: An Unsupervised Machine Learning Algorithm for Automated Analysis of Transmission Electron Microscope Images of Metal Nanoparticles

Wang

Li²,

Ha³

et al. 2021

Preprint

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The synthesis quality of artificial inorganic nanocrystals is most often assessed by transmission electron microscopy (TEM) for which new high-throughput advances have dramatically increased both the quantity and information richness of metal nanoparticle (mNP) characterization. Existing automated data analysis algorithms of TEM mNP images generally adopt a supervised approach, requiring a significant effort in human preparation of labelled data that reduces objectivity, efficiency, and generalizability. We have developed an unsupervised algorithm AutoDetect-mNP for automated analysis of TEM images that objectively extracts morphological information of convex mNPs from TEM images based on their shape attributes, requiring little to no human input in the process. The performance of AutoDetect-mNP is tested on two datasets of bright field TEM images of Au nanoparticles with different shapes, demonstrating that the algorithm is quantitatively reliable, and can thus serve as a generalizable measure of the morphology distributions of any mNP synthesis. The AutoDetect-mNP algorithm will aid in future developments of high-throughput characterization of newly synthesized mNPs, and the future advent of time-resolved TEM studies that can investigate reaction mechanisms of mNP synthesis and reactivity.

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“…[ 21–25 ] These structural deviations are also sensitive to the local environment on the surface, such as the specific binding chemistry of ligands that passivate surfaces and interacting molecules in the solution or gas phase. [ 25–27 ] Such change in ligands often leads to an increase or decrease in lattice parameters. [ 27 ] In addition, the high surface energy of nanoparticles is strongly correlated with the introduction of defects, including vacancies, stacking faults, and dislocations.…”

Section: Introductionmentioning

confidence: 99%

Determination of the 3D Atomic Structures of Nanoparticles

Kim

Heo

2020

Small Science

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The 3D atomic arrangements of materials determine the free energy landscape, thus governing the physical and catalytic properties of those materials. The 3D structures of nanoparticles can deviate from the periodic atomic arrangement of their bulk counterparts due to the dominance of surface dangling bonds, defects, and dislocations. One approach to understand the structure of nanoparticles and their resulting unique properties involves precise probing of the 3D positions of all constituent atoms of individual nanoparticles. The 3D electron tomography and Brownian one particle reconstruction allow investigation of the 3D atomic positions of nanoparticles. Both methods use transmission electron microscopy (TEM) or scanning TEM (STEM) images of nanoparticles with different projection angles and collect their phase information in reciprocal space to reconstruct the 3D structure of the particles. The thus‐reconstructed 3D maps of metal nanoparticles are highly resolved, facilitating the determination of their atomic coordinates. Grain boundary, dislocation, and lattice expansion are observed on the 3D atomic maps. On the basis of the 3D atomic maps, the physical properties of individual nanoparticles can be accurately predicted, enabling purpose‐driven synthesis.

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Critical differences in 3D atomic structure of individual ligand-protected nanocrystals in solution

Cited by 123 publications

References 42 publications

Chemical and bonding analysis of liquids using liquid cell electron microscopy

Chemical and bonding analysis of liquids using liquid cell electron microscopy

AutoDetect-mNP: An Unsupervised Machine Learning Algorithm for Automated Analysis of Transmission Electron Microscope Images of Metal Nanoparticles

Determination of the 3D Atomic Structures of Nanoparticles

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