Novel microchip for in situ TEM imaging of living organisms and bio-reactions in aqueous conditions

Liu, Kuo Liang; Wu, Chien Chen; Huang, Ying; Peng, Hwei-Ling; Chang, Hwan‐You; Chang, Po‐Cheng; Hsu, Lih‐Hsing; Yew, Tri‐Rung

doi:10.1039/b804986f

Cited by 99 publications

(87 citation statements)

References 35 publications

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“…The past few years have seen a flare of efforts to develop devices that allow real-time, in situ imaging of dynamical, nanoscale processes in fluids with the resolution of a TEM or STEM (scanning TEM) [1][2][3][4][5][6][7][8][9][10][11][12]. Liquid-cell TEM-STEM devices confine a thin slice of liquid sample in a sealed chamber sandwiched between two electron-transparent membranes, thus preventing evaporation while allowing the electron beam to pass through the sample to produce an image.…”

Section: Introductionmentioning

confidence: 99%

In situliquid-cell electron microscopy of colloid aggregation and growth dynamics

2011

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We report on real-time observations of the aggregation of gold nanoparticles using a custom-made liquid cell that allows for in situ electron microscopy. Process kinetics and fractal dimension of the aggregates are consistent with three-dimensional cluster-cluster diffusion-limited aggregation, even for large aggregates, for which confinement effects are expected. This apparent paradox was resolved through in situ observations of the interactions between individual particles as well as clusters at various stages of the aggregation process that yielded the large aggregates. The liquid cell described herein facilitates real-time observations of various processes in liquid media with the high resolution of the electron microscope. Disciplines Engineering | Mechanical Engineering CommentsSuggested Citation: We report on real-time observations of the aggregation of gold nanoparticles using a custom-made liquid cell that allows for in situ electron microscopy. Process kinetics and fractal dimension of the aggregates are consistent with three-dimensional cluster-cluster diffusion-limited aggregation, even for large aggregates, for which confinement effects are expected. This apparent paradox was resolved through in situ observations of the interactions between individual particles as well as clusters at various stages of the aggregation process that yielded the large aggregates. The liquid cell described herein facilitates real-time observations of various processes in liquid media with the high resolution of the electron microscope.

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Section: Introductionmentioning

confidence: 99%

In situliquid-cell electron microscopy of colloid aggregation and growth dynamics

2011

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“…Recently, Ross et al have developed a liquid cell reactor that can be placed in a special TEM sample holder, which was used to image the dynamic growth of Cu clusters on a surface during electrochemical plating using a TEM with a resolution of 5 nm (24) (also see other related techniques (25,26)). Here, we employ this TEM capability in a newly designed self-contained liquid cell with an improved resolution in the subnanometer range (see the details on the liquid cells in SOM).…”

mentioning

confidence: 99%

Observation of Single Colloidal Platinum Nanocrystal Growth Trajectories

Zheng

Smith

Jun

et al. 2009

Science

1,270

1,375

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Mergers and Acquisitions The crystallization of small molecules or polymers is often described in terms of a nucleation stage, where initial clusters form, followed by a distinct growth stage. Growth can come from the addition of unbound molecules, or through “Ostwald ripening” where larger crystals grow at the expense of smaller ones due to thermodynamic effects. Zheng et al. (p. 1309 ) studied the growth of platinum nanocrystals inside a transmission electron microscope using a special liquid cell, allowing observation of crystal growth in situ. Both monomer addition to growing particles and the coalescence of two particles were observed. The specific growth mechanism appeared to be governed by the size of each of the particles. The combination of growth processes makes it possible for an initially broad distribution of particles to narrow into an almost uniform one.

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“…This SLC platform sealed the aqueous electrolyte by assembling two silicon chips with thin silicon nitride membranes in a face-to-face configuration. This flip-chip approach allows imaging chemical reactions in liquids with high spatial resolution [34,37,38,41,76] with different membranes of silicon nitride, silicon dioxide, or polymer, such that it has been adopted in various studies, including cell imaging [77][78][79] and nanoparticle synthesis [38] in solutions. For example, electrochemical deposition of polycrystalline Au [76], anisotropic electrodeposition of nickel nanograins [80], and electrochemical growth of single crystal lead dendrites through nucleation, aggregation, alignment, and attachment of randomly oriented small grains [81] were imaged by using electrochemical SLCs.…”

Section: Platforms With a Sealed-cell Configuration For In-situ Tem Ementioning

confidence: 99%

Advances in sealed liquid cells for in-situ TEM electrochemial investigation of lithium-ion battery

Wu¹,

Yao²

2015

Nano Energy

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Novel microchip for in situ TEM imaging of living organisms and bio-reactions in aqueous conditions

Cited by 99 publications

References 35 publications

In situliquid-cell electron microscopy of colloid aggregation and growth dynamics

In situliquid-cell electron microscopy of colloid aggregation and growth dynamics

Observation of Single Colloidal Platinum Nanocrystal Growth Trajectories

Advances in sealed liquid cells for in-situ TEM electrochemial investigation of lithium-ion battery

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