Graphene‐Enhanced 3D Chemical Mapping of Biological Specimens at Near‐Atomic Resolution

Adineh, Vahid R.; Zheng, Changxi; Zhang, Qianhui; Marceau, Ross K. W.; Liu, Boyin; Chen, Yu; J., Kae; Weyland, Matthew; Velkov, Tony; Cheng, Wenlong; Li, Jian; Fu, Jianzhong

doi:10.1002/adfm.201801439

Cited by 19 publications

(28 citation statements)

References 44 publications

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“…22 Highly packed Au + (197 Da) ions are detected within a confined region, which represents a single AuNP. 14 H + (1 Da) ions are distributed across both the W and solution volume due to background H + residuals in the vacuum, 30,31 similar with H2 + and H3 + . In the following three repeats of APT imaging with the same batch of AuNP solution, no significant changes of ionic species have been identified in the acquired mass spectra, as shown in Figure S2.…”

Section: Apt Imaging Of Graphene-encapsulated Aunp Specimenmentioning

confidence: 99%

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Direct Imaging of Liquid–Nanoparticle Interfaces with Atom Probe Tomography

et al. 2020

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Understanding the structure and chemical composition at the liquid-nanoparticle (NP) interface is crucial for a wide range of physical, chemical and biological processes. In this study, direct imaging of the liquid-NP interface by atom probe tomography (APT) is reported for the first time, which reveals the distributions and the interactions of key atoms and molecules in this critical domain. The APT specimen is prepared by controlled graphene encapsulation of the solution containing nanoparticles on a metal tip, with an end radius in the range of 50 nm to allow field ionization and evaporation. Using Au nanoparticles (AuNPs) in suspension as an example, analysis of the mass spectrum and three-dimensional (3D) chemical maps from APT provides a detailed image of the water-gold interface with near-atomic resolution. At the watergold interface, the formation of an electrical double layer (EDL) rich in water (H2O) molecules has been observed, which results from the charge from the binding between the trisodiumcitrate layer and the AuNP. In the bulk water region, the density of reconstructed H2O has been shown to be consistent, reflecting a highly packed density of H2O molecules after graphene encapsulation. This study is the first demonstration of direct imaging of liquid-NP interface using APT with results providing an atom-by-atom 3D dissection of the liquid-NP interface.

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Section: Apt Imaging Of Graphene-encapsulated Aunp Specimenmentioning

confidence: 99%

“…Recently, graphene has been employed to coat insulated specimens for voltage-pulsed APT imaging, 14 due to its outstanding conductivity and mechanical properties. Imaging liquid specimens has also been proved to be feasible with minimal damages to unravel the protein structure.…”

Section: Introductionmentioning

confidence: 99%

Direct Imaging of Liquid–Nanoparticle Interfaces with Atom Probe Tomography

et al. 2020

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“…The recent efforts around specimen coating using only a few graphene sheets 50,56,57 demonstrates that even very thin conductive layer can achieve the necessary increase in conductivity and sufficient shielding to enable APT analysis. These species may simply neutralise dangling bonds for instance or modify the very local conduction properties, enabling surface conductivity, i.e.…”

Section: Intrinsic Shieldingmentioning

confidence: 99%

Atom probe analysis of electrode materials for Li-ion batteries: challenges and ways forward

et al. 2022

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“…More recently, Adineh et al developed a unique approach to sandwich biological materials (e.g., metal nanoparticles and bacterial cell culture) between a tungsten needle tip and a graphene coating [ 45 ]. This was accomplished by lowering a small-diameter metal ring with a suspended droplet of biomaterial sample with a graphene film floating on top, over a tungsten needle tip.…”

Section: Key Research Driversmentioning

confidence: 99%

New frontiers in atom probe tomography: a review of research enabled by cryo and/or vacuum transfer systems

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Bagot

Devaraj

et al. 2020

Materials Today Advances

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There has been a recent surge in the use of cryo and/or vacuum specimen preparation and transfer systems to broaden the scope of research enabled by the microscopy technique of atom probe tomography. This is driven by the fact that, as for many microscopes, the application of atom probes to air- and temperature-sensitive materials or wet biological specimens has previously been limited by transfer through air at room temperature. Here we provide an overview of areas of research that benefit from these new transfer and analysis protocols, as well as a review of current advances in transfer devices, environmental cells, and glove boxes for controlled specimen manipulation. This includes the study of catalysis and corrosion, biological samples, liquid-solid interfaces, natural aging, and the distribution of hydrogen in materials.

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Graphene‐Enhanced 3D Chemical Mapping of Biological Specimens at Near‐Atomic Resolution

Cited by 19 publications

References 44 publications

Direct Imaging of Liquid–Nanoparticle Interfaces with Atom Probe Tomography

Direct Imaging of Liquid–Nanoparticle Interfaces with Atom Probe Tomography

Atom probe analysis of electrode materials for Li-ion batteries: challenges and ways forward

New frontiers in atom probe tomography: a review of research enabled by cryo and/or vacuum transfer systems

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