Electron–Water Interactions and Implications for Liquid Cell Electron Microscopy

Schneider, Nicholas M.; Norton, Michael M.; Mendel, Brian J.; Grogan, Joseph M.; Ross, Frances M.; Bau, Haim H.

doi:10.1021/jp507400n

Cited by 572 publications

(975 citation statements)

References 43 publications

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“…To analyze the evolution of the growth rate after nucleation, we first evaluated the effects of the electron beam, which increases the temperature of the specimen (18) and generates chemical species (19), on our system. We observed the growth of orthorhombic lysozyme crystals under different electron fluxes ( Fig.…”

Section: Significancementioning

confidence: 99%

Two types of amorphous protein particles facilitate crystal nucleation

Yamazaki

Kimura

Vekilov

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

163

165

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Nucleation, the primary step in crystallization, dictates the number of crystals, the distribution of their sizes, the polymorph selection, and other crucial properties of the crystal population. We used timeresolved liquid-cell transmission electron microscopy (TEM) to perform an in situ examination of the nucleation of lysozyme crystals. Our TEM images revealed that mesoscopic clusters, which are similar to those previously assumed to consist of a dense liquid and serve as nucleation precursors, are actually amorphous solid particles (ASPs) and act only as heterogeneous nucleation sites. Crystalline phases never form inside them. We demonstrate that a crystal appears within a noncrystalline particle assembling lysozyme on an ASP or a container wall, highlighting the role of heterogeneous nucleation. These findings represent a significant departure from the existing formulation of the two-step nucleation mechanism while reaffirming the role of noncrystalline particles. The insights gained may have significant implications in areas that rely on the production of protein crystals, such as structural biology, pharmacy, and biophysics, and for the fundamental understanding of crystallization mechanisms.nucleation | protein | lysozyme | transmission electron microscopy | in situ observation C rystallization can be divided into two processes: nucleation and crystal growth. The crystal growth process has been well examined for a long time, yet the nucleation process is not understood; for example, the nucleation rate of crystals provides a textbook example of order-of-magnitude discrepancies between theoretical predictions and experimental results. Recent proposals have attributed these discrepancies to a nonclassical nucleation pathway, along which a structured crystalline embryo forms within a highly concentrated disordered precursor (1). This mechanism was first proposed for protein crystals (2, 3). Direct observations have demonstrated its applicability to organic (4), inorganic (5, 6), and colloidal (7) crystals. In proteins, clusters of protein molecules have been suggested as precursors; these clusters have mesoscopic sizes from several tens to several hundreds of nanometers and are considered to behave like liquids. It has also been suggested that the precursor is thermodynamically stable with respect to the mother liquid phase but is metastable or unstable with respect to the crystalline phase. The latter nature of the precursor differs from the stable macroscopically dense liquid formed as a result of the liquid-liquid phase separation (8). Such protein-rich mesoscopic clusters have been observed for many proteins, primarily using optical techniques, and have been tentatively identified as precursors for crystal nucleation (9-12). Several important questions concerning this mechanism remain unanswered. First, are the observed mesoscopic clusters actually liquid-like or solid-amorphous? Second, do they play an active role in crystal nucleation? In addition, finally, do the clusters serve as classical heteroge...

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Section: Significancementioning

confidence: 99%

Two types of amorphous protein particles facilitate crystal nucleation

Yamazaki

Kimura

Vekilov

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

163

165

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“…18,21,22,27,28 However, recent experimental observations have shown that these effects can be quantified, controlled and mitigated using calibrated electron doses. [28][29][30] As a result, in situ TEM observations can be used as an accurate starting point for understanding nanoparticle behavior in liquids.…”

mentioning

confidence: 99%

Understanding the Role of Solvation Forces on the Preferential Attachment of Nanoparticles in Liquid

Welch¹,

Woehl²,

Park

et al. 2015

ACS Nano

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Optimization of colloidal nanoparticle synthesis techniques requires an understanding of underlying particle growth mechanisms. Non-classical growth mechanisms are particularly important as they affect nanoparticle size and shape distributions which in turn influence functional properties. For example, preferential attachment of nanoparticles is known to lead to the formation of mesocrystals, although the formation mechanism is currently not well understood. Here we employ in situ liquid cell scanning transmission electron microscopy (STEM) and steered molecular dynamics (SMD) simulations to demonstrate that the experimentally observed preference for end-to-end attachment of silver nanorods is a result of weaker solvation forces occurring at rod ends. SMD reveals that when the side of a nanorod approaches another rod, perturbation in the surface bound water at the nanorod surface creates significant energy barriers to attachment. Additionally, rod morphology (i.e. facet shape) effects can explain the majority of the side attachment effects that are observed experimentally.

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“…In addition, for the specific case of aqueous corrosion studies, the electron beam that is used as the imaging probe has two principle detrimental effects: first, it may charge the sample through direct electron transfer, which could lead to a change in the temperature of the solution and/or sample (Cazaux, 1995;Zheng et al, 2009); second, the beam may stimulate radiolysis in the electrolyte subtly changing its chemistry. These can change the pH and, together with temperature, can accelerate the electrochemical reaction at the Helmholtz double layer in the system (Schneider et al, 2014).…”

Section: In Situ Aqueous Studies: Corrosion Basicsmentioning

confidence: 99%

Practical Aspects of Electrochemical Corrosion Measurements During In Situ Analytical Transmission Electron Microscopy (TEM) of Austenitic Stainless Steel in Aqueous Media

et al. 2017

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The capability to perform liquid in situ transmission electron microscopy (TEM) experiments provides an unprecedented opportunity to examine the real-time processes of physical and chemical/ electrochemical reactions during the interaction between metal surfaces and liquid environments. This work describes the requisite steps to make the technique fully analytical, from sample preparation, through modifications of the electrodes, characterization of electrolytes, and finally to electrochemical corrosion experiments comparing in situ TEM to conventional bulk cell and microcell configurations.

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Electron–Water Interactions and Implications for Liquid Cell Electron Microscopy

Cited by 572 publications

References 43 publications

Two types of amorphous protein particles facilitate crystal nucleation

Two types of amorphous protein particles facilitate crystal nucleation

Understanding the Role of Solvation Forces on the Preferential Attachment of Nanoparticles in Liquid

Practical Aspects of Electrochemical Corrosion Measurements During In Situ Analytical Transmission Electron Microscopy (TEM) of Austenitic Stainless Steel in Aqueous Media

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