Visualizing Ligand-Mediated Bimetallic Nanocrystal Formation Pathways with <i>in Situ</i> Liquid-Phase Transmission Electron Microscopy Synthesis

Wang, Mei; Leff, Asher C.; Li, Yue; Woehl, Taylor J.

doi:10.1021/acsnano.0c07131

Cited by 29 publications

(41 citation statements)

References 88 publications

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“… ,, Since all particles imaged after this point showed dendritic growth behavior, it is reasonable to assume that the mixing and exchange of flowed HAuCl 4 solution had completed by ∼60 min, consistent with previous reports. ,, Interestingly, the growth pathway observed after ∼45 min of fluid flow, representing intermediate concentrations of ligand and Au precursor, showed the development of a tetrahedral nanoparticle product ( T d ) from the original RD ( O h ) seed (Figure b and Movie S2), suggesting a complex interplay between thermodynamic and kinetic factors being responsible for the symmetry reduction growth mechanism. Although the precise radiolytic chemistry inside a liquid cell experiment is difficult to quantify, ,, the particle growth reactions described above were imaged using identical electron dose rates, indicating that the observed differences are better attributed to energetic arguments rather than effects of the electron beam.…”

Section: Resultsmentioning

confidence: 99%

Understanding Symmetry Breaking at the Single-Particle Level via the Growth of Tetrahedron-Shaped Nanocrystals from Higher-Symmetry Precursors

et al. 2021

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The vast majority of single crystalline metal nanoparticles adopt shapes in the O h point group as a consequence of the symmetry of the underlying face-centered cubic (FCC) crystal lattice. Tetrahedra are a notable exception to this rule, and although they have been observed in several syntheses, their growth mechanism, and the symmetry-reduction process that necessarily characterizes it, is poorly understood. Here, a symmetry breaking mechanism is revealed by in situ liquid flow cell transmission electron microscopy (TEM) observation of seeded growth in which tetrahedra nanoparticles are formed from higher symmetry seeds. Real-time observation of the growth demonstrates a kinetically driven pathway during which rhombic dodecahedra nanoparticles transition to tetrahedra through tristetrahedra intermediates, with an accompanying surface facet evolution from {110} to {111} via {hhl} (where h > l), respectively. On the basis of these data, we propose a mechanism that relies on a rapid loss of inversion symmetry in the initial stages of the reaction, followed by differential reactivity of tips vs faces under conditions of relatively high supersaturation and moderate ligand concentration. The application of these insights to ex situ synthesis conditions allowed for an improved yield of tetrahedra nanoparticles. This work sheds an important mechanistic light on the crystallographic underpinnings of nanoparticle shape and symmetry transformations and highlights the importance of single-particle characterization tools for monitoring nanoscale phenomena.

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Section: Resultsmentioning

confidence: 99%

Understanding Symmetry Breaking at the Single-Particle Level via the Growth of Tetrahedron-Shaped Nanocrystals from Higher-Symmetry Precursors

et al. 2021

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“…Prior works have established that alcohols, such as isopropanol and tert-butanol, and other organic molecules can act as hydroxyl radical scavengers to mitigate radiation damage to organic molecules during LP-TEM imaging. 50,[56][57][58][59] We added 1 M tert-butanol in DI water as a radical scavenger to test its impact on electron beam damage of BPEI in the presence of silver nanoparticles (Figure 6). Similar to the experiment without any nanoparticles, there was no visible change in fluorescence intensity in the image regions exposed for 30 seconds and 1 minute at a dose rate of 0.274 MGy/s.…”

Section: Resultsmentioning

confidence: 99%

“…Several prior works by our group and others have demonstrated irreversible electron beam induced aggregation of polymer ligand capped nanoparticles during LP-TEM. 4,57,64 It is plausible that electron beam induced intermolecular crosslinking and chain scission of polymer ligands will contribute to nanoparticle aggregation by reducing nanoparticle colloidal stability or covalently linking nanoparticles together. An important implication of this process is that irreversible electron beam induced aggregation of nanoparticles is a kinetically controlled process driven by radical reactions, making it distinct from selfassembly, which is a reversible process driven by interparticle interactions.…”

Section: Discussionmentioning

confidence: 99%

“…72 A recent study by our group showed that PEG -SH ligands act as radical scavengers for hydroxyl radicals by hydrogen abstraction from the thiol groups and PEG chain. 57 In aqueous solutions of PEG and polyacrylamide, an uncharged polymer, intermolecular and intramolecular crosslinking prevails over degradation in deoxygenated solutions while main chain scission dominates with oxygen present. 40,73,74 Therefore, the molecular structure of the ligands are important in determining the successive radiation driven reactions of polymeric capping ligands during LP-TEM experiments.…”

Section: Discussionmentioning

confidence: 99%

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Visualizing Electron Beam-Capping Ligand Reactions for Controlled Nanoparticle Imaging with Liquid Phase Transmission Electron Microscopy

Dissanayake¹,

Wang²,

Woehl

2021

Preprint

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Liquid phase transmission electron microscopy (LP-TEM) enables real-time imaging of nanoparticle self-assembly, formation, and etching with single nanometer resolution. Despite the importance of organic nanoparticle capping ligands in these processes, the effect of electron beam irradiation on surface bound and soluble capping ligands during LP-TEM imaging has not been investigated. Here we use correlative LP-TEM and fluorescence microscopy (FM) to demonstrate that polymeric nanoparticle ligands undergo competing crosslinking and chain scission reactions that non-monotonically modify ligand coverage over time. Branched polyethylenimine (BPEI) coated silver nanoparticles were imaged with dose-controlled LP-TEM followed by labeling their primary amine groups with fluorophores to visualize the local thickness of adsorbed capping ligands. FM images showed that free ligands crosslinked in the LP-TEM image area over imaging times of tens of seconds, enhancing local capping ligand coverage on nanoparticles and silicon nitride membranes. Nanoparticle surface ligands underwent chain scission over irradiation times of minutes to tens of minutes, which depleted surface ligands from the nanoparticle and silicon nitride surface. Conversely, solutions of only soluble capping ligand underwent successive crosslinking reactions with no chain scission, suggesting nanoparticles enhanced the chain scission reactions by acting as radiolysis hotspots. The addition of a hydroxyl radical scavenger, tert-butanol, eliminated chain scission reactions and slowed the progression of crosslinking reactions. These experiments have important implications for performing controlled and reproducible LP-TEM nanoparticle imaging as they demonstrate the electron beam can significantly alter ligand coverage on nanoparticles in a non-intuitive manner. They emphasize the need to understand and control the electron beam radiation chemistry of a given sample to avoid significant perturbations to the nanoparticle capping ligand chemistry, which are invisible in electron micrographs.<br>

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“…Indeed, success in LCTEM experiments heavily depends on the flux (e – Å –2 s –1 ) and fluence (e – Å –2 ) used to observe a given nanoscale process. − Solvated soft materials typically experience radiation damage by undergoing secondary reactions with radicals produced from solvent radiolysis, causing a perturbation in the chemistry and dynamics of the nanomaterials under investigation. − The analysis of the liquid-cell chips after imaging ( i.e. , post-mortem analysis) can be performed to verify morphology and the extent of the electron beam effects in the observed dynamic process. ,, Specifically for polymers and peptides, we have reported the use of matrix-assisted laser desorption/ionization imaging mass spectrometry (MALDI-IMS) to characterize the extent of electron beam damage at the chemical level. , Here, we observe FF assemblies in real-time via LCTEM and examine the effect of the electron beam through post-mortem surface characterization via time-of-flight secondary ion mass spectroscopy (ToF-SIMS).…”

Section: Introductionmentioning

confidence: 99%

Dipeptide Nanostructure Assembly and Dynamics via in Situ Liquid-Phase Electron Microscopy

et al. 2021

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In this paper, we report the in situ growth of FF nanotubes examined via liquid-cell transmission electron microscopy (LCTEM). This direct, high spatial, and temporal resolution imaging approach allowed us to observe the growth of peptide-based nanofibrillar structures through directional elongation. Furthermore, the radial growth profile of FF nanotubes through the addition of monomers perpendicular to the tube axis has been observed in real-time with sufficient resolution to directly observe the increase in diameter. Our study demonstrates that the kinetics, dynamics, structure formation, and assembly mechanism of these supramolecular assemblies can be directly monitored using LCTEM. The performance of the peptides and the assemblies they form can be verified and evaluated using post-mortem techniques including time-of-flight secondary ion mass spectrometry (ToF-SIMS).

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Visualizing Ligand-Mediated Bimetallic Nanocrystal Formation Pathways with in Situ Liquid-Phase Transmission Electron Microscopy Synthesis

Cited by 29 publications

References 88 publications

Understanding Symmetry Breaking at the Single-Particle Level via the Growth of Tetrahedron-Shaped Nanocrystals from Higher-Symmetry Precursors

Understanding Symmetry Breaking at the Single-Particle Level via the Growth of Tetrahedron-Shaped Nanocrystals from Higher-Symmetry Precursors

Visualizing Electron Beam-Capping Ligand Reactions for Controlled Nanoparticle Imaging with Liquid Phase Transmission Electron Microscopy

Dipeptide Nanostructure Assembly and Dynamics via in Situ Liquid-Phase Electron Microscopy

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