通过液相电子显微镜和反应通量分析发现分子中间体和非典型纳米粒子形成机制

Jiayue Sun, Birk Fritsch, Andreas Körner, Mehran Taherkhani, Chiwoo Park, Mei Wang, Andreas Hutzler, Taylor J. Woehl
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摘要

金属纳米粒子的形成动力学一般通过基于质量传输和热力学的模型来描述,如扩散限制生长和经典成核理论(CNT)。然而,金属单体通常被假定为前体,因此分子中间体的身份及其对纳米粒子形成的贡献尚不清楚。本文利用液相透射电子显微镜(LPTEM)和反应动力学模型建立了银纳米粒子形成过程中的成核和生长机制,并发现了分子中间产物。定量透射电子显微镜测量结果表明,银纳米粒子的成核率降低,而生长率几乎与电子剂量率无关。反应动力学模拟显示,Ag4 和 Ag- 与实验测定的生长率具有相似的剂量依赖性。我们表明,实验生长率与通过这些物种附着在纳米粒子上的扩散限制生长是一致的。成核率的剂量率依赖性与 CNT 不一致。我们提出了一种反应受限的成核机制,并证明实验成核动力学与 Ag42+ 在毫秒级时间尺度上的聚集率一致。动力学模拟的反应吞吐量分析揭示了介导中间浓度的形成和衰变途径。我们展示了定量 LPTEM 与动力学建模相结合在建立纳米粒子形成机制和主要中间产物方面的强大功能。
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Discovery of Molecular Intermediates and Nonclassical Nanoparticle Formation Mechanisms by Liquid Phase Electron Microscopy and Reaction Throughput Analysis
Formation kinetics of metal nanoparticles are generally described via mass transport and thermodynamics-based models, such as diffusion-limited growth and classical nucleation theory (CNT). However, metal monomers are commonly assumed as precursors, leaving the identity of molecular intermediates and their contribution to nanoparticle formation unclear. Herein, liquid phase transmission electron microscopy (LPTEM) and reaction kinetic modeling are utilized to establish the nucleation and growth mechanisms and discover molecular intermediates during silver nanoparticle formation. Quantitative LPTEM measurements show that their nucleation rate decreases while growth rate is nearly invariant with electron dose rate. Reaction kinetic simulations show that Ag4 and Ag follow a statistically similar dose rate dependence as the experimentally determined growth rate. We show that experimental growth rates are consistent with diffusion-limited growth via the attachment of these species to nanoparticles. The dose rate dependence of nucleation rate is inconsistent with CNT. A reaction-limited nucleation mechanism is proposed and it is demonstrated that experimental nucleation kinetics are consistent with Ag42+ aggregation rates at millisecond time scales. Reaction throughput analysis of the kinetic simulations uncovered formation and decay pathways mediating intermediate concentrations. We demonstrate the power of quantitative LPTEM combined with kinetic modeling for establishing nanoparticle formation mechanisms and principal intermediates.
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