Abstract
With Liquid-Cell Transmission Electron Microscopy (LCTEM) we can observe the kinetic processes taking place in nanoscale materials that are in a solvated environment. However, the beam-driven solvent radiolysis, which results from the microscope's high-energy electron beam, can dramatically influence the dynamics of the system. Recent research suggests that radical-induced redox chemistry can be used to investigate the various redox-driven dynamics for a wide range of functional nanomaterials. In view of this, the interplay between the formation of various highly reactive radiolysis species and the nanomaterials under investigation needs to be quantified in order to formulate new strategies for nanomaterials research. We have developed a comprehensive radiolysis model by using the electron-dose rate, the temperature of the solvent, the H2 and O2 gas saturation concentrations and the pH values as the key variables. These improved kinetic models make it possible to simulate the material's specific radical-induced redox reactions. As in the case of the Au model system, the kinetic models are presented using Temperature/Dose-rate Redox potential (TDR) diagrams, which indicate the equilibrium [Au0]/[Au+] concentration ratios that are directly related to the temperature-/dose-rate-dependent precipitation or dissolution regions of the Au nanoparticles. Our radiolysis and radical-induced redox models were successfully verified using previously reported data from low-dose experiments with γ radiation and experimentally via TDR-dependent LCTEM. The presented study represents a holistic approach to the radical-induced redox chemistry in LCTEM, including the complex kinetics of the radiolysis species and their influence on the redox chemistry of the materials under investigation, which are represented here by Au nanoparticles.
Highlights
A transmission electron microscope (TEM) allows the direct imaging and spectroscopy of nanoparticles (NPs)
Several previous studies were focused on the precipitation and dissolution dynamics of different nanostructured systems utilizing electron-beam-induced phenomena inside a liquid-cell TEM, for example, Cu and Ni nanocrystals,[7] Pd dendritic nanostructures,[8] alloys such as Ag–Pd7 or more complex structures like CaCO3 and CeO2.10 One of the most commonly studied materials using the liquid-cell electron-microscopy (LCTEM) technique is gold,[11,12,13,14] with the aim being to investigate the dynamics of the precipitation and dissolution of Au NPs in various aqueous environments
The proposed Temperature/Dose-rate Redox potential (TDR) diagrams obtained from the improved kinetic radiolysis model provide us with a better simulation of the precipitation, growth and dissolution of Au NPs under a variety of Liquid-Cell Transmission Electron Microscopy (LCTEM) conditions
Summary
A transmission electron microscope (TEM) allows the direct imaging and spectroscopy of nanoparticles (NPs). Recent advances have partially overcome this limitation with the use of specialized TEM harnesses, i.e., liquid cells, that can maintain the liquid in a closed environment, allowing the imaging and spectroscopy of samples in liquid media without affecting the vacuum in the microscope.[1] The samples are held between two silicon chips that have electron-transparent windows made from silicon nitride[2] or graphene.[3] This allows us to study dynamic phenomena taking place in the materials in solvated environments[4] with high spatial and temporal resolution.[5,6]. The ndings revealed a complex interplay of thermodynamic and kinetic parameters that in uence the nal morphologies, begging questions about the in uence of electron-beam-induced phenomena.[11,12,15,16,17,18,19,20,21]
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