Taherkhani M, Fritsch B, Jank MPM, Spiecker E, Hutzler A (2021)
Publication Type: Journal article, Original article
Publication year: 2021
Original Authors: Mehran Taherkhani, Birk Fritsch, Michael P. M. Jank, Erdmann Spiecker, Andreas Hutzler
Book Volume: 27
Pages Range: 103-104
Issue: S2
DOI: 10.1017/S1431927621013519
In this study, we model the radiolysis chemistry of aerated AgNO3 solutions during liquid-phase
transmission electron microscopy (LP-TEM) in presence of bromide ions using a Python-based adaption
of the radiolysis model of Schneider et al. [1]. We verify the model qualitatively by comparing the results
with experiments using a graphene-supported microwell liquid cell [2,3]. LP-TEM is a powerful, yet novel
method for analyzing dynamic processes of nanostructures in liquid environment. One of the major
challenges for enabling LP-TEM to become a standard characterization method, however, is the
development of accurate physical models describing electron-beam interactions with liquid specimen, e.g.
heating [4], radiolysis [1,2,5,6], and charging effects [7]. In particular, the model of Schneider et al. [1]
describing radiolysis of deionized and deaerated water under electron beam irradiation has been used
intensively to explain a vast variety of LP-TEM-specific phenomena.
Recently, complex particle growth and dissolution studies investigating gold-silver heterostructures
obtained high interest in research [2,8]. In order to support the proposed interpretation of experimental
results, we elaborate an adaption of Schneider’s radiolysis script to describe the reaction chemistry of
aerated AgNO3 solutions in presence of bromide ions, which originate from stabilizing agents like
cetrimonium bromide (CTAB). Besides water, this requires 36 additional species and yields a reaction set
comprising 232 coupled ordinary differential equations. The original Matlab©-based script is ported to
open source software (Python) as a first step towards an easily accessible simulation program. We find
excellent agreement in both performance and outcome of our script with the initial version. A validation
of our model is achieved by comparison with LP-TEM experiments on silver-shell growth on gold
nanorods using an in-house developed liquid-cell architecture [2,3] in combination with a Philips CM-30
(S)TEM operated at 300 kV and electron flux densities between 104 and 105 e-nm-2s-1
APA:
Taherkhani, M., Fritsch, B., Jank, M.P.M., Spiecker, E., & Hutzler, A. (2021). Modelling the Radiolysis of Silver Nitrate Solutions in presence of Bromide Ions in Liquid-Phase Transmission Electron Microscopy. Microscopy and Microanalysis, 27, 103-104. https://doi.org/10.1017/S1431927621013519
MLA:
Taherkhani, Mehran, et al. "Modelling the Radiolysis of Silver Nitrate Solutions in presence of Bromide Ions in Liquid-Phase Transmission Electron Microscopy." Microscopy and Microanalysis 27 (2021): 103-104.
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