Development of Experiment and Theory to Detect and Predict Ligand Phase Separation on Silver Nanoparticles |
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| Authors: | Zachary Farrell Steve Merz Jon Seager Caroline Dunn Dr Sergei Egorov Dr David L Green |
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| Institution: | 1. University of Virginia, Department of Chemical Engineering, Charlottesville, VA 22904 (USA);2. University of Virginia, Department of Chemistry, McCormick Road, Charlottesville, VA 22904 (USA) |
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| Abstract: | MALDI mass‐spectrometry measurements are combined with self‐consistent mean‐field (SCF) calculations to detect and predict ligand phase separation on Ag nanoparticles. The experimental and theoretical techniques complement each other by enabling quantification of the nearest‐neighbor distribution of a ligand mixture in a monolayer shell. By tracking a characteristic metallic fragment family, analysis of a MALDI spectrum produces a frequency distribution corresponding to specific ligand patterning. Inherent to the SCF calculation is the enumeration of local interactions that dictate ligand assembly. Interweaving MALDI and SCF facilitates a comparison between the experimentally and theoretically derived frequency distributions as well as their deviation from a well‐mixed state. Thus, we combine these techniques to detect and predict phase separation in monolayers that mix uniformly or experience varying degrees of de‐mixing, including microphase separation and stripe formation. Definition of MALDI removed as this is a commonly recognized technique. |
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| Keywords: | mass spectrometry nanoparticles nanotechnology self‐assembly statistical thermodynamics |
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