AI Article Synopsis
- The study focuses on how different surface chemistries of copper selenide (CuSe) nanoparticles affect the way metals are deposited on them, especially in the context of integrating these particles into nanoheterostructures.
- Researchers tested 12 different ligands to see how they influence metal deposition, finding that most did not significantly change the pattern or amount of deposition.
- However, quaternary alkylammonium bromides showed distinct deposition patterns, suggesting a special cooperative binding effect at play, which could inform future strategies for modifying CuSe nanoparticles.
Article Abstract
The use of nanoparticle surface chemistry to direct metal deposition has been well-studied in the modification of metal nanoparticle substrates but is not yet well-established for metal chalcogenide particle substrates, although integration of these particles into nanoheterostructures is of high interest. In this report, we investigate the effect of CuSe surface chemistry on the morphology of metal deposition on these plasmonic semiconductor nanoparticles. Specifically, we functionalize CuSe nanoparticles with a suite of 12 different ligands and investigate how different aspects of the ligand structure do or do not impact the morphology and extent of subsequent metal deposition on the CuSe surface. Surprisingly, our results indicate that the morphology of the resulting metal deposits and the extent of metal deposition onto the existing CuSe particle substrate are indistinguishable for the majority of ligands tested. An exception to these findings is observed for particles functionalized by quaternary alkylammonium bromides, which exhibit statistically distinct metal deposition patterns compared to all other ligands tested. We hypothesize that this unique behavior is due to a cooperative binding mechanism of the quaternary alkylammonium bromides to the surface of copper selenide. Taken together, these results yield both new strategies for controlling postsynthetic modification of copper selenide nanoparticles and also reveal limitations of surface chemistry-based approaches for this system.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11308770 | PMC |
| http://dx.doi.org/10.1021/acs.langmuir.4c01817 | DOI Listing |
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