Highly concentrated single-chain atomic crystal LiMo3Se3 solution using ion-exchange chromatography

Ion-exchange chromatography can be used to effectively replace the lithium ion of LiMo3Se3 with a proton. The enlargement of the Stern layer distance caused by this ion exchange improves the dispersibility of (Mo3Se3−)∞ chains and also prevents the re-bundling and aggregation of nanowires in aqueous...

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Veröffentlicht in:	Chemical communications (Cambridge, England) England), 2018, Vol.54 (88), p.12503-12506
Hauptverfasser:	Chae, Sudong, Oh, Seungbae, Siddiqa, Akhtar J, Choi, Kyung Hwan, Lee, Weon-Gyu, Woo-Sung, Jang, Joo Song Lee, Young-Min, Kim, Huh, Joonsuk, Kim, Soo Min, Jae-Young, Choi
Format:	Artikel
Sprache:	eng
Schlagworte:	Absorption spectra Chains Chromatography Enlargement Ion exchange Lithium ions Mathematical analysis Nanowires
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creator	Chae, Sudong Oh, Seungbae Siddiqa, Akhtar J Choi, Kyung Hwan Lee, Weon-Gyu Woo-Sung, Jang Joo Song Lee Young-Min, Kim Huh, Joonsuk Kim, Soo Min Jae-Young, Choi
description	Ion-exchange chromatography can be used to effectively replace the lithium ion of LiMo3Se3 with a proton. The enlargement of the Stern layer distance caused by this ion exchange improves the dispersibility of (Mo3Se3−)∞ chains and also prevents the re-bundling and aggregation of nanowires in aqueous solutions, even at high concentrations (1 mg mL−1).
doi_str_mv	10.1039/c8cc06306k
format	Article
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subjects	Absorption spectra Chains Chromatography Enlargement Ion exchange Lithium ions Mathematical analysis Nanowires
title	Highly concentrated single-chain atomic crystal LiMo3Se3 solution using ion-exchange chromatography
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