Ion-Driven Self-Assembly of Lanthanide Bis-phthalocyaninates into Conductive Quasi-MOF Nanowires: an Approach toward Easily Recyclable Organic Electronics

Controlled self-assembly and rapid disintegration of supramolecular nanowires is potentially useful for ecology-friendly organic electronics. Herein, a novel method exploiting the binding between crown-substituted double-decker lanthanide phthalocyaninates (ML2, M = Lu, Ce, Tb) and K+ ions is applie...

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Veröffentlicht in:	Inorganic chemistry 2021-10, Vol.60 (20), p.15509-15518
Hauptverfasser:	Zvyagina, Alexandra I, Aleksandrov, Alexey E, Martynov, Alexander G, Tameev, Alexey R, Baranchikov, Alexander E, Ezhov, Alexander A, Gorbunova, Yulia G, Kalinina, Maria A
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container_title	Inorganic chemistry
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creator	Zvyagina, Alexandra I Aleksandrov, Alexey E Martynov, Alexander G Tameev, Alexey R Baranchikov, Alexander E Ezhov, Alexander A Gorbunova, Yulia G Kalinina, Maria A
description	Controlled self-assembly and rapid disintegration of supramolecular nanowires is potentially useful for ecology-friendly organic electronics. Herein, a novel method exploiting the binding between crown-substituted double-decker lanthanide phthalocyaninates (ML2, M = Lu, Ce, Tb) and K+ ions is applied for the one-step fabrication of macroscopically long conductive one-dimensional quasi-metal–organic frameworks. Their properties are controlled by the size of the lanthanide ion guiding the assembly through either intra- or intermolecular interactions. A LuL2 linker with a small interdeck distance yields fully conjugated intermolecular-bonded K+–LuL2 nanowires with a thickness of 10–50 nm, a length of up to 50 μm, and a conductivity of up to 11.4 S cm–1, the highest among them being reported for phthalocyanine assemblies. The large size of CeL2 and TbL2 leads to the formation of mixed intra- and intermolecular K+–ML2 phases with poor electric properties. A field-assisted method is developed to deposit aligned conductive K+–LuL2 assemblies on solids. The solid-supported nanowires can be disintegrated into starting components in a good aprotic solvent for further recycling.
doi_str_mv	10.1021/acs.inorgchem.1c02147
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subjects	Chemistry Chemistry, Inorganic & Nuclear Physical Sciences Science & Technology
title	Ion-Driven Self-Assembly of Lanthanide Bis-phthalocyaninates into Conductive Quasi-MOF Nanowires: an Approach toward Easily Recyclable Organic Electronics
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