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The carbonization of aromatic molecules with three-dimensional structures affords carbon materials with controlled pore sizes at the Ångstrom-level

Tomoki Ogoshi, Yuma Sakatsume, Katsuto Onishi, Rui Tang, Kazuma Takahashi, Hirotomo Nishihara, Yuta Nishina, Benoît Denis Louis Campéon, Takahiro Kakuta, Tada-aki Yamagishi

2021Communications Chemistry35 citationsDOIOpen Access PDF

Abstract

Carbon materials with controlled pore sizes at the nanometer level have been obtained by template methods, chemical vapor desorption, and extraction of metals from carbides. However, to produce porous carbons with controlled pore sizes at the Ångstrom-level, syntheses that are simple, versatile, and reproducible are desired. Here, we report a synthetic method to prepare porous carbon materials with pore sizes that can be precisely controlled at the Ångstrom-level. Heating first induces thermal polymerization of selected three-dimensional aromatic molecules as the carbon sources, further heating results in extremely high carbonization yields (>86%). The porous carbon obtained from a tetrabiphenylmethane structure has a larger pore size (4.40 Å) than those from a spirobifluorene (4.07 Å) or a tetraphenylmethane precursor (4.05 Å). The porous carbon obtained from tetraphenylmethane is applied as an anode material for sodium-ion battery.

Topics & Concepts

CarbonizationMaterials scienceCarbon fibersChemical engineeringPorosityPolymerizationAnodePyrolysisMoleculeTemplate method patternDesorptionExtraction (chemistry)NanotechnologyAdsorptionOrganic chemistryComposite materialChemistryPolymerElectrodeComposite numberPhysical chemistryEngineeringScanning electron microscopeSupercapacitor Materials and FabricationCovalent Organic Framework ApplicationsAdvancements in Battery Materials
The carbonization of aromatic molecules with three-dimensional structures affords carbon materials with controlled pore sizes at the Ångstrom-level | Litcius