Abstract
We developed an upcycling process of polyurethane obtaining porous nitrogen-doped carbon materials that were applied in supercapacitor electrodes. In detail, a mechanochemical solvent-free one-pot synthesis is used and combined with a thermal treatment. Polyurethane is an ideal precursor already containing nitrogen in its backbone, yielding nitrogen-doped porous carbon materials with N content values of 1–8 wt %, high specific surface area values of up to 2150 m2·g−1 (at a N content of 1.6 wt %) and large pore volume values of up to 0.9 cm3·g−1. The materials were tested as electrodes for supercapacitors in aqueous 1 M Li2SO4 electrolyte (100 F·g−1), organic 1 M TEA-BF4 (ACN, 83 F·g−1) and EMIM-BF4 (70 F·g−1).
Highlights
More than 275 million tons of plastics end up as waste every year, 12.7 million tons of which accumulate in the oceans [1,2]
We developed an upcycling process of polyurethane obtaining porous nitrogen-doped carbon materials that were applied in supercapacitor electrodes
One approach is the synthesis of porous carbon materials from PU waste
Summary
More than 275 million tons of plastics end up as waste every year, 12.7 million tons of which accumulate in the oceans [1,2]. The main properties of porous carbon materials [22,23] such as high specific surface area and high electrical conductivity allow for a variety of applications in catalysis [24,25,26], gas sorption/ separation [27,28,29] and electrochemical energy storage/conversion. For the latter, porous carbon materials are established as electrode materials in fuel cells [30,31,32,33], Li–S cells [34,35,36,37], and supercapacitors [38]. The N-doped carbon materials have been investigated as electrode material for supercapacitors in aqueous Li2SO4, organic TEA-BF4 in acetonitrile, and an ionic liquid EMIM-BF4 electrolyte
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