Phosphorus and nitrogen-containing carbons obtained by the carbonization of conducting polyaniline complex with phosphites

Phosphorus and nitrogen-containing carbons obtained by the carbonization of conducting polyaniline complex with phosphites

Non-conducting polyaniline base interacts with organic phosphites to a conducting product resembling classical polyaniline salts. Polyaniline–phosphite complexes were carbonized in inert atmosphere at 650°C to phosphorus- and nitrogen-containing carbons. The resulting materials were tested with resp...

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Bibliographic Details
Published in:Electrochimica acta Vol. 246; pp. 443 - 450
Main Authors: Bober, Patrycja, Trchová, Miroslava, Morávková, Zuzana, Kovářová, Jana, Vulić, Iva, Gavrilov, Nemanja, Pašti, Igor A., Stejskal, Jaroslav
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 20-08-2017
Elsevier BV
Subjects:
Carbonization
Catalysts
Conducting polymer
Conductivity
Electrochemical analysis
Functional groups
Inorganic salts
Nitrogen
Nitrogen-containing carbon
Phosphite
Phosphorus
Phosphorus-containing carbon
Polyaniline
Polyanilines
Potassium hydroxides
Specific surface
Carbonization
Nitrogen-containing carbon
Phosphorus-containing carbon
Conducting polymer
Polyaniline
Phosphite
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Summary:Non-conducting polyaniline base interacts with organic phosphites to a conducting product resembling classical polyaniline salts. Polyaniline–phosphite complexes were carbonized in inert atmosphere at 650°C to phosphorus- and nitrogen-containing carbons. The resulting materials were tested with respect to their electrochemical performance by considering their capacitive properties and electrocatalytic activity towards oxygen reduction reaction (ORR). Carbonized polyaniline–diphenyl phosphite displayed the highest capacitance among all investigated carbons, reaching the values above 100Fg−1 at 5mVs−1 in concentrated potassium hydroxide solution, while the same material also displayed the highest ORR activity in alkaline media. Considering small specific surface area of obtained carbon materials, the synthetic procedures lead to the surface structures which are exceptionally active for charge storage and in electrocatalysis of ORR. It is proposed that further improvement of electrochemical properties can be obtained by preserving the type of the present surface functional groups with simultaneous increase of their number by the increase of the specific surface.
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2017.06.036