Piezopotential-Driven Redox Reactions at the Surface of Piezoelectric Materials

Piezocatalysis uses piezopotential to modulate charge carrier energetics (see picture), thus allowing the direct enhancement or suppression of electrochemical reactions that occur at a piezoelectric material/solution interface. Such a direct conversion of mechanical to chemical energy is shown by th...

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Veröffentlicht in:	Angewandte Chemie International Edition 2012-06, Vol.51 (24), p.5962-5966
Hauptverfasser:	Starr, Matthew B., Shi, Jian, Wang, Xudong
Format:	Artikel
Sprache:	eng
Schlagworte:	Charge carriers Chemical energy Direct conversion electrochemistry Evolution Pictures piezocatalysis Piezoelectricity piezotronics Redox reactions water splitting
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creator	Starr, Matthew B. Shi, Jian Wang, Xudong
description	Piezocatalysis uses piezopotential to modulate charge carrier energetics (see picture), thus allowing the direct enhancement or suppression of electrochemical reactions that occur at a piezoelectric material/solution interface. Such a direct conversion of mechanical to chemical energy is shown by the electrochemical H2 evolution that is achieved by straining a piezoelectric material in aqueous medium.
doi_str_mv	10.1002/anie.201201424
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subjects	Charge carriers Chemical energy Direct conversion electrochemistry Evolution Pictures piezocatalysis Piezoelectricity piezotronics Redox reactions water splitting
title	Piezopotential-Driven Redox Reactions at the Surface of Piezoelectric Materials
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