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<rdf:RDF xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#" xmlns:dc="http://purl.org/dc/elements/1.1/"><rdf:Description rdf:about="https://repozitorij.uni-lj.si/IzpisGradiva.php?id=181479"><dc:title>A parallel-plate electrochemical microreactor for the continuous production of hydrogen peroxide</dc:title><dc:creator>Yordanova Apostolov,	Desislava	(Avtor)
	</dc:creator><dc:creator>Bardarov,	Ivo	(Avtor)
	</dc:creator><dc:creator>Tjell,	Anders Ø.	(Avtor)
	</dc:creator><dc:creator>Gričar,	Ema	(Avtor)
	</dc:creator><dc:creator>Starin,	Mark	(Avtor)
	</dc:creator><dc:creator>Farinazzo Bergamo Dias Martins,	Pedro	(Avtor)
	</dc:creator><dc:creator>Nosan,	Miha	(Avtor)
	</dc:creator><dc:creator>Mayr,	Torsten	(Avtor)
	</dc:creator><dc:creator>Strmčnik,	Dušan	(Avtor)
	</dc:creator><dc:creator>Plazl,	Igor	(Avtor)
	</dc:creator><dc:creator>Genorio,	Boštjan	(Avtor)
	</dc:creator><dc:subject>electrosynthesis</dc:subject><dc:subject>hydrogen peroxide</dc:subject><dc:subject>two-electron oxygen reduction reaction carbon electrocatalysts</dc:subject><dc:subject>electrochemical microreactor</dc:subject><dc:subject>continuous flow microreactor</dc:subject><dc:description>This study presents a comprehensive evaluation of a microfluidic electrochemical system for the controlled generation and detection of hydrogen peroxide (H$_2$O$_2$). The integrated microreactor with a three-electrode configuration in combination with optical sensors enabled real-time monitoring of dissolved oxygen and H$_2$O$_2$ concentrations during chronoamperometric operation. Glassy carbon (GC) electrodes exhibited high selectivity toward  the  two-electron  oxygen  reduction  reaction  (2e-  ORR),  a  key  requirement  for  efficient  H$_2$O$_2$ electro- synthesis. Cyclic voltammetry (CV), rotating ring-disk electrode (RRDE) analyses and electrochemical testing in real system identified 0.4 V vs. RHE as the optimal working potential. Flow rate experiments revealed a decline in H$_2$O$_2$ production with increasing flow rates, consistent with electrical charge measurements and oxygen consumption data. A mathematical model, validated with experimental data, reliably predicted H$_2$O$_2$ outlet concentration as a function of flow rate (residence time). The model captured the interplay between mass transport and surface electrocatalytic reactions and enabled the identification of an optimal operating  window (25–50  μL  min-1),  supporting  model-based  reaction  optimization.  Post-experiment  surface  characterization using SEM-EDS, XPS, and μ-FTIR revealed increased oxygen-containing functional groups on the GC working electrode, indicating surface oxidation that may enhance catalytic performance. Overall, this system offers a scalable, sustainable platform for on-demand H$_2$O$_2$ production, supporting cleaner, decentralized electro- chemical synthesis with reduced environmental impact and greater adaptability for modern industrial applications.
</dc:description><dc:date>2026</dc:date><dc:date>2026-04-08 23:04:30</dc:date><dc:type>Neznano</dc:type><dc:identifier>181479</dc:identifier><dc:language>sl</dc:language></rdf:Description></rdf:RDF>