Unraveling the Environmental Applications of Nanoporous Ultrananocrystalline Diamond Films DOI Open Access
Laís Gimenes Vernasqui, Inalmar D. Barbosa Segundo, Carlos A. Martínez‐Huitle

et al.

Catalysts, Journal Year: 2024, Volume and Issue: 14(12), P. 872 - 872

Published: Nov. 29, 2024

In this work, a nanoporous ultrananocrystalline diamond film (B-UNCDWS/TDNT/Ti) was obtained and compared with commercial electrode in the degradation of methomyl, recalcitrant pesticide. The morphological structural differences between materials were highlighted by SEM XRD analysis: while presented regular planar surface microcrystalline grains, supported features, B-UNCDWS/TDNT/Ti porous morphology DRX features indicating high renucleation rate. Those affected electrooxidation methomyl; responsible for faster more economic pollutant, achieving methomyl 78% (against 35% electrode). highly UNCDWS/TDNT/Ti provides an electrochemical area threefold greater than one found electrode, justifying better efficiency formation persulfate, which can be singled out as main mechanism degradation.

Language: Английский

Unraveling the Environmental Applications of Nanoporous Ultrananocrystalline Diamond Films DOI Open Access
Laís Gimenes Vernasqui, Inalmar D. Barbosa Segundo, Carlos A. Martínez‐Huitle

et al.

Catalysts, Journal Year: 2024, Volume and Issue: 14(12), P. 872 - 872

Published: Nov. 29, 2024

In this work, a nanoporous ultrananocrystalline diamond film (B-UNCDWS/TDNT/Ti) was obtained and compared with commercial electrode in the degradation of methomyl, recalcitrant pesticide. The morphological structural differences between materials were highlighted by SEM XRD analysis: while presented regular planar surface microcrystalline grains, supported features, B-UNCDWS/TDNT/Ti porous morphology DRX features indicating high renucleation rate. Those affected electrooxidation methomyl; responsible for faster more economic pollutant, achieving methomyl 78% (against 35% electrode). highly UNCDWS/TDNT/Ti provides an electrochemical area threefold greater than one found electrode, justifying better efficiency formation persulfate, which can be singled out as main mechanism degradation.

Language: Английский

Citations

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