Compacts of Boron-Doped Synthetic Diamond: Acceleration of Cathodic Reactions by Plasma-Assisted and Electrochemical Treatment of the Electrodes

Diamond compacts were synthesized by thermobaric processing of graphite and amorphous boron mixtures under the conditions of the diamond thermodynamic stability (at a pressure of 8–9 GPa and temperature of ∼2500 K). The boron-doped diamond-compact electrode surface was modified by its subjecting to...

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Published inRussian journal of electrochemistry Vol. 58; no. 6; pp. 520 - 527
Main Authors Krivenko, A. G., Manzhos, R. A., Kochergin, V. K., Kotkin, A. S., Pleskov, Yu. V., Krotova, M. D., Ekimov, E. A.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.06.2022
Springer Nature B.V
Subjects
Acceleration
Ammonia
Anodic polarization
Aqueous solutions
Boron
Cathodic polarization
Chemical reactions
Chemical reduction
Chemistry
Chemistry and Materials Science
Compacts
Diamonds
Electrochemistry
Electrode polarization
Electrodes
Electron transfer
Electrons
Oxygen reduction reactions
Physical Chemistry
Plasma
Quinones
Rotating disks
Rotating plasmas
Voltage pulses
Fe(CN)
diamond
electrolytic plasma
compact
Ru(NH
)
rotating disc electrode
oxygen reduction reaction
]
redox-reaction
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Summary:Diamond compacts were synthesized by thermobaric processing of graphite and amorphous boron mixtures under the conditions of the diamond thermodynamic stability (at a pressure of 8–9 GPa and temperature of ∼2500 K). The boron-doped diamond-compact electrode surface was modified by its subjecting to the action of cathodic, anodic, and cathodic–anodic electrolytic plasma formed under the applying of voltage pulses with amplitude up to 300 V in Na 2 SO 4 aqueous solution. It was found by using rotating disc electrode that the applying of sole cathodic–anodic plasma provides negligible catalytic effect with respect to the oxygen reduction reaction. However, thus pre-processed electrode acquired significant electrocatalytical activity upon the cathodic treatment, with the consequence that the reaction of O 2 reduction to H 2 O passed predominantly by the four-electron mechanism. At the same time, the cathodic polarization of the plasma-modified electrode produced no effect on the rate constant of the electron transfer in the [Ru(NH 3 ) 6 ] 2+/3+ redox couple; yet, the rate constant in the [Fe(CN) 6 ] 4–/3– one increased significantly. Hypothetically, the observed electrocatalytical effect in the oxygen reduction reaction is due to the formation, under the combined action of the cathodic–anodic plasma and cathodic polarization, of quinone groups at the boron-doped diamond surface; they play the role of active sites for the oxygen four-electron reduction.
ISSN:1023-1935
1608-3342
DOI:10.1134/S1023193522050068