Boron-Doped Activated Carbon Supports for Cobalt-Catalyzed Oxygen Evolution in Alkaline Electrolyte.
Jae-Hyung WeeSeoyoon ShinDoo-Won KimChangho LeeYoong Ahm KimMoo Whan ShinKi Ro YoonSang Young YeoPublished in: ACS applied materials & interfaces (2023)
Activated carbons (ACs) are the most widely used and attractive support materials for electrocatalytic applications because of their significant surface areas, high electrical conductivities, and moderate affinities toward supported metal catalysts. However, the corrosive behavior of ACs at oxidative potentials causes an inevitable reduction in the active surface area of supported catalysts, resulting in the continuous deterioration of their electrocatalytic performance. Therefore, the introduction of corrosion-resistant durable catalyst supports is essential for sustainable and efficient electrocatalysis. Here, we modified ACs to obtain different boron (B)-doped structures via doping-temperature controls to investigate the corrosion resistance of B-doped ACs. With increasing doping temperature, the B-doped ACs exhibited a decreased defect density and enhanced crystallinity owing to the accelerating dopant-induced graphitization. We found that the substitution of B atoms into the carbon lattice improved the structural integrity of the carbon structure, and cyclic voltammetry (CV) tests suggested that the highly B-substituted structures caused electrochemical surface passivation against carbon corrosion. Moreover, B-doped ACs significantly contributed to the increase in loading mass of cobalt (Co)-based catalyst on them and the electrochemical durability toward the oxygen evolution reaction as catalyst-support hybrid. The B22 (B-doped AC obtained at a 2200 °C B-doping temperature)-supported Co catalyst with the lowest oxidation current exhibited a voltage change of 32 mV at a current density of 10 mA/cm 2 (Δ E j =10 ) after 10,000 cycles, which was a factor of ∼7 higher cycle durability and stability than that of the conventional IrO 2 catalyst (Δ E j =10 = 205 mV). Here, we propose that surface engineering by B-doping to improve the structural integrity of ACs is an attractive method for designing durable electrocatalytic support materials.
Keyphrases
- metal organic framework
- acute coronary syndrome
- highly efficient
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- reduced graphene oxide
- ionic liquid
- gold nanoparticles
- quantum dots
- transition metal
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- room temperature
- oxidative stress
- high glucose
- mass spectrometry
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- hydrogen peroxide
- electron transfer
- carbon nanotubes
- endothelial cells