Fe3C/CoFe2O4 nanoparticles wrapped in one-dimensional MIL-53 (Fe)-derived carbon nanofibers as efficient dual-function oxygen catalysts

Structure engineering for non-precious-metal catalyst plays the major roles in governing the activity and stability for oxygen evolution/reduction reactions (OER/ORR). Herein, via an electrospinning method, one-dimensional (1D) carbon fibers containing MIL-53 (Fe) and Co3+ are obtained as precursor for preparation of Fe3C/CoFe2O4- embedded carbon nanofibers (Fe3C/CoFe2O4@CNFs). Scanning electron microscopy image of Fe3C/ CoFe2O4@CNFs-1.5 (mass ratio of MIL-53(Fe) to CoCl3 center dot 6H(2)O is 1.5) shows that it has a well-formed 1D structure with diameters of 200-300 nm. Hydrophilic surface with a contact angle of 16.5 degrees is detected for Fe3C/ CoFe2O4@CNFs-1.5 (250.1 m(2) g(-1)), which shows a promising bifunctional activity with Delta E = 0.73 V (E-1/2 = 0.84 V (ORR) and E-j10 = 1.57 V (OER)). For ORR, E1/2 of Fe3C/CoFe2O4@CNFs-1.5 is close to that of commercial Pt/C (0.85 V), while its activity maintenance (92.5%) is much better than Pt/C (78.4%) after 30000 s, indicating that low-valence interfaces of CoFe2O4 (Co2+) and Fe3C (Fe2+) can provide multiple active sites to stabilize ORR rate. For OER, Fe3C/CoFe2O4@CNFs-1.5 has a low overpotential of 340 mV at 10 mA cm(-2) and a high Faraday efficiency of 92.13%. Co2+ acts as an initiator to boost the formation of active CoOOH for OER. Oxygen vacancies on the reverse spinel structure of CoFe2O4 make the surface Co2+ easier to be oxidized to Co3+ (CoOOH). Fe3C/CoFe2O4 wrapped in carbon fiber lowers their aggregation and corrosion during ORR/OER. Networks constructed by the interconnected 1D nanofibers can provide 3D pathways for mass transfer. It indicates that bimetallic species (Fe/Co) can change the electronic and interface structures to promote bifunctional activity.

Automated summary

Electrospun one-dimensional carbon nanofibers containing Fe3C and CoFe2O4 showed promising bifunctional activity in oxygen evolution/reduction reactions, with well-formed structure and stability, providing multiple active sites for reaction stabilization and efficient mass transfer pathways through interconnected nanofibers. CoFe2O4 and Fe3C interfaces play a crucial role in promoting catalytic activity, with Co2+ acting as an initiator for boosting active CoOOH formation for OER.