Letter

Inherent mass transfer engineering of a Co, N co-doped carbon material towards oxygen reduction reaction

Hollow hierarchical porous nitrogen-doped carbon (HNC) derived from ZIF-8@ZIF-67 (ZIF: zeolitic-imidazolate framework) is a promising nanocomposite electrocatalyst rich in active sites. However, the single active species (Co-N_x) constrains its application. By introducing Fe in the precursor preparation, this work increased the active species of the catalyst to Co/Fe-N_x species and Co_0.72Fe_0.28 nanoparticles. Due to the advantages of abundant active sites and the synergy of multiple active species, Co,Fe-HNC-1 exhibited excellent oxygen reduction reaction (ORR) performance in 0.1 M KOH electrolyte with an onset potential (E_onset = 0.92 V vs. RHE) and a half-wave potential (E_1/2 = 0.85 V vs. RHE) comparable to those of commercial Pt/C, as well as better long-term stability and methanol resistance. Meanwhile, Co,Fe-HNC-1 additionally demonstrated oxygen evolution reaction (OER) activity. Co,Fe-HNC-1 also performed well as an air cathode in a zinc-air battery (ZAB) with a peak power density of 85.00 mW cm^-2 and outstanding stability with only 1.8 % loss after more than 200 galvanostatic cycles at 10 mA cm^-2. This work provides a new perspective for the rational design and preparation of electrocatalysts based on HNC nanocomposites.

The recharged zinc-air battery (ZAB) has drawn significant attention owing to increasing requirement for energy conversion and storage devices. Fabricating the efficient bifunctional oxygen catalyst using a convenient strategy is vitally important for the rechargeable ZAB. In this study, the bimetallic ZIFs-containing electrospun (ES) carbon nanofibers membrane with hierarchically porous structure was prepared by coaxial electrospinning and carbonization process, which was expected to be a bifunctional electrocatalyst for ZABs. Owing to the formed dual single-atomic sites of Co–N₄ and Zn–N₄, the obtained ES-Co/Zn-CN_ZIF exhibited the preferable performance toward oxygen reduction reaction (ORR) with E_1/2 of 0.857 V and J_L of 5.52 mA cm⁻², which were more than Pt/C. Meanwhile, it exhibited a marked oxygen evolution reaction (OER) property with overpotential of 462 mV due to the agglomerated metallic Co nanoparticles. Furthermore, the ZAB based on the ES-Co/Zn-CN_ZIF carbon nanofibers membranes delivered peak power density of 215 mW cm⁻², specific capacity of 802.6 mA h g⁻¹, and exceptional cycling stability, far larger than Pt/C+RuO₂-based ZABs. A solid-state ZAB based on ES-Co/Zn-CN_ZIF showed better flexibility and stability with different bending angles.

Large-scale magnetic Co nanoparticles/N-doped carbon nanotubes (Co@NCNTs) hybrids have been designed by pyrolyzing the mixture of cobalt nitrate and melamine for microwave (MW)-induced tetracycline (TC) degradation. The results demonstrated that Co@NCNTs-5, annealed from cobalt nitrate and melamine (mole ratio: 1:5), possessed a good MW absorption ability, resulting in excellent degradation performance towards TC. Specifically, 99.5 % TC (20 mg/L, natural pH) could be removed after 6 min of MW irradiation (520 W) in the presence of Co@NCNTs-5. Meanwhile, Co@NCNTs-5 exhibited competitive degradation efficiency over TC at various concentrations (20–100 mg/L) and pH values (3−8). Results of reusability experiments identified the magnetic recovery ability and stability of Co@NCNTs-5. Based on free radical experiments and electron paramagnetic resonance (EPR) results, HO• and ${\text{O}}_2^{-}$• radicals participated in the catalytic degradation process. The degradation pathway of TC was proposed with the assistance of ultrahigh-performance liquid chromatography-mass spectrometry (UPLC-MS). This work develops a facile, low-cost and large-scale method to synthesize Co@NCNTs, which demonstrates great potential in MW-induced catalytic treatment of antibiotic pollutants as high-efficient catalysts.

The development and utilization of renewable clean energy can effectively solve the two major problems of energy and environment. As an efficient power generation device that converts hydrogen energy into electric energy, fuel cell has attracted more and more attention. For fuel cells, the oxygen reduction reaction (ORR) at the cathode is the core reaction, and the design and development of high-performance ORR catalysts remain quite challenging. Since the microenvironment of the active center of single atom catalysts (SACs) has an important influence on its catalytic performance, it has been a research focus to improve the ORR activity and stability of electrocatalysts by adjusting the structure of the active center through reasonable structural regulation methods. In this review, we reviewed the preparation and structure–activity relationship of SACs for ORR. Then, the structural precision regulation methods for improving the activity and stability of ORR electrocatalysts are discussed. And the advanced in-situ characterization techniques for revealing the changes of active sites in the electrocatalytic ORR process are summarized. Finally, the challenges and future design directions of SACs for ORR are discussed. This work will provide important reference value for the design and synthesis of SACs with high activity and stability for ORR.

The carbon-based electrocatalyst for rechargeable zinc-air battery not only needs bifunctional activities to oxygen reduction and evolution reactions, but also requires a high graphitization degree to maintain an excellent stability. Herein, a simple and scale-up strategy is developed to synthesize a highly active and stable electrocatalyst (Co@N-CNT) through a solid-state thermal conversion process, derived from a single and easy-to-get precursor (cobaltic Prussian blue analogue). The Co particles trapped inside the tips are the growth sites of the carbon nanotubes and greatly improve the catalytic activity. This kind of special structure helps Co@N-CNT to achieve remarkable bifunctional activities comparable to the noble metal counterparts and superior durability. Interestingly, Co@N-CNT is proved to have no single-atom Co sites on the carbon nanotube. In combination with electrochemical tests, X-ray absorption spectroscopy and theoretical calculations, Co@graphitic N-C is considered to be the best ORR active site while Co@pyridinic N-C is the best OER active site.