Atomically dispersed metal-nitrogen-carbon (M− N− C) oxygen reduction reaction (ORR)
catalysts have been proven as one of the most promising non-precious metal catalysts. In …

The large‐scale commercialization of proton‐exchange‐membrane fuel cells (PEMFCs) is
extremely limited by their costly platinum‐group metals (PGMs) catalysts, which are used for …

Single atom metal–nitrogen–carbon materials have shown immense potential for the oxygen
reduction reaction (ORR) while the development of durable catalysts with high reactivity …

The controllable construction of Fe, N co-doped carbon (Fe-NC) nanocomposite has highly
potential in replacing the noble metal catalysts. Herein, the Fe/N/P-tridoped expanded …

Challenges in developing fuel cells provide strong stimulation to develop efficient
electrocatalysts for the sluggish cathodic oxygen reduction reaction (ORR). Among various …

Fe–N–C materials exhibit excellent activity and stability for oxygen reduction reaction (ORR),
as one of the most promising candidates to replace commercial Pt/C catalysts. However, it is …

Manganese-incorporated Co 3 O 4 catalysts were prepared via thermal pyrolysis of ZIF-67,
and the effect of manganese incorporation and annealing temperature on their catalytic …

Atomically dispersed iron-nitrogen-carbon catalysts offer great potential in oxygen reduction
reaction (ORR), yet the poor exposure and low density of Fe-N x sites causes relatively low …

The reasonable design of porous structures is important but usually overlooked for
nonprecious metal ORR catalysts. In this study, a facile dual melt-salt-mediated templating …

Developing advanced non-precious metal catalysts towards acidic oxygen reduction
reaction (ORR) is critical for electrochemical energy conversion devices. Fe-NC catalysts are …