Abstract
A series of triple hierarchical micro-meso-macroporous N-doped carbon shells with hollow cores have been successfully prepared via etching N-doped hollow carbon spheres with CO2 at high temperatures. The surface areas, total pore volumes and micropore percentages of the CO2-activated samples evidently increase with increasing activation temperature from 800 to 950 °C, while the N contents show a contrary trend from 7.6 to 3.8 at%. The pyridinic and graphitic nitrogen groups are dominant among various N-containing groups in the samples. The 950 °C-activated sample (CANHCS-950) has the largest surface area (2072 m2 g−1), pore volume (1.96 cm3 g−1), hierarchical micro-mesopore distributions (1.2, 2.6 and 6.2 nm), hollow macropore cores (~91 nm) and highest relative content of pyridinic and graphitic N groups. This triple micro-meso-macropore system could synergistically enhance the activity because macropores could store up the reactant, mesopores could reduce the transport resistance of the reactants to the active sites, and micropores could be in favor of the accumulation of ions. Therefore, the CANHCS-950 with optimized structure shows the optimal and comparable oxygen reduction reaction (ORR) activity but superior methanol tolerance and long-term durability to commercial Pt/C with a 4e−-dominant transfer pathway in alkaline media. These excellent properties in combination with good stability and recyclability make CANHCSs among the most promising metal-free ORR electrocatalysts reported so far in practical applications.
Highlights
Fuel cells, which serve as a highly efficient, environmentfriendly energy transformation system, have received intensive research and focus in transports, aerospace and communication equipment during these years [1,2,3]
We successfully developed a kind of novel porous N-doped carbons shells with large hollow cores and triple micro-meso-macroporosity (1.1, 2.6, 6.2, *91 nm) by etching N-doped hollow carbon spheres (NHCSs) with CO2 at high temperatures
Where W1 is the weight of CO2-activated NHCSs (CANHCSs) and W2 is the weight of parent NHCSs
Summary
Fuel cells, which serve as a highly efficient, environmentfriendly energy transformation system, have received intensive research and focus in transports, aerospace and communication equipment during these years [1,2,3]. Due to its unique structures of triple hierarchical micro-meso-macroporosity, large surface area and highcontent doping of pyridinic and graphitic N groups, CANHCS-950 demonstrates the best ORR activity among these samples, which is comparable to commercial Pt/C. The as-formed micropores could be in favor of the accumulation of ions (1.1 nm) [65] It could catalyze the ORR via a close four-electron reaction process with very low yield of peroxides as the side product, obtaining the maximum energy transformation efficacy. It shows the superior long-term stability and methanol tolerance to commercial Pt/C for ORR, indicating that CANHCS-950 is a good candidate for replacing Pt/C used in fuel cells
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