Abundant FeS2 with high theoretical capacity is one of the promising anode candidates in sodium-ion batteries(SlBs),however,the uneven sodium deposition due to the poor interface compatibility and sluggish reaction ki...Abundant FeS2 with high theoretical capacity is one of the promising anode candidates in sodium-ion batteries(SlBs),however,the uneven sodium deposition due to the poor interface compatibility and sluggish reaction kinetics because of the high activation barrier still plague its practical application.Herein,we synthesized the ordered porous carbon matrix wrapped FeS2 nanoparticles(FeS_2@OCN)with high sodium wettability and low pore tortuosity to economically enhance the interface compatibility as well as to lower the energy barrier in SIBs.The synergistic effects of low tortuosity pores and strong sodium wettability homogenize the Na+flux distribution,bring the electron dislocation via the enrichment of edgenitrogen(Pyridinic N and Pyrrolic N),thus achieving the dendrite-free sodium deposition and dramatically enhanced reaction kinetics.Benefiting from exceptional structural/compositional/electronic merits,the resultant anode is endowed with exceptional structure stability,achieving long-term cycling stability of 451.9 mAh·g^(-1)after 1000cycles at 1 A·g^(-1)with specific capacity retention of 92.9%.Attenuated electrode tortuosity and high sodium wettability can corporately improve the interface compatibility and attenuate the activation barrier of the FeS_2 host and beyond.展开更多
基金financially supported by the National Natural Science Foundation of China (Nos.22175103 and 22178191)。
文摘Abundant FeS2 with high theoretical capacity is one of the promising anode candidates in sodium-ion batteries(SlBs),however,the uneven sodium deposition due to the poor interface compatibility and sluggish reaction kinetics because of the high activation barrier still plague its practical application.Herein,we synthesized the ordered porous carbon matrix wrapped FeS2 nanoparticles(FeS_2@OCN)with high sodium wettability and low pore tortuosity to economically enhance the interface compatibility as well as to lower the energy barrier in SIBs.The synergistic effects of low tortuosity pores and strong sodium wettability homogenize the Na+flux distribution,bring the electron dislocation via the enrichment of edgenitrogen(Pyridinic N and Pyrrolic N),thus achieving the dendrite-free sodium deposition and dramatically enhanced reaction kinetics.Benefiting from exceptional structural/compositional/electronic merits,the resultant anode is endowed with exceptional structure stability,achieving long-term cycling stability of 451.9 mAh·g^(-1)after 1000cycles at 1 A·g^(-1)with specific capacity retention of 92.9%.Attenuated electrode tortuosity and high sodium wettability can corporately improve the interface compatibility and attenuate the activation barrier of the FeS_2 host and beyond.
