Abstract
In view of the low cost and comparable properties with lithium ion batteries (LIBs), sodium ion batteries (SIBs) are considered to be the most hopeful candidate or supplement for LIBs. To date, conversion-type transition metal phosphides (TMPs) are pursued as vital anode materials in SIBs since their high theoretical capacity and low redox potential compared to their oxides and sulfides, yet still suffer from unfavorable electrical conductivity and poor reaction kinetices. In this regard, for the first time, we put forward a self supported Fe 2 P hierarchical microsphere arrays with Se doping to optimize the performance of transition metal phosphides. As expected, the Se doped Fe 2 P (Fe 2 P 0.8 Se 0.2 ) arrays obviously show superior performnace than bare Fe 2 P, delivering a high reversible capacity of 312.5 mAh g −1 at 2000 mA g −1 , and sustaining a capacity of 395.1 mAh g −1 at 1000 mA g −1 experiencing 1000 cycles. Combined with the experiment and in-depth DFT calculation results, it can be concluded that the Se doping protocol could largely modulate the charge density distribution and enhance Na adsorption ability thereafter minimize Na + diffusion energy barrier, enabling elevated electrochemical performance. • A self supported Fe 2 P hierarchical microsphere arrays with Se doping is designed. • The Se doped Fe 2 P arrays shows superior performnace than bare Fe 2 P. • Se doping into Fe 2 P could largely modulate the charge density distribution. • Se doping into Fe 2 P protocol could minimize Na + diffusion energy barrier.
Published Version
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