posted on 2020-09-15, 15:45authored byQian Liu, Shao-Jian Zhang, Cheng-Cheng Xiang, Chen-Xu Luo, Peng-Fang Zhang, Chen-Guang Shi, Yao Zhou, Jun-Tao Li, Ling Huang, Shi-Gang Sun
Cubic
N,S codoped carbon coating MnS–FeS2 composites
(MnS–FeS2@NSC) with a hollow structure were prepared
and used as anode materials for sodium-ion batteries. MnS–FeS2@NSC exhibits excellent cycle performance and high rate capability
and delivered a reversible capacity of 501.0 mAh g–1 after 800 cycles at a current density of 0.1 A g–1 with a capacity retention of 81%. More importantly, the MnS–FeS2@NSC anode holds long-term cycle stability; the capacity can
remain 134.0 mAh g–1 after 14 500 cycles
at 4 A g–1. Kinetic analysis demonstrated that Na+ storage follows a pseudocapacitive dominating process, which
is ascribed to the origin of the outstanding rate performance of the
MnS–FeS2@NSC material. The enhancement of electrochemical
performance is attributed to the hollow structure and the N,S codoped
carbon coating structure, which can reduce the diffusion distance
for sodium ions and electrons, alleviate volume expansion during sodium-ion
insertion/extraction, and retain the structural integrity effectively.
Furthermore, a two-step sodiation processes with FeS2 sodiation
prior to MnS was demonstrated by X-ray diffraction (XRD), and the
electrochemical impedance spectroscopy (EIS) spectra might indicate
that the accumulation of the metallic elements in the preconversion
reaction can accelerate the transfer of electrons and ions in the
further conversion process.