posted on 2020-07-23, 17:04authored byZhiming Zheng, Hong-Hui Wu, Haodong Liu, Qiaobao Zhang, Xin He, Sicen Yu, Victoria Petrova, Jun Feng, Robert Kostecki, Ping Liu, Dong-Liang Peng, Meilin Liu, Ming-Sheng Wang
Conversion-type
transition-metal phosphide anode materials with
high theoretical capacity usually suffer from low-rate capability
and severe capacity decay, which are mainly caused by their inferior
electronic conductivities and large volumetric variations together
with the poor reversibility of discharge product (Li3P),
impeding their practical applications. Herein, guided by density functional
theory calculations, these obstacles are simultaneously mitigated
by confining amorphous FeP nanoparticles into ultrathin 3D interconnected
P-doped porous carbon nanosheets (denoted as FeP@CNs) via a facile approach, forming an intriguing 3D flake-CNs-like configuration.
As an anode for lithium-ion batteries (LIBs), the resulting FeP@CNs
electrode not only reaches a high reversible capacity (837 mA h g–1 after 300 cycles at 0.2 A g–1)
and an exceptional rate capability (403 mA h g–1 at 16 A g–1) but also exhibits extraordinary durability
(2500 cycles, 563 mA h g–1 at 4 A g–1, 98% capacity retention). By combining DFT calculations, in situ transmission electron microscopy, and a suite of ex situ microscopic and spectroscopic techniques, we show
that the superior performances of FeP@CNs anode originate from its
prominent structural and compositional merits, which render fast electron/ion-transport
kinetics and abundant active sites (amorphous FeP nanoparticles and
structural defects in P-doped CNs) for charge storage, promote the
reversibility of conversion reactions, and buffer the volume variations
while preventing pulverization/aggregation of FeP during cycling,
thus enabling a high rate and highly durable lithium storage. Furthermore,
a full cell composed of the prelithiated FeP@CNs anode and commercial
LiFePO4 cathode exhibits impressive rate performance while
maintaining superior cycling stability. This work fundamentally and
experimentally presents a facile and effective structural engineering
strategy for markedly improving the performance of conversion-type
anodes for advanced LIBs.