Electrode reaction-driven orientation regrowth of Fe2O3 crystals from novel dendritic architecture in anode of lithium-ion batteries

Morphology design is one effective strategy for improving the rate capability and cycling stability of Fe2O3 anode material for lithium-ion batteries. Herein, a kind of dendritic Fe2O3 architecture was prepared through a hydrothermal route in which glycine molecules guide crystal growth and turn into carbon in the final composite. The special coralloid Fe2O3/NC composite integrates the structure advantages of porous and low-dimensional regular electrode materials. The mutually supportive architecture provides more space to exchange ions with electrolyte and accommodate mechanical stress to suppress volume change, and im-proves better electron conductivity compared to isolated particles. The Fe2O3/NC delivers 837.6 mAh g(-1) at 10 A g(-1) and maintains 788 mAh g(-1) after a long-term life of 1000 cycles. One more discovery is that the dendritic Fe2O3 architecture grows into needle-like crystals driven by electrode reaction revolved to ion migration and crystal regeneration. (C) 2022 Elsevier B.V. All rights reserved.

Automated summary

Morphology design is an effective strategy for improving the performance of Fe2O3 anode material for lithium-ion batteries. A dendritic Fe2O3 architecture was prepared using a hydrothermal route, with glycine guiding crystal growth and becoming carbon in the final composite. The coralloid Fe2O3/NC composite integrates the advantages of porous and low-dimensional electrode materials, providing more space for ion exchange, better mechanical stability, and improved electron conductivity.