Phase change-induced heterointerface engineering of hollow sphere structured graphene oxide/layered double hydroxide composites for superior pseudocapacitive energy storage in lithium-ion batteries
Minseop Lee, Jing Xie, Jae‐Min Oh, Seung‐Min Paek
Abstract
This study investigates how controlling nanostructures and phase changes within GO/NiFe-LDH two-dimensional heterostructures can enhance electrochemical performance. The phase change of NiFe-LDH leads to the formation of a-NiO/NiFe 2 O 4 nanoparticles, characterized by rich grain boundaries and effectively embedded within a graphene matrix. • The rGO/a-NiO/NiFe 2 O 4 -HS anode is developed with a hollow nanostructure derived from the GO/NiFe-LDH composite. • The phase change of NiFe-LDH leads to the formation of a-NiO/NiFe 2 O 4 nanoparticles embedded in a graphene matrix. • This hollow nanostructure prevents volume expansion and nanoparticle aggregation, ensuring long-term cycling stability. Integrating transition metal oxides with carbon-based materials through chemical heterointerface engineering presents a promising approach for achieving enhanced ionic/electrical conductivity, additional interfacial storage space, and structural stability, facilitating superior cyclic performance in energy storage systems. In this study, we synthesized a hierarchical heterostructure composite by combining graphene oxide with nickel–iron layered double hydroxides and promoted the formation of additional grain boundaries through phase change. Thus, we enhanced the pseudocapacitive contributions and the ion/charge transfer kinetics through nano-interfaces. These hybrid structures were formed through the layer-by-layer self-assembly of two-dimensional nanosheets. This design facilitates the construction of low-dimensional nanoarchitecture suitable for long-term cycling without ionic intermediates. Furthermore, to prevent agglomeration during the annealing process, we induced a phase change in NiCo-LDH under an inert atmosphere to fabricate reduced graphene oxide (rGO) embedded with amorphous nickel oxide (a-NiO) and NiFe 2 O 4 nanoparticles, designated as rGO/a-NiO/NiFe 2 O 4 -HS. When utilized as an anode material for lithium-ion batteries, this material maintained an outstanding specific capacity of 1687.6 mA h g −1 at a current density of 100 mA g −1 after 580 cycles. This nanostructuring and phase change strategy of the two-dimensional heterostructures can effectively promote the development of high-performance electrode materials based on the pseudocapacitive mechanism.