Approaching Elaborate Control of the Nano-Products of Carbothermal Reduction Reaction Through In Situ Identification

Atomic understanding of a chemical reaction can realize the programmable design and synthesis of desired products with specific compositions and structures. Through directly monitoring the phase transition and tracking the dynamic evolution of atoms in a chemical reaction, in situ transmission electron microscopy (TEM) techniques offer the feasibility of revealing the reaction kinetics at the atomic level. Nevertheless, such investigation is quite challenging, especially for reactions involving multi-phase and complex interfaces, such as the widely adopted carbothermal reduction (CTR) reactions. Herein, in-situ TEM is applied to monitor the CTR of Co3O4 nanocubes on reduced graphene oxide nanosheets. Together with the first-principle calculation, the migration route of Co atoms during the phase transition of the CTR reaction is revealed. Meanwhile, the interfacial edge-dislocations/stress-gradient is identified as a result of the atomistic diffusion, which in turn can affect the morphology variation of the reactants. Accordingly, controllable synthesis of Co-based nanostructure with a desirable phase and structure has been achieved. This work not only provides atomic kinetic insight into CTR reactions but also offers a novel strategy for the design and synthesis of functional nanostructures for emerging energy technologies.

Automated summary

Atomic understanding of chemical reactions enables programmable design and synthesis of desired products. In situ transmission electron microscopy (TEM) techniques, combined with first-principle calculations, are used to monitor the carbothermal reduction (CTR) reactions and reveal the migration route of Co atoms during phase transition and the effect of interfacial edge-dislocations/stress-gradient on morphology variation. Controllable synthesis of Co-based nanostructures with desirable phase and structure is achieved, providing insights into CTR reactions and offering a novel strategy for designing functional nanostructures in emerging energy technologies.