Recent Advances in Magnetite Crystallization: Pathway, Modulation, and Characterization

Abstract: Magnetite has wide applications in the fields of environment, biomedicine, and energy storage. Understanding the crystallization process of magnetite will improve the design and control of its properties. However, the challenge lies in determining the crystallization pathway of magnetite due to its nanosized and unstable intermediates. Recent developments in the in situ characterization techniques have shed light on this process, which has rarely been elucidated systematically. This review builds the correlati… Show more

“…Generally, the formation of magnetite follows a typical three-stage process: (i) the generation of amorphous intermediates, (ii) the transformation of these intermediates into crystalline nuclei, and (iii) the subsequent growth of crystalline nuclei to form larger-sized magnetite crystals. 14 In our study, it is inevitable that intermediates are formed in the initial stage. Therefore, shortening the crystalline nuclei transformation process in the subsequent stage has the potential to minimize the binding opportunities between the iron phase and Zn.…”

“…It is well known that thermodynamically unstable, kinetically stable, amorphous intermediates, such as goethite, lepidocrocite, and akaganeite, are commonly formed during magnetite formation in different reaction conditions (reaction for 1–72 h at pH = 5–14 and 25 °C). 11–14 These intermediates are characterized by their nano/micron size, large specific surface area, and abundant exposed groups, particularly hydroxyl groups. In the transformation process, these intermediates bind to metal ions by adsorption, surface deposition, or complexation, and retain the metal ions in the final crystal product.…”

Magnetite precipitation approach for zinc hydrometallurgy: a microfluidic strategy

“…Generally, the formation of magnetite follows a typical three-stage process: (i) the generation of amorphous intermediates, (ii) the transformation of these intermediates into crystalline nuclei, and (iii) the subsequent growth of crystalline nuclei to form larger-sized magnetite crystals. 14 In our study, it is inevitable that intermediates are formed in the initial stage. Therefore, shortening the crystalline nuclei transformation process in the subsequent stage has the potential to minimize the binding opportunities between the iron phase and Zn.…”

“…It is well known that thermodynamically unstable, kinetically stable, amorphous intermediates, such as goethite, lepidocrocite, and akaganeite, are commonly formed during magnetite formation in different reaction conditions (reaction for 1–72 h at pH = 5–14 and 25 °C). 11–14 These intermediates are characterized by their nano/micron size, large specific surface area, and abundant exposed groups, particularly hydroxyl groups. In the transformation process, these intermediates bind to metal ions by adsorption, surface deposition, or complexation, and retain the metal ions in the final crystal product.…”

Magnetite precipitation approach for zinc hydrometallurgy: a microfluidic strategy

Reactions of disinfectants at solution/iron interfaces: Modeling pipeline surface chemistry

Iron biomineralization by mediation of clMagR/clCry4 protein contribute to T2 contrast enhanced in MRI