Room temperature colossal superparamagnetic order in aminoferrocene–graphene molecular magnets

• Published in: Applied physics letters Vol. 122; no. 24
• Main Authors: Getahun, Yohannes W., Manciu, Felicia S., Pederson, Mark R., El-Gendy, Ahmed A.
• Format: Journal Article
• Language: English
• Published: Melville American Institute of Physics 12.06.2023; American Institute of Physics (AIP)
• Subjects: Anisotropy; Applied physics; Bowing; Charge transfer; Chemical compounds; CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS; Density functional theory; Graphene; Hammers; Infrared spectroscopy; Interlayers; Ligands; Magnetic anisotropy; Magnetic materials; Magnetic properties; Magnets; Mechanical properties; Operating temperature; Physics; Pressure effects; Qubits (quantum computing); Raman spectroscopy; Room temperature; Sheets; Solid phases; Substitution reactions
• ISSN: 0003-6951; 1077-3118
• DOI: 10.1063/5.0153212

Intensive studies are published for graphene-based molecular magnets due to their remarkable electric, thermal, and mechanical properties. However, to date, most of all produced molecular magnets are ligand based and subject to challenges regarding the stability of the ligand(s). The lack of long-range coupling limits high operating temperature and leads to a short-range magnetic order. Herein, we introduce an aminoferrocene-based graphene system with room temperature superparamagnetic behavior in the long-range magnetic order that exhibits colossal magnetocrystalline anisotropy of 8 × 105 and 3 × 107 J/m3 in aminoferrocene and graphene-based aminoferrocene, respectively. These values are comparable to and even two orders of magnitude larger than pure iron metal. Aminoferrocene [C10H11FeN]+ is synthesized by an electrophilic substitution reaction. It was then reacted with graphene oxide that was prepared by the modified Hammers method. The phase structure and functionalization of surface groups were characterized and confirmed by XRD, FT-IR, and Raman spectroscopy. To model the behavior of the aminoferrocene between two sheets of hydroxylated graphene, we have used density functional theory by placing the aminoferrocene molecule between two highly ordered hydroxylated sheets and allowing the structure to relax. The strong bowing of the isolated graphene sheets suggests that the charge transfer and resulting magnetization could be strongly influenced by pressure effects. In contrast to strategies based on ligands surface attachment, our present work that uses interlayer intercalated aminoferrocene opens routes for future molecular magnets as well as the design of qubit arrays and quantum systems.