Effect of Phase Transitions in Polymer Solutions on the Magnetic Response of Embedded Nanoparticles

Abstract: Doping complex polymer solutions with magnetic nanoparticles opens up a class of functional materials. However, a distinct decrease in the degree of magnetic in-field alignment of nanoparticles upon crystallization of the carrier liquid is observed, which could pose a crucial hindrance for the preparation of such hybrid materials. To understand their behavior in detail, including their performance over extended temperature ranges and their structural transformations in the presence of external fields, it is us… Show more

“…These may originate either from enhanced interparticular magnetic interaction within the remaining fluid volume or mechanical or hydrodynamic interaction with forming ice-crystal structures. 52 3.2.2 Temperature dependent AC-susceptibility. To gather closer information on temperature dependent relaxation dynamics of individual MNPs as well as of the microgel particles, magnetic AC-susceptometry measurements were performed at temperatures of 0-50 1C.…”

Magnetic response of CoFe₂O₄ nanoparticles confined in a PNIPAM microgel network

“…These may originate either from enhanced interparticular magnetic interaction within the remaining fluid volume or mechanical or hydrodynamic interaction with forming ice-crystal structures. 52 3.2.2 Temperature dependent AC-susceptibility. To gather closer information on temperature dependent relaxation dynamics of individual MNPs as well as of the microgel particles, magnetic AC-susceptometry measurements were performed at temperatures of 0-50 1C.…”

Magnetic response of CoFe₂O₄ nanoparticles confined in a PNIPAM microgel network

“…This modified thermal decomposition method can save material and time cost more effectively. [15,[17][18][19][20] Silica coating of Zn 0.5 Co x Fe 2.5−x O 4 NPs was performed via the reverse microemulsion method. [16] The hyperthermia properties of Zn 0.5 Co x Fe 2.5−x O 4 /SiO 2 composite NPs were systematically studied under AC field.…”

Enhanced hyperthermia performance in hard-soft magnetic mixed Zn_0.5CoxFe_{2.5 – x} O₄/SiO₂ composite magnetic nanoparticles*

Impact of coating type on structure and magnetic properties of biocompatible iron oxide nanoparticles: insights into cluster organization and oxidation stability