Coupling of demixing and magnetic ordering phase transitions probed by turbidimetric measurements in a binary mixture doped with magnetic nanoparticles

We present a novel study on the effect of a magnetic field applied on a binary mixture doped with magnetic nanoparticles close to its demixing transition. Turbidity measurements in the Faraday configuration show that the effect of applying an external field produces changes in the critical opalescence of the mixture that allow us to track an aggregation produced by critical Casimir forces and a reversible aggregation due to the formation of chain-like flocks in response to the external magnetic field. The observation of a crossover of the aggregation curves through optical signals is interpreted as the evolution from low to high power dispersion nuclei due to an increase in the radius of the condensation seed brought about by Casimir or magnetic interactions. Finally, evidence of an enhanced magnetocaloric effect due to the coupling between mixing and ordering phase transitions is presented which opens up a nonsolid state approach of designing refrigerating cycles and devices. © 2010 IOP Publishing Ltd.

Casimir; Chain-like; Critical Casimir forces; De-mixing; Demixing transitions; External fields; External magnetic field; Faraday configuration; Low-to-high; Magnetic interactions; Magnetic nanoparticles; Magnetic ordering; Magneto-caloric effects; Optical signals; Ordering phase; Refrigerating cycles; Reversible aggregation; Turbidity measurements; Binary mixtures; Magnetic fields; Magnetic materials; Nanoparticles; Phase transitions; Turbidity; Nanomagnetics; magnetite nanoparticle; article; chemistry; drug mixture; materials testing; methodology; phase transition; photometry; solution and solubility; Complex Mixtures; Magnetite Nanoparticles; Materials Testing; Nephelometry and Turbidimetry; Phase Transition; Solutions

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