Interparticle interactions mediated superspinglass to superferromagnetic transition in Ni-bacterial cellulose aerogel nanocomposites

TL;DR

This study investigates how interparticle interactions influence phase transitions from superparamagnetic to superspinglass to superferromagnetic in Ni-bacterial cellulose aerogel nanocomposites, revealing temperature-dependent magnetic behavior.

Contribution

It introduces a microstructural model linking nanoparticle size distribution and interparticle interactions to magnetic phase transitions in Ni-BC composites.

Findings

Nanoparticles of 10 nm, 50 nm, and 100 nm sizes form naturally within the composite.

Magnetic behavior transitions from weakly ferromagnetic at room temperature to superferromagnetic at low temperatures.

A temperature-dependent microstructural model explains the observed magnetic phase transitions.

Abstract

The interparticle interactions in a magnetic nanocomposite play a dominant role in controlling the phase transitions superparamagnetic to superspinglass to superferromagnetic. These interactions can be tuned by controlling the size and number density of nanoparticles. Aerogel composites, 0.3 Ni-BC and 0.7 Ni-BC, consisting of Ni nanoparticles distributed in bacterial cellulose have been used as model systems to study the effect of interparticle interactions with increasing fraction of Ni in the composite. Contrary to conventional approach, the size of Ni nanoparticles is not controlled and was allowed to form naturally in the bacterial cellulose template. The structural characterization using x-ray diffraction and electron microscopies indicates the presence of only Ni and cellulose with no other phases. The uncontrolled growth of Ni in cellulose matrix results in the formation of nanoparticles with 3 different size distributions - 10 nm particles mainly distributed along the length of fibrils, 50 nm particles present in the intermediate spaces between the fibrils and 100 nm particles present in voids formed by the reticulate structure. At room temperature the composites exhibit a weakly ferromagnetic behavior with a coercivity of 40 Oe which increases to 160 Oe at 10 K. The transition from weakly ferromagnetic state at room temperature to a superferromagnetic state at low temperatures is mediated via a superspinglass state at intermediate temperatures. A temperature dependent microstructural model has been developed combining the structural and magnetic results obtained from the two composite aerogels.