Shu-Ting Liu

Facile preparation of MnFe2O4/halloysite nanotubular encapsulates with enhanced magnetic and electromagnetic performances

We synthesized novel magnetic nanotubular encapsulates with ferrite nanoparticles embedded into the inner channels of halloysite nanotubes (HNTs) for the first time. The nano-encapsulates with enclosed ferrite nanoparticles show significantly enhanced magnetic and electromagnetic performance when compared to that with external particles.

Preparation of hollow iron/halloysite nanocomposites with enhanced electromagnetic performances

Nanostructures loaded on halloysite nanotubes (HNTs) have attracted global interest, because the nanotubular HNTs could extend the range of their potential applications. In this study, we fabricated a novel nanocomposite with hollow iron nanoparticles loaded on the surface of HNTs. The structure of the iron nanoparticles can be adjusted by ageing time. Owing to the increased remnant magnetization and coercivity values, the nanocomposites loaded with hollow iron nanoparticles showed better electromagnetic performance than that with solid iron nanoparticles. This study opens a new pathway to fabricate halloysite nanotubular nanocomposites that may gain applications in the catalytic degradation of organic pollutants and electromagnetic wave absorption.

Thermal destruction of luffa sponge under air and nitrogen

Luffa sponge is an agricultural product with large global production. In this study, we studied the effect of ashing temperature and atmosphere on the physicochemical characteristics of luffa sponge. All of the ashed samples are amorphous materials with porous structures. The luffa sponge ashed in air (LSA) and luffa sponge ashed in nitrogen (LSN) show analogous elemental compositions. However, the oxygen in the air can promote the incineration and combustion of luffa sponge, while nitrogen atmosphere can hinder the decomposition of organic compounds due to carbonization. Their pore characteristics, therefore, vary with temperatures and atmospheres. The BET surface area, total pore volume, and mesopore volume generally increase with ashing temperature, due to the thermal destruction of organic matter in luffa sponge. LSA samples exhibit relatively higher surface area and total pore volume than LSN samples. Their mesopore volumes, however, are comparable, attributed to the preservation of original pores from enlargement under nitrogen atmosphere. With characteristics of low cost, low density, and comparable pore properties with traditional adsorbents, luffa sponge is a potential adsorbent for organic pollutants and a carrier for catalysts.