Measuring and modeling broadband magnetic losses versus temperature and aging effects in CoO-doped Mn-Zn ferrites

We analyze the physical mechanisms associated with addition of CoO to sintered Mn-Zn ferrites and the ensuing stabilization versus temperature of their magnetic properties. We determine, in particular, the value and behavior of the magnetic anisotropy as a function of doping and temperature and we model in physical terms the evolution of the energy loss in the investigated frequency (DC - 1 GHz) and temperature (20 degrees C - +130 degrees C) ranges. We show that magnetic aging by long exposure of the CoO-doped ferrites at 200 degrees C is minimized by additional TiO2 doping. This is observed to restrain the increase of the extra-anisotropy induced by directional ordering of the Co2+ cations

Green synthesis and characterization of silver nanoparticles produced using 'Arbutus Unedo' leaf extract

Metallic nanoparticles have received great attention from chemists, physicists, biologists and engineers who wish to use them for the development of a new generation of nanodevices. In the present study silver nanoparticles were synthesized from aqueous silver nitrate through a simple and eco-friendly route using leaf broth of Arbutus unedo, which acted as a reductant and stabilizer simultaneously. The aqueous silver ions when exposed to the leaf broth were reduced and stabilized over long periods of time resulting in the green synthesis of surface functionalized silver nanoparticles. The bio-reduced silver nanoparticles were appropriately characterized. The results revealed the formation of single crystalline Ag nanoparticles with a narrow size distribution for each sample. The particles, although discrete, were predominately coated with the organic leaf extract forming small aggregates, which makes them stable over long time periods and highly appropriate for coatings or biotechnology applications.Publicad

Assessing the role of bed sediments in the persistence of red mud pollution in a shallow lake (Kinghorn Loch, UK)

Red mud is a by-product of alumina production. Little is known about the long-term fate of red mud constituents in fresh waters or of the processes regulating recovery of fresh waters following pollution control. In 1983, red mud leachate was diverted away from Kinghorn Loch, UK, after many years of polluting this shallow and monomictic lake. We hypothesised that the redox-sensitive constituents of red mud leachate, phosphorus (P), arsenic (As) and vanadium (V), would persist in the Kinghorn Loch for many years following pollution control as a result of cycling between the lake bed sediment and the overlying water column. To test this hypothesis, we conducted a 12-month field campaign in Kinghorn Loch between May 2012 and April 2013 to quantify the seasonal cycling of P, As, and V in relation to environmental conditions (e.g., dissolved oxygen (DO) concentration, pH, redox chemistry and temperature) in the lake surface and bottom waters. To confirm the mechanisms for P, As and V release, a sediment core incubation experiment was conducted using lake sediment sampled in July 2012, in which DO concentrations were manipulated to create either oxic or anoxic conditions similar to the bed conditions found in the lake. The effects on P, As, and V concentrations and species in the water column were measured daily over an eight-day incubation period. Phosphate (PO4-P) and dissolved As concentrations were significantly higher in the bottom waters (75.9 ± 30.2 μg L−1 and 23.5 ± 1.83 μg L−1, respectively) than in the surface waters (12.9 ± 1.50 μg L−1 and 14.1 ± 2.20 μg L−1, respectively) in Kinghorn Loch. Sediment release of As and P under anoxic conditions was confirmed by the incubation experiment and by the significant negative correlations between DO and P and As concentrations in the bottom waters of the lake. In contrast, the highest dissolved V concentrations occurred in the bottom waters of Kinghorn Loch under oxic conditions (15.0 ± 3.35 μg L−1), with the release from the bed sediment apparently being controlled by a combination of competitive ion concentrations, pH and redox conditions

MnZn-ferrites: Targeted Material Design for New Emerging Application Products

In this article the main characteristics for emerging MnZn-ferrite applications are described on the basis of the new demands they possess on the ferrite material development. A number of recently developed MnZn-ferrite materials is presented together with the main scientific principles lying behind their development. These include: (i) high saturation flux density MnZn-ferrites (i.e. Bsat=550 mT at 10 kHz, 1200 A/m, 100°C), (ii) low power losses MnZn-ferrites (i.e. Pv~210 mW cm-3 at 100 kHz, 200mT, 100°C), (iii) MnZn-ferrites with broad temperature stability (i.e. PV<375 mW cm-3 for 25°C<T<140°C at 100 kHz, 200 mT), and (iv) MnZn-ferrites with high and frequency stable permeability (i.e. μi~12600 at 10 kHz, 0.1 mT, 25°C and tan(δ)/μi=20.5×10-6 at 100 kHz). In a final discussion the importance of defect chemistry for the time stability and stress sensitivity of the magnetic properties is discussed and some important issues are addressed, encountered during the transfer of a laboratory developed material to a large scale industrial production process

Magnetic nanoparticles in medical diagnostic applications: Synthesis, characterization and proteins conjugation

Background: Magnetic nanoparticles (NPs) used in biomedical applications should be discrete with small particle sizes, narrow size distribution and superparamagnetic. NPs can be tailored to target, through chemical bonds, specific organs, cells, or even molecular markers of different diseases in vivo, with suitable surface chemistry modification. Methods: Nanoparticles are synthesized by a low cost coprecipitation reaction of ferrous and ferric salts with alkaline solution. The characteristics of the NPs are modified by varying the addition rate of the alkaline solution. NPs surface is silica coated using a modified Stöbe method. The conversion of the surface hydroxyl groups into amino-groups is performed by two different alkoxysilanes and the silanization reaction is conducted either in Methanol – Glycerol environment at elevated temperature, or in water at room temperature. The surface amine groups of the NPs are further converted, either to aldehyde groups by glutaraldehyde, or to carboxyl groups using glutaric anhydride. Bovine Serum Albumin and Vena human natural immunoglobulin are used in order to study the protein conjugation capacity of the functionalized NPs. The amount of protein attached to the nanoparticles is determined by UV–Vis spectroscopy of the supernatant. Conjugation of synthesized nanoparticles to protein BSA is examined by FTIR spectroscopy. SDS-PAGE electrophoresis followed by protein immunoblotting is used to test the effect of nano-conjugation to the antibodies. Results: Superparamagnetic Fe3O4 nanoparticles with saturation magnetization 60emu/g, a mean diameter 8-12 nm and BET surface areas between 100-250 m2/gr are obtained with total time of addition of the base between 1-5 minutes. They are coated with a thin and nearly uniform silica (SiO2) layer with thickness 1-2 nm. The most appropriate source for surface functionalization with amino groups is 3-aminopropyltriethoxysilane (APTES), while the two silanization methods used, proved to be equally efficient. NPs with surface aldehyde groups display better conjugation capacity than NPs functionalized with carboxyl groups. The FTIR spectra of the protein conjugated NPs samples, contain the two main peaks, at 1529 cm-1 and 1661 cm-1, attributed to the amide bond of the protein, which confirms the conjugation of the protein to the NPs. During a SDS-PAGE electrophoresis -protein immunoblotting experiment, the antibodies, after being conjugated to the nanoparticles, are selectively attached to their antigen, which indicates of lack of significant conformation changes secondary to the conjugation process. Conclusion: The conjugation capacity of the optimized nanoparticles is higher for Ig antibody than for BSA protein, under similar reaction conditions. The conjugational efficacy and conformational stability and the effect on electrophoretic mobility of the antibodies conjugated to the nanoparticles are verified by protein immunoblotting. © 2016 Bentham Science Publishers

Activity and Thermal Aging Stability of La_1−xSr_xMnO₃ (x = 0.0, 0.3, 0.5, 0.7) and Ir/La_1−xSr_xMnO₃ Catalysts for CO Oxidation with Excess O₂

The catalytic oxidation of CO is probably the most investigated reaction in the literature, for decades, because of its extended environmental and fundamental importance. In this paper, the oxidation of CO on La1−xSrxMnO3 perovskites (LSMx), either unloaded or loaded with dispersed Ir nanoparticles (Ir/LSMx), was studied in the temperature range 100–450 °C under excess O2 conditions (1% CO + 5% O2). The perovskites, of the type La1−xSrxMnO3 (x = 0.0, 0.3, 0.5 and 0.7), were prepared by the coprecipitation method. The physicochemical and structural properties of both the LSMx and the homologous Ir/LSMx catalysts were evaluated by various techniques (XRD, N2 sorption–desorption by BET-BJH, H2-TPR and H2-Chem), in order to better understand the structure–activity–stability correlations. The effect of preoxidation/prereduction/aging of the catalysts on their activity and stability was also investigated. Results revealed that both LSMx and Ir/LSMx are effective for CO oxidation, with the latter being superior to the former. In both series of materials, increasing the substitution of La by Sr in the composition of the perovskite resulted to a gradual suppression of their CO oxidation activity when these were prereduced; the opposite was true for preoxidized samples. Inverse hysteresis phenomena in activity were observed during heating/cooling cycles on the prereduced Ir/LSMx catalysts with the loop amplitude narrowing with increasing Sr-content in LSMx. Oxidative thermal sintering experiments at high temperatures revealed excellent antisintering behavior of Ir nanoparticles supported on LSMx, resulting from perovskite’s favorable antisintering properties of high oxygen storage capacity and surface oxygen vacancies