Search Results (73)

A facile low temperature hydrothermal-calcination approach was developed for the fabrication of β-FeOOH nanorods (NRs) and hollow-structure α-Fe₂O₃ magnetic nanorods (MNRs), and the products were characterized using SEM, TEM, XRD and VSM techniques. To achieve smaller-sized β-FeOOH NRs, the effects of Fe³⁺ concentration, the volume ratio of ethanol to water in solution, hydrothermal temperature, and hydrothermal time on the structure of the precursors were systematically investigated, and the nanorods with an average length 104 nm and diameter 36 nm were fabricated at hydrothermal temperature of 100 °C for 2 h using 0.15 M ferric chloride hexahydrate in 50% ethanol solution. Subsequently, the hollow-structure α-Fe₂O₃ MNRs with an average length of 67 nm, diameter of 20 nm, and thickness of 5 nm were successfully obtained via the calcination process at 400 °C for 2.5 h for versatile applications. Full article

The synergistic application of magnetic fields and iron oxide nanorod particles (IONPs) presents a novel therapeutic approach for inducing lysosome-dependent cell death (LDCL) via magneto-mechanical force (MMF). This study demonstrates the efficacy of decaying oscillating pulsed magnetic fields (DOPMFs) to propel IONPs to induce rapid tumor regression via lysosomal membrane permeabilization (LMP). The systematic evaluation of dose-dependent parameters revealed that DOPMF intensity and pulse number critically determine A375 melanoma cell viability reduction. Mechanistic investigations identified two hallmark biomarkers of LMP: increased cytosolic cathepsin B activity and downregulated LAMP-2 expression. Crucially, in vivo experiments using A375 melanoma-bearing mouse models corroborated the therapeutic potential of this approach, showing significant tumor growth inhibition without systemic toxicity or invasive procedures. Collectively, our findings demonstrate that MMF by IONPs under DOPMF stimulation exhibits significant efficacy in suppressing melanoma proliferation, offering a non-invasive, targeted approach for oncological intervention. Full article

A hydrothermal and combustion-reduction process with polyvinyl pyrrolidone (PVP) as a restricted growth agent and galactose as a reducing agent was developed for the fabrication of rod-like α-Fe₂O₃/Fe₃O₄ magnetic nanocomposites (MNCs). Firstly, β-FeOOH nanorods (NRs) were fabricated by the hydrothermal method, with PVP as a restricted growth agent. To obtain a smaller size for better applications in the biomedical field, the concentrations of FeCl₃ and PVP, the hydrothermal temperature, and the hydrothermal time were optimized as 0.171 M, 0.163 mM, 100 °C, and 8 h, and the fabricated β-FeOOH NRs were 193.1 nm in average length and 43.2 nm in average diameter. Then, with β-FeOOH NRs as precursors, α-Fe₂O₃/Fe₃O₄ MNCs were prepared via the combustion-reduction process with galactose as a reducing agent; the factors of the calcination temperature and time and the mass ratio of β-FeOOH and galactose were assessed as 300 °C, 0.5 h, and 1:2, respectively. The prepared α-Fe₂O₃/Fe₃O₄ MNCs under the optimized conditions were 81.6 nm in average length and 23.9 nm in average diameter, while their saturation magnetization reached 69.8 emu/g. Full article

Due to a wide band gap and large exciton binding energy, zinc oxide (ZnO) is currently receiving much attention in various areas, and can be prepared in various forms including nanorods, nanowires, nanoflowers, and so on. The reliability of ZnO produced by a single dopant is unstable, which in turn promotes the development of co-doping techniques. Co-doping is a very promising technique to effectively modulate the optical, electrical, magnetic, and photocatalytic properties of ZnO, as well as the ability to form various structures. In this paper, the important advances in co-doped ZnO nanomaterials are summarized, as well as the preparation of co-doped ZnO nanomaterials by using different methods, including hydrothermal, solvothermal, sol-gel, and acoustic chemistry. In addition, the wide range of applications of co-doped ZnO nanomaterials in photocatalysis, solar cells, gas sensors, and biomedicine are discussed. Finally, the challenges and future prospects in the field of co-doped ZnO nanomaterials are also elucidated. Full article

Numerous optoelectronic devices based on low-dimensional nanostructures have been developed in recent years. Among these, pyramidal low-dimensional semiconductors (zero- and one-dimensional nanomaterials) have been favored in the field of optoelectronics. In this review, we discuss in detail the structures, preparation methods, band structures, electronic properties, and optoelectronic applications (photocatalysis, photoelectric detection, solar cells, light-emitting diodes, lasers, and optical quantum information processing) of pyramidal low-dimensional semiconductors and demonstrate their excellent photoelectric performances. More specifically, pyramidal semiconductor quantum dots (PSQDs) possess higher mobilities and longer lifetimes, which would be more suitable for photovoltaic devices requiring fast carrier transport. In addition, the linear polarization direction of exciton emission is easily controlled via the direction of magnetic field in PSQDs with C_3v symmetry, so that all-optical multi-qubit gates based on electron spin as a quantum bit could be realized. Therefore, the use of PSQDs (e.g., InAs, GaN, InGaAs, and InGaN) as effective candidates for constructing optical quantum devices is examined due to the growing interest in optical quantum information processing. Pyramidal semiconductor nanorods (PSNRs) and pyramidal semiconductor nanowires (PSNWRs) also exhibit the more efficient separation of electron-hole pairs and strong light absorption effects, which are expected to be widely utilized in light-receiving devices. Finally, this review concludes with a summary of the current problems and suggestions for potential future research directions in the context of pyramidal low-dimensional semiconductors. Full article

This work reports on the design, development, and characterization of novel magneto-plasmonic elastic liposomes (MPELs) of DPPC:SP80 (85:15) containing Mg_0.75Ca_0.25Fe₂O₄ nanoparticles coupled with gold nanorods, for topical application of photothermal therapy (PTT). Both magnetic and plasmonic components were characterized regarding their structural, morphological, magnetic and photothermal properties. The magnetic nanoparticles display a cubic shape and a size (major axis) of 37 ± 3 nm, while the longitudinal and transverse sizes of the nanorods are 46 ± 7 nm and 12 ± 1.6 nm, respectively. A new methodology was employed to couple the magnetic and plasmonic nanostructures, using cysteine as bridge. The potential for photothermia was evaluated for the magnetic nanoparticles, gold nanorods and the coupled magnetic/plasmonic nanoparticles, which demonstrated a maximum temperature variation of 28.9 °C, 33.6 °C and 37.2 °C, respectively, during a 30 min NIR-laser irradiation of 1 mg/mL dispersions. Using fluorescence anisotropy studies, a phase transition temperature (T_m) of 35 °C was estimated for MPELs, which ensures an enhanced fluidity crucial for effective crossing of the skin layers. The photothermal potential of this novel nanostructure corresponds to a specific absorption rate (SAR) of 616.9 W/g and a maximum temperature increase of 33.5 °C. These findings point to the development of thermoelastic nanocarriers with suitable features to act as photothermal hyperthermia agents. Full article

We report a new facile method for the synthesis of prolate cobalt ferrite nanoparticles without additional stabilizers, which involves a co-precipitation reaction of Fe³⁺ and Co²⁺ ions in a static magnetic field. The magnetic field is demonstrated to be a key factor for the 1D growth of cobalt ferrite nanocrystals in the synthesis. Transmission electron microscopy (TEM), X-ray diffraction (XRD), and Raman spectroscopy are applied to characterize the morphology and structure of the obtained nanoparticles. According to TEM, they represent nanorods with a mean length of 25 nm and a diameter of 3.4 nm that have a monocrystalline structure with characteristic plane spacing of 2.9 Å. XRD and Raman spectroscopy confirm the spinel CoFe₂O₄ structure of the nanorods. After aging, the synthesized nanorods exhibit maximum saturation magnetization and coercivity equal to 30 emu/g and 0.3 kOe, respectively. Thus, the suggested method is a simple and “green” way to prepare CoFe₂O₄ nanorods with high aspect ratios and pronounced magnetic properties, which are important for various practical applications, including biomedicine, energy storage, and the preparation of anisotropic magnetic nanocomposites. Full article

The Co-Pt binary system can form a two-phase nanochessboard structure comprising regularly aligned nanorods of magnetically hard tetragonal L1₀ phase and magnetically soft cubic L1₂ phase. This Co-Pt nanochessboard, being an exchange-coupled magnetic nanocomposite, exhibits a strong effect on magnetic domains and coercivity. While the ideal nanochessboard structure has tiles with equal edge lengths (a = b), the non-ideal or nonstandard nanochessboard structure has tiles with unequal edge lengths (a ≠ b). In this study, we employed phase-field modeling and computer simulation to systematically investigate the exchange coupling effect on magnetic properties in nonstandard nanochessboards. The simulations reveal that coercivity is dependent on the length scale, with magnetic hardening occurring below the critical exchange length, followed by magnetic softening above the critical exchange length, similar to the standard nanochessboards. Moreover, the presence of unequal edge lengths induces an anisotropic exchange coupling and shifts the coercivity peak with the length scale. Full article

This Special Issue includes 12 research papers on the development of various materials for adsorbing different contaminants in water, such as Sb, Cr(VI), Cu(II), Zn(II), fluorine, phenol, dyes (indigo carmine, Congo red, methylene blue, and crystal violet), and drugs (dlevofloxacin, captopril, and diclofenac, and paracetamol). The commercial, natural, and synthetic materials used as adsorbents comprise commercial activated carbon, natural clay and montmorillonite, biosorbent based on sugarcane bagasse or algal, graphene oxide, graphene oxide-based magnetic nanomaterial, mesoporous Zr-G-C₃N₄ nanomaterial, nitrogen-doped core–shell mesoporous carbonaceous nano-sphere, magnetic Fe-C-N composite, polyaniline-immobilized ZnO nanorod, and hydroxy-iron/acid–base-modified sepiolite composite. Various operational conditions are evaluated under batch adsorption experiments, such as pH, NaCl, solid/liquid ratio, stirring speed, contact time, solution temperature, initial adsorbate concentration. The re-usability of laden materials is evaluated through adsorption–desorption cycles. Adsorption kinetics, isotherm, thermodynamics, and mechanisms are studied and discussed. Machine learning processes and statistical physics models are also applied in the field of adsorption science and technology. Full article

The recent advancements in magnetoelectric (ME) materials have enabled the development of functional magnetoelectric composites for sensor applications in the medical and engineering sectors, as well as in energy harvesting and material exploration. Magnetoelectric composites rely on the interaction between piezoelectric and magnetoelastic materials by coupling the magnetization-induced strain to the strain-generated potential of the piezoelectric phase. This creates an increased interest around the development of novel piezoelectric materials that not only possess favorable piezoelectric properties but also fulfill specific material criteria such as biocompatibility, bioactivity, ease of fabrication and low cost. ZnO, and its nanostructures, is one such material that has been employed in the magnetoelectric research due to its remarkable piezoelectric, semiconducting and optical properties. Thus, this article provides a comprehensive review of the available literature on magnetoelectric composites based on ZnO micro- and nanostructures, aiming to present a concise reference on the methods, applications and future prospects of ZnO-based ME composites. Specifically, a brief introduction is provided, presenting the current research interests around magnetoelectric composites, followed by a concise mention of the magnetoelectric effect and its key aspects. This is followed by separate sections describing the relevant research on ZnO magnetoelectric composites based on ZnO thin-films, either pure or doped, and nano- and microrods composites, as well as nano composites comprised of ZnO nanoparticles mixed with ferromagnetic nanoparticles. Finally, the future prospects and the extension of ME ZnO research into nanowire and nanorod composites are discussed. Full article

The presence of antibiotic ciprofloxacin (CIP) in pharmaceutical wastewaters is dangerous when their concentrations exceed the allowable limits. Thus, eliminating CIP from pharmaceutical wastewaters is an essential issue. In this work, magnetic MOFs, named Fe₃O₄/Zn₃(BTC)₂ MMOF, were successfully synthesized and used for the adsorption of CIP. Compared with Cu₃(BTC)₂ and Fe₃O₄/Cu₃(BTC)₂ MMOF, the Fe₃O₄/Zn₃(BTC)₂ MMOF exhibited the best CIP-adsorption performance, with a maximum removal rate of 72.15% due to the large pore size, abundant adsorption sites and functional groups of MOFs, and the magnetic properties of the Fe₃O₄ nanorod. The influencing factors in the adsorption process, including oscillation time and pH value, were discussed, and the best adsorption performance was obtained when the pH was 3.84 and the oscillation time was 90 min. Furthermore, the removal rate of the Fe₃O₄/Zn₃(BTC)₂ MMOF still reached 31.45% after five instances of reuse, revealing its great regeneration and reusability. The results of the adsorption-kinetics studies showed that the adsorption process of CIP by Fe₃O₄/Zn₃(BTC)₂ MMOF followed the pseudo-second-order kinetic model and was mainly chemical adsorption. Based on the results above, Fe₃O₄/Zn₃(BTC)₂ MMOF is recommended as a highly efficient adsorbent for the removal of CIP from pharmaceutical wastewaters. Full article

This study presents a simple and innovative approach for producing one-dimensional Mn₅Si₃ nanorods through a casting-extraction process. In this technique, the Mn₅Si₃ nanorods were synthesized by reacting Mn and Si during brass solidification and extracted by electrochemical etching of the brass matrix. The effect of the cooling rate during casting on the nanorods’ dimension, morphology, and magnetic properties was investigated. The results demonstrate that the prepared high-purity Mn₅Si₃ nanorods had a single-crystal D8₈ structure and exhibited ferromagnetism at room temperature. The morphology of the nanorods was an elongated hexagonal prism, and their preferred growth was along the [0001] crystal direction. Increasing the cooling rate from 5 K/s to 50 K/s lead to a decrease in the dimension of the nanorods but an increase in their ferromagnetism. At the optimal cooling rate of 50 K/s, the nanorods had a diameter and length range of approximately 560 nm and 2~11 μm, respectively, with a highest saturation magnetization of 7.5 emu/g, and a maximum coercivity of 120 Oe. These properties make the fabricated Mn₅Si₃ nanorods potentially useful for magnetic storage applications, and this study also provides a new perspective on the preparation of one-dimensional nanomaterials. Full article

Helical magnets are emerging as a novel class of materials for spintronics and sensor applications; however, research on their charge- and spin-transport properties in a thin film form is less explored. Herein, we report the temperature and magnetic field-dependent charge transport properties of a highly crystalline MnP nanorod thin film over a wide temperature range (2 K < T < 350 K). The MnP nanorod films of ~100 nm thickness were grown on Si substrates at 500 °C using molecular beam epitaxy. The temperature-dependent resistivity ρ(T) data exhibit a metallic behavior (dρ/dT > 0) over the entire measured temperature range. However, large negative magnetoresistance (Δρ/ρ) of up to 12% is observed below ~50 K at which the system enters a stable helical (screw) magnetic state. In this temperature regime, the Δρ(H)/ρ(0) dependence also shows a magnetic field-manipulated CONE + FAN phase coexistence. The observed magnetoresistance is dominantly governed by the intergranular spin dependent tunneling mechanism. These findings pinpoint a correlation between the transport and magnetism in this helimagnetic system. Full article

The inherent existence of multi phases in iron oxide nanostructures highlights the significance of them being investigated deliberately to understand and possibly control the phases. Here, the effects of annealing at 250 °C with a variable duration on the bulk magnetic and structural properties of high aspect ratio biphase iron oxide nanorods with ferrimagnetic Fe₃O₄ and antiferromagnetic α-Fe₂O₃ are explored. Increasing annealing time under a free flow of oxygen enhanced the α-Fe₂O₃ volume fraction and improved the crystallinity of the Fe₃O₄ phase, identified in changes in the magnetization as a function of annealing time. A critical annealing time of approximately 3 h maximized the presence of both phases, as observed via an enhancement in the magnetization and an interfacial pinning effect. This is attributed to disordered spins separating the magnetically distinct phases which tend to align with the application of a magnetic field at high temperatures. The increased antiferromagnetic phase can be distinguished due to the field-induced metamagnetic transitions observed in structures annealed for more than 3 h and was especially prominent in the 9 h annealed sample. Our controlled study in determining the changes in volume fractions with annealing time will enable precise control over phase tunability in iron oxide nanorods, allowing custom-made phase volume fractions in different applications ranging from spintronics to biomedical applications. Full article

Multiple resonance modes in an optical absorber are necessary for nanophotonic devices and encounter a challenge in the visible range. This article designs a multiple-channel plasmonic metamaterial absorber (PMA) that comprises a hexagonal arrangement of metal-shell nanorods in a unit cell over a continuous thin metal layer, operating in the visible range of the sensitive refractive index (RI) and temperature applications. Finite element method simulations are utilized to investigate the physical natures, such as the absorptance spectrum, magnetic flux and surface charge densities, electric field intensity, and electromagnetic power loss density. The advantage of the proposed PMA is that it can tune either three or five absorptance channels with a narrowband in the visible range. The recorded sensitivity and figure of merit (S, FOM) for modes 1–5 can be obtained (600.00 nm/RIU, 120.00), (600.00 nm/RIU, 120.00 RIU⁻¹), (600.00 nm/RIU, 120.00 RIU⁻¹), (400.00 nm/RIU, 50.00 RIU⁻¹), and (350.00 nm/RIU, 25.00 RIU⁻¹), respectively. Additionally, the temperature sensitivity can simultaneously reach 0.22 nm/°C for modes 1–3. The designed PMA can be suitable for RI and temperature sensing in the visible range. Full article