Facile preparation of ammonium alginate-derived nanofibers carrying diverse therapeutic cargo.

Alginic acid was converted to a variety of ammonium alginate derivatives carrying diverse chemical cargo such as analgesics, antibiotics, and enzymes. These functional polymers could be fashioned into nanofibrous mats by electrostatic spinning. The therapeutic payload could be released in functional form by a simple ion exchange mechanism. Prospects in wound healing are discussed.

Tuning physical and optical properties of ZnO nanowire arrays grown on cotton fibers.

This article reports the first systematic study on the quantitative relationship between the process parameters of solution concentration ratio, structure, and physical and optical properties of ZnO nanowires grown on cotton surfaces. To develop a fundamental understanding concerning the process-structure-activity relations, we grew a series of well-defined, radially oriented, highly dense, and uniform single-crystalline ZnO nanorods and nanoneedles on cotton surfaces by a simple and inexpensive two-step optimized hydrothermal process at a relatively low temperature. This process involves seed treatment of a cotton substrate with ZnO nanocrystals that will serve as the nucleation sites for subsequent anisotropic growth of single crystalline ZnO nanowires. All of the ZnO nanowires exhibit wurtzite crystal structure oriented along the c-axis. For investigating structure-controlled properties, seed-to-growth solutions concentrations ratio ([S]/[G]) of the synthesis process was varied over six different values. Superhydrophobicity was achieved for all morphologies after 1-dodecanethiol modification, which was highly durable after prolonged UV irradiation. Durability of the ZnO materials under laundry condition was also verified. Variation of the [S]/[G] ratio resulted in a morphological transform from nanorods to needle-like structures in conjunction with a drastic change in the physical and optical properties of the ZnO modified cotton surfaces. Higher [S]/[G] ratios yielded formation of ZnO nanoneedles with high degree of crystallinity and higher aspect ratio compared to nanorods. Increasing [S]/[G] ratio resulted in the amount of ZnO grown on the cotton surface to drop significantly, which also caused a decrease in the surface hydrophobicity and UV absorption. In addition, room temperature photoluminescence measurements revealed that the band gap of ZnO widened and the structural defects were reduced as the morphology changed from nanorods to nanoneedles. A similar trend was observed in the UV-vis absorption of nanorods and nanoneedles, the onset of the latter exhibiting a blue-shift that correlates with the widening of band gap with nanoneedle formation.

Systematic study of the structure-property relationships of branched hierarchical TiO2/ZnO nanostructures.

We report a simple and effective route for fabricating branched hierarchical nanostructures of TiO(2)/ZnO by combining electrospinning and the low-temperature hydrothermal growth technique. First, TiO(2) nanofibers were prepared by electrospinning polystyrene (PS)/titanium tetraisopropoxide (Ti(OiPr)(4)) solutions onto glass substrates followed by calcination at 500 °C. The electrospun TiO(2) nanofibers served as a 3D primary platform upon which the branched, highly uniform, and dense secondary ZnO nanorods were hydrothermally grown. We observed that the concentration of Ti(OiPr)(4) in the polystyrene solution has a significant effect on the surface roughness and areal material ratio of the electrospun fibers. Most significantly, the morphology of the branched secondary ZnO nanorods and the overall charge transfer capacity of the nanoheterostructured systems are controlled by the density of the TiO(2) platform. This study demonstrates that, by properly choosing the synthesis parameters, it is possible to fine-tune the microscopic and macroscopic properties of branched hierarchical metal-oxide systems. The presented approach can be applied to the development of controlled, reproducible, miniaturized, and robust high-performance metal-oxide photovoltaic and photocatalytic systems.