Carbon nanotubes are man-made one-dimensional carbon crystals with different diameters and chiralities. Owing to their superb mechanical and electrical properties, many potential applications have been proposed for them. However, polydispersity and poor solubility in both aqueous and non-aqueous solution impose a considerable challenge for their separation and assembly, which is required for many applications. Here we report our finding of DNA-assisted dispersion and separation of carbon nanotubes. Bundled single-walled carbon nanotubes are effectively dispersed in water by their sonication in the presence of single-stranded DNA (ssDNA). Optical absorption and fluorescence spectroscopy and atomic force microscopy measurements provide evidence for individually dispersed carbon nanotubes. Molecular modelling suggests that ssDNA can bind to carbon nanotubes through pi-stacking, resulting in helical wrapping to the surface. The binding free energy of ssDNA to carbon nanotubes rivals that of two nanotubes for each other. We also demonstrate that DNA-coated carbon nanotubes can be separated into fractions with different electronic structures by ion-exchange chromatography. This finding links one of the central molecules in biology to a technologically very important nanomaterial, and opens the door to carbon-nanotube-based applications in biotechnology.
Electrospinning is a technique used to produce micron to submicron diameter polymeric
fibers. The surface of electrospun fibers is important when considering end-use applications. For example,
the ability to introduce porous surface features of a known size is required if nanoparticles need to be
deposited on the surface of the fiber or if drug molecules are to be incorporated for controlled release.
Surface features, or pores, became evident when electrospinning in an atmosphere with more than 30%
relative humidity. Increasing humidity causes an increase in the number, diameter, shape, and distribution
of the pores. Increasing the molecular weight of the polystyrene (PS) results in larger, less uniform shaped
pores. This work includes an investigation of how humidity and molecular weight affect the surface of
electrospun PS fibers. The results of varying the humidity and molecular weight on the surface of
electrospun PS fibers were studied using optical microscopy, field emission scanning electron microscopy
(FESEM), and atomic force microscopy (AFM) coupled with image analysis.
Nanocellulose is a biogenerated and biorenewable organic material. Using a process based on 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO)/NaClO/NaBr system, a highly translucent and light-diffusive film consisting of many layers of nanocellulose fibers and wood pulp microfibers was made. The film demonstrates a combination of large optical transmittance of ∼90% and tunable diffuse transmission of up to ∼78% across the visible and near-infrared spectra. The detailed characterizations of the film indicate the combination of high optical transmittance and haze is due to the film's large packing density and microstructured surface. The superior optical properties make the film a translucent light diffuser and applicable for improving the efficiencies of optoelectronic devices such as thin-film silicon solar cells and organic light-emitting devices.
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