Improving the ultraviolet protection factor of textiles through mechanical surface modification using calendering

The textile modification technique of calendering was used to change the cover factor of wearable textiles in order to improve the ultraviolet protection factor and decrease the amount of ultraviolet radiation transmitted through the fabric. Using optical microscopy and ultraviolet spectrophotometry, the quantifiable changes that occurred after repeated passes through the calender were measured. It was found that after one pass the uncovered area decreased by a factor of two and the ultraviolet protection factor increased by 200%. The thickness and air permeability of treated fabric decreased with repeated calendering. The bending stiffness remained nearly unchanged, and thus the mechanical properties were not altered substantially by the fabric compression.

Preparation of Multifunctional Plasma Cured Cellulose Fibers Coated with Photo-Induced Nanocomposite toward Self-Cleaning and Antibacterial Textiles

Multifunctional fibrous surfaces with ultraviolet protection, self-cleaning, or antibacterial activity have been highly attractive. Nanocomposites consisting of silver (AgNPs) and titanium dioxide (TiO2 NPs) nanoparticles (Ag/TiO2) were developed and coated onto the surface of viscose fibers employing a straightforward pad–dry–cure procedure. The morphologies and elemental compositions were evaluated by scan electron microscopy (SEM), infrared spectra (FTIR), and energy-dispersion X-ray spectra (EDS). The resultant multifunctional textile materials displayed antibacterial and photo-induced catalytic properties. The photocatalyzed self-cleaning properties were investigated employing the photochemical decay of methylthioninium chloride, whereas the antibacterial properties were studied versus E. coli. The viscose fibers coated with Ag/TiO2 nanocomposite demonstrated improved efficiency compared with viscose fibers coated with pure anatase TiO2 nano-scaled particles.

Rational Construction of Superhydrophobic PDMS/PTW@cotton Fabric for Efficient UV/NIR Light Shielding

Passive daytime radiative cooling (PDRC) material has intrigued increasing attentions with its energy saving potential and smart cloth feature. In this work, PDRC cotton fabric with superhydrophobicity, ultraviolet protection and self-cleaning competency was successful constructed through the deposition chemically-stable potassium titanate whiskers (PTW) and polydimethylsiloxane (PDMS) onto cotton fibers. While featured with ultra-high contact angle of 151.9±0.9 °, the synthesized fabric marked an average temperature drop of ~5.1 ℃, bestowed to its high sunlight reflectivity of 83 % and infrared emissivity of nearly 90 %. On the other hand, real human tests further confirmed the practicality of the modified cotton fabric, with the recorded temperature drops ranged from 3.1~4.7 ℃ under direct sunlight. Such performance elucidated a significant improvement upon PTW/PDMS modification, which outperformed that of pristine cotton fabric. Surmising from these, the synthesized superhydrophobic fabric exhibits advantageous techno-economical index with its excellent performance and simple preparation, therefore manifesting limitless application potential, particularly in outdoor clothing and other facilities.

The Influence of Iron Ions on Optical Brighteners and Their Application to Cotton Fabrics

The influence of iron ions at concentrations of 0.2, 0.5, and 1.0 g/L on optical brighteners of the groups stilbene and biphenyl in solution and on cotton fabric was investigated. Both groups of optical brighteners are intended for detergent formulations. The influence of iron ions was studied by absorption and fluorescence spectra in solution and by whiteness degree, identifying color differences using CIEL*a*b* coordinates and Ultraviolet Protection Factor (UPF) of cotton fabrics. The obtained results in solutions and cotton fabrics showed different behavior of optical brighteners stilbene and biphenyl in the presence of iron. Stilbene compounds with metal ions produced new species capable of absorbing in the UV-B region of the spectrum. A biphenyl compound in combination with iron had no effect on the absorption properties. Both optical brighteners were influenced by iron ions in the sense of fluorescence quenching. The influence of iron ions in single- and two-bath treatments of cotton fabrics after one cycle on whiteness degree and UPF was negligible.