Influence of Anatomy, Microstructure, and Composition of Natural Fibers on the Performance of Thermal Insulation Panels.

The growing interest in environmentally friendly materials is leading to a re-evaluation of natural fibers for industrial applications in order to meet sustainability and low-cost objectives, especially for thermal insulation of buildings. This paper deals with the chemical and physical characterization of fibers extracted from seagrass (Posidonia oceanica) and alfa grass (Stipa tenacissima) for a possible substitution of synthetic materials for thermal insulation. Hemp (Cannabis sativa), a fiber broadly used, was also studied for comparison. The parameters characterized include porosity, thermal degradation, elemental composition, skeletal and particle density of the fibers as well as investigation of the thermal conductivity of fiber-based panels. Several technologies were involved in investigating these parameters, including mercury intrusion, thermogravimetric analysis, fluorescence spectroscopy, and fluid pycnometry. The fibers showed a degradation temperature between 316 and 340 °C for Posidonia, between 292 and 326 °C for alfa, and between 300 and 336 °C for hemp fibers. A high porosity allied with a reduced pore size was revealed for Posidonia (77%, 0.54 µm) compared to hemp (75%, 0.61 µm) and alfa (57%, 2.1 µm) raw fibers, leading to lower thermal conductivity values for the nonwoven panels based on Posidonia (0.0356-0.0392 W/m.K) compared to alfa (0.0365-0.0397 W/m.K) and hemp (0.0387-0.0427 W/m.K). Bulk density, operating temperature, and humidity conditions have been shown to be determining factors for the thermal performance of the panels.

Polyester Fabric with Fluorescent Properties Using Microwave Technology for Anti-Counterfeiting Applications.

The article presented concerns the application of fluorescein as a fluorescent material for anti-counterfeiting technology which will allow the labeling and identification of legitimate articles in the textile field. Fluorescein has been applied to polyester fabrics by microwave irradiation technique in the presence of a UV absorber. Thus, its presence in the textile substrate is detectable following an excitation at a specific wavelength belonging to the Ultra-violet zone, which makes this material very effective for tracking and detecting counterfeit articles. Fluorescent samples are characterized morphologically by scanning electron microscopy (SEM) and quantitatively by optical spectroscopy such as reflectance and transmission measurements. The treated samples show under UV light a yellowish green emission with a slight yellow coloration of the polyester fiber. The UV absorber applied to the fluorescent solution improves the light resistance of the treated samples by 25%. Their addition to the bath can also ensure the production of a protective fabric against UV.

Production, purification, and biochemical characterization of serine alkaline protease from Penicillium chrysogenium strain X5 used as excellent bio-additive for textile processing.

A new ascomycete fungus X5, a hyperproducer (9000 U/mL) of a serine alkaline protease (SAPTEX) was identified as Penicillium chrysogenum. The experimental purification protocol comprises three steps: heat treatment (10 min at 80 °C) followed by an ammonium sulfate precipitation (30-50%)-dialysis, and a UNO Q-12 anion exchange chromatography using the FPLC system. The chemical characterizations performed include physico-chemical determination and spectroscopic analysis. The MALDI-TOF/MS analysis revealed that the purified enzyme was a monomer with a molecular mass of 43,074.11 Da. The 25 residue NH2-terminal sequence of the enzyme showed high homology with Penicillium proteases. The optimum pH and temperature values for protease activity were pH 10 and 80 °C, respectively. Compared to other proteases (SPTC; Flavourzyme® 500 L; Proteinase, type XXIII; Proteinase K; and Alcalase® 2.4 L), SAPTEX has the highest catalytic efficacy, hydrolysis degree, and a powerful stability toward some commercial detergents. According to morphological, physico-chemical [scanning electron microscopy (SEM), energy dispersive X-Ray analysis (EDX), and FTIR-Fourier transform infrared spectroscopy], and mechanical evaluation, SAPTEX has no destructive impact on fibers after the enzyme treatment and a very slight effect on textile support. Obtained results suggested that SAPTEX may be considered as a potential candidate as a protein stain removal product for textile supports.