Shah Huda scite author profile

Ten popular disperse dyes with different energy levels and chemical constitutions were used to compare their exhaustion, color yield, and colorfastness on polylactide (PLA) and poly(ethylene terephthalate) (PET). Only two out of the 10 dyes had exhaustions higher than 80% on PLA at 2% owf. Five out of the 10 dyes had exhaustions less than 50%. All 10 dyes had more than 90% exhaustion on PET, whereas six of them had exhaustions of 98% or higher. There was no obvious pattern as for which energy level or which structure class provided dye exhaustion better than that of others. Although PLA had lower disperse dye exhaustion than that of PET, it had higher color yield. Based on the 10 dyes examined, the color yield of PLA was about 30% higher than that of PET. This means that even with low dye uptake, PLA could have a similar apparent shade depth as that of PET if the same dyeing conditions are applied. Our study supported that the lower reflectance, or reflectivity, of PLA contributes to the higher color yield of PLA than that of PET. A quantitative relation between the shade depth of PLA and PET based on their dye sorption was developed. Disperse dyes examined had lower washing and crocking fastness on PLA than on PET. The differences in class were about 0.5 to 1.0. If the comparison was based on the same dye uptake, the differences might be larger. The differences in light fastness between the two fibers were smaller than that in washing and crocking fastnesses. The light fastness of disperse dyes on PLA is expected to be even better if the comparison is based on the same dye uptake on both fibers.

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Feather Fiber Reinforced Light-Weight Composites with Good Acoustic Properties

Huda

Yang

2009

J Polym Environ

110

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Lightweight composites from long wheat straw and polypropylene web

Zou

Huda

Yang

2010

Bioresource Technology

103

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Chemically Extracted Cornhusk Fibers as Reinforcement in Light‐Weight Poly(propylene) Composites

Huda

Yang

2008

Macro Materials & Eng

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Flexural, impact resistance, tensile, and sound absorption properties of composites from cornhusk fiber (CHF) and PP have been investigated. The effect of holding temperature, CHF length, CHF concentration, and enzyme treatment of CHF on mechanical properties and the effect of the latter two on sound absorption have been studied. Compared with jute/PP composites, CHF/PP composites have similar impact resistance, 33% higher flexural strength, 71% lower flexural modulus, 43% higher tensile strength, 54% lower tensile modulus, and slightly higher noise reduction coefficient. Enzyme treatment of CHF results in increased mechanical and sound absorption properties.

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Shah Huda

Composites from ground chicken quill and polypropylene

Comparison of disperse dye exhaustion, color yield, and colorfastness between polylactide and poly(ethylene terephthalate)

Feather Fiber Reinforced Light-Weight Composites with Good Acoustic Properties

Lightweight composites from long wheat straw and polypropylene web

Chemically Extracted Cornhusk Fibers as Reinforcement in Light‐Weight Poly(propylene) Composites

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