Modification and Application of Dye Extract from Tectona Grandis on Cotton Fabric
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10.58578/ajstm.v1i1.3362
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Abstract
The natural dye was extracted from Tectona grandis using a soxhlet extractor, and a percentage yield of 16.84% was obtained. The color of the dye extract is maroon, and after the dye extract was modified, the color changed to brown. The modified dye was characterized using FTIR, AMF, and UV-visible spectroscopy. The results of the FTIR suggested the presence of C-H, C=C, C=O, N-H, C-O-C, C-Cl, and C-Br functional groups. The AFM suggests that the area roughness is 629.9 nm in the 25μm×25μm scan area. The UV shows a maximum wavelength of 581 nm with an absorbance of 0.074. The chromophore of the modified dye extract is -N=N- and C=O. The modified dye was applied to the cotton fabrics. The color fastness to washing shows that 3–4 and 4 were experienced for color change and staining, respectively, while the color fastness to rubbing shows that 4-5 and 4 were experienced for dry and wet rubbing, respectively. The outcome of color fastness shows that the modified dye has a good affinity to remain on the fabric. We therefore recommend the use of different kinds of mordants to improve the affinity of cotton fabric.
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References
Merdan, N., Eyupoglu, S. & Duman, M.N. (2017). Ecological and Sustainable Natural Dyes. In: Muthu, S. (eds) Textiles and Clothing Sustainability. Textile Science and Clothing Technology. Springer, Singapore. https://doi.org/10.1007/978-981-10-2185-5_1
Adeel, S., Rehman, FU., Rafi, S., Zia, K.M. & Zuber, M. (2019). Environmentally Friendly Plant-Based Natural Dyes: Extraction Methodology and Applications. In: Ozturk, M., Hakeem, K. (eds) Plant and Human Health, 2. Springer, Cham. 2, 383–415.
Mehta, M., Sharma, M. & Pathania, K. (2021). Degradation of synthetic dyes using nanoparticles: a mini-review. Environment Science Pollution Resources, 28, 49434– 49446
Kulkarni SS, Gokhale AV, Bodake UM, Pathade GR. (2011) Cotton dyeing with Natural Dye Extracted from Pomegranate, Journal of Environmental Research and Technology. 1(2):135-139.
Joshua, Y., Atoshi, M. A., Japhet, A. T., & Efu, (2023) A. Production and Testing of Baphia Ntida Stem Dye on Cotton Fabric. Nigerian Research Journal of Chemical Sciences (ISSN:2682-6054) Volume 11, Issue 2
Rather, L. J., Zhou, Q., Ali, A., Haque, Q. M. R., & Li, Q. (2020). Valorization of natural dyes extracted from Mugwort leaves (Folium artemisiae argyi) for wool fabric yeing optimization of extraction and dyeing processes with simultaneous coloration and biofunctionalization.
Taleb, F., Ammar, M., Mosbah, M. B., Salem, R. B., & Moussaoui, Y. (2020). Chemical modification of lignin derived from spent coffee grounds for methylene blue adsorption. Scientific Reports, 10(1), 11048.
Sannapapamma, K. J., Naikwadi, S., Bhairappanavar, D., Patil, R., & Aladakatti, Y. R. (2022). Effect of scouring and laundering on functional properties of natural colour cotton fabric. Environment Conservation Journal, 23(1&2), 143-153.
Liu, X., Yue, O., Wang, X., Hou, M., Zheng, M., & Jiang, H. (2020). Preparation and application of a novel biomass-based amphoteric retanning agent with the function of reducing free formaldehyde in leather. Journal of Cleaner Production, 265, 121796.
Karabulut, K., & Atav, R. (2020). Dyeing of cotton fabric with natural dyes without mordant usage part I: Determining the most suitable dye plants for dyeing and UV protective functionalization. Fibers and Polymers, 21, 1773-1782.
Geetam, R., Anil, K., Perapong, T. & Bhupendra, G. (2017). Natural dyes for dye sensitized solar cell: A review, Renewable and Sustainable Energy Reviews, Elsevier, 69, 705- 718
Samanta, A.K. & Agarwal, P.(2020). Application of natural dyes on textiles. ReviewArticle.Fibre Text Res. 34, 384-399.
Hassan, M. M. (2023). Valorization of Sulfonated Kraft Lignin as a Natural Dye for the Sustainable Dyeing of Wool Fabrics: Effect of Peroxide Oxidation. ACS Sustainable Chemistry & Engineering, 11(37), 13787-13797.
Sanda, B., & Liliana, I. (2021). Natural dye extraction and dyeing of different fibers: a review.Innovative and Emerging Technologies for Textile Dyeing and Finishing, 113-135.
da Conceição, L. R. B., da Cunha, H. O., Leite, A. M. B., Suresh Babu, R., Raja, S., Ribeiro, C., & de Barros, A. L. F. (2023). eval__uation of solar conversion efficiency in dye-sensitized solar cells using natural dyes extracted from alpinia purpurata and alstroemeria flower petals as novel photosensitizers.Colorants, 2(4), 618-631.
Pandey, D., Daverey, A., Dutta, K., & Arunachalam, K. (2023). Dye removal from simulated and real textile effluent using laccase immobilized on pine needle biochar. Journal of Water Process Engineering, 53, 103710.
Fried, R., Oprea, I., Fleck, K., & Rudroff, F. (2022). Biogenic colourants in the textile industry–a promising and sustainable alternative to synthetic dyes.Green Chemistry,24(1), 13-35.
Khattab, T. A., Abdelrahman, M. S., & Rehan, M. (2020). Textile dyeing industry: environmental impacts and remediation. Environmental Science and Pollution Research, 27, 3803-3818.
Otutu, J.O., Osabohien, E. & Efurhievwe, E.M. (2012). Extraction of natural dyes for textile dyeing from the by-product of the timber industry. Bioscience, biotechnology research Asia. 7(1), 87-92.
Periyasamy, A. P. (2022). Natural dyeing of cellulose fibers using syzygium cumini fruit extracts and a bio-mordant: A step toward sustainable dyeing. Sustainable Materials and Technologies, 33, e00472.
