An experimental study on production of intelligent textile by using ionocromic materials

Year 2019, , 182 - 188, 15.12.2019

Aslıhan Koruyucu

https://doi.org/10.35860/iarej.526440

Abstract

The
production of an intelligent textile material that changes color under the
influence of pH was researched in this research article. For this purpose,
halochromic dyes were used. In halochromic dyes, bleeding and fastness
problems are encountered after dyeing. In order to solve these problems; the dye is fixed with cationic fixators in the
textile fiber. In this study, a woven nylon fabric was dyed with Alizarin Red S
halochromic dyestuff by conventional dyeing method which was followed by
post-treated by tannic acid/potassium antimony tartarate at different ratios
(1%, 2%, 3%). After dyeing and post-treating, CIELab, K/S, ΔE* values were
measured by spectrophotometer and compared. In order to investigate the effect of halochromics on the post-treated, dyed and post-treated
fabrics were immersed in 5 different solutions prepared by using HCl and NaOH between pH 2 and 10, and the samples
were removed after 1 hour and the color change in the samples was
compared. After the process, the speed of fixation of the dye molecule onto the
fiber was increased.

Corrected by       Aslıhan Koruyucu and Ayben Pakolpakçıl

                             Correction to: An experimental study on production of intelligent textile by using ionochromic materials
                             International Advanced Researches and Engineering Journal 04(01): 056, 2020

                             DOI: 10.35860/iarej.686847

Keywords

Halochromic dyes, pH-indicator, pH-sensor, Textile

References

• 1. Zollinger, H., Color chemistry: syntheses, properties, and applications of organic dyes and pigments. 2003, Switzerland: VHCA and Wiley-VCH, Inc.
• 2. Kim, S.H., editor. 2006, Functional dyes. Elsevier.
• 3. Bamfield, P. and Hutchings M.G., Chromic phenomena: technological applications of colour chemistry. 2010, UK: Royal Society of Chemistry.
• 4. Kirschning, A., Monenschein, H. and Wittenberg, R., Functionalized polymers—emerging versatile tools for solution‐phase chemistry and automated parallel synthesis. Angewandte Chemie International Edition, 2001. 40(4): p. 650-679.
• 5. Vancoillie G., Pelz S., Holder E., Hoogenboom R., Direct nitroxide mediated (co) polymerization of 4-vinylphenylboronic acid as route towards sugar sensors. Polymer Chemistry, 2012. 3(7): p. 1726-1729.
• 6. Pietsch, C., Schubert, U.S., and Hoogenboom, R., Aqueous polymeric sensors based on temperature-induced polymer phase transitions and solvatochromic dyes. Chemical Communications, 2011. 47(31): p. 8750-8765.
• 7. Fournier, D. and Du Prez, F., “Click” chemistry as a promising tool for side-chain functionalization of polyurethanes. Macromolecules, 2008. 41(13): p. 4622-4630.
• 8. Roy, D., Cambre, J.N. and Sumerlin, B.S., Future perspectives and recent advances in stimuli-responsive materials. Progress in Polymer Science, 2010. 35(1-2), p. 278-301.
• 9. De Meyer, T., Hemelsoet, K., Van der Schueren, L., Pauwels, E., De Clerck, K., Van Speybroeck, V., Investigating the halochromic properties of azo dyes in an aqueous environment by using a combined experimental and theoretical approach. Chemistry–A European Journal, 2012. 18(26): p. 8120-8129.
• 10. Makedonski, P., Brandes, M., Grahn, W., Kowalsky, W., Wichern, J., Wiese, S., & Johannes, H.H., Synthesis of new kinds of reactive azo dyes and their application for fibre-optical pH-measurements. Dyes and Pigments, 2004. 61(2): p. 109-119.
• 11. Trupp, S., Alberti, M., Carofiglio, T., Lubian, E., Lehmann, H., Heuermann, R., Yacoub-George, E., Bock, K., and Mohr, G.J., Development of pH-sensitive indicator dyes for the preparation of micro-patterned optical sensor layers. Sensors and Actuators B: Chemical, 2010. 150(1), p. 206-210.
• 12. Kuwabara, T., Nakajima, H., Nanasawa, M. and Ueno, A., Color change indicators for molecules using methyl red-modified cyclodextrins. Analytical Chemistry, 1999. 71(14): p. 2844-2849.
• 13. Van der Schueren, L. and De Clerck, K., The use of pH-indicator dyes for pH-sensitive textile materials. Textile research journal, 2010. 80(7): p. 590-603.
• 14. De Meyer, T., Hemelsoet, K., Van der Schueren, L., Pauwels, E., De Clerck, K. and Van Speybroeck, V., Investigating the halochromic properties of azo dyes in an aqueous environment by using a combined experimental and theoretical approach. Chemistry–A European Journal, 2012. 18(26): p. 8120-8129.
• 15. De Meyer, T., Hemelsoet, K., Van Speybroeck, V. and De Clerck, K., Substituent effects on absorption spectra of pH indicators: An experimental and computational study of sulfonphthaleine dyes. Dyes and Pigments, 2014. 102: p. 241-250.
• 16. Bouas-Laurent, H. and Dürr, H., Organic photochromism (IUPAC technical report). Pure and Applied Chemistry, 2001. 73(4): p. 639-665.
• 17. Schueren, L.V. and Clerck, K.D., The Use of pH-indicator Dyes for pH-sensitive Textile Materials. Textile Research Journal, 2010. 80(7): p. 590-603.
• 18. Staneva, D. and Betcheva, R., Synthesis and Functional Properties of New Optical pH Sensor Based on Benzo [de]anthracen-7-one Immobilized on the Viscose. Dyes and Pigments, 2007. 74(1): p. 148-153.
• 19. De Meyer, T., Steyaert, I., Hemelsoet, K., Hoogenboom, R., Van Speybroeck, V. and De Clerck, K., Halochromic properties of sulfonphthaleine dyes in a textile environment: The influence of substituents. Dyes and Pigments, 2016. 124: p. 249-257.
• 20. Gautam, R.K., Gautam, P.K., Chattopadhyaya, M.C. and Pandey, J.D., Adsorption of Alizarin Red S onto biosorbent of Lantana camara: kinetic, equilibrium modeling and thermodynamic studies. Proceedings of the National Academy of Sciences, India Section A: Physical Sciences, 2014. 84(4): p. 495-504.
• 21. Van der Schueren, L. and De Clerck, K., Coloration and application of pH‐sensitive dyes on textile materials. Coloration Technology, 2012. 128(2): p. 82-90.