The influence of the main elemental constituents of thousand year old barai mud extension of shades of natural dyed silk from marigold flowers

Authors

  • Chuleekant Sainate Department of Chemistry, Faculty of Science, Buriram Rajabhat University, Buriram, 31000 Thailand

DOI:

https://doi.org/10.55674/cs.v16i2.253499

Keywords:

Flavonoids; Bankhokmuang, Natural dyes, Prasat Muang Tam, Kuti Ruesi

Abstract

This research aimed (1) to study the main element of thousand year old mud and types of color-giving substances from marigold flowers and (2) to study the causes of silk color change from dark yellow to dark green at Bankhokmuang, Chorakhemark Sub-district, Prakhonchai District, Buriram Province. Firstly, the researcher studied the element of the mud from Barai Prasat Muang Tam and Barai Kuti Ruesi, using EDXRF. Secondly, the researcher studied types of phytochemicals in marigold extract using HCl solution and NaOH solution. Finally, the researcher dyed the silk with marigold flower extract mixed with alum and dyed it with iron ion solution and the mud solution from both sources. The results showed that both muds had the highest amount of Fe2O3, 64.03% of Barai Prasat Muang Tam mud and 44.22% of Barai Kuti Ruesi mud. The coloring substance of marigold extract was flavonoids and had good water solubility. Then the researcher dyed the silk with marigold flower extract mixed with alum because alum contained Al3+ions. The silk was dark yellow. The silk was divided into three groups to be dyed again. The first group was dyed with 1,000 ppm iron ion solution. The second group was dyed with a solution of Barai Prasat Muang Tam mud. The third group was dyed with a solution of Barai Kuti Ruesi mud. All group color changed from dark yellow to dark green. Thus, iron ion solution and both of Barai mud solution were rich in iron ion. This complex compound could form with flavonoids which made golden yellow color turns dark green and sticks to silk threads. It was also water insolubility. The color was not faded. All groups had different shade values at the significance level of 0.05.

GRAPHICAL ABSTRACT

submission_253499_22968_coverImage_en_US.jpg

HIGHLIGHTS

  • Study the main element of thousand year old mud

  • Study area at at Bankhokmuang, Chorakhemark Sub-district, Prakhonchai District, Buriram Province.
  • Causes the color of the silk thread to change from yellow to dark green

References

T.P. Nguyen, Q.V. Nguyen, V.H. Nguyen, T.H. Le, V.Q.N. Huynh, D.V.N. Vo, Q.T. Trinh, S.Y. Kim, Q.V. Le, Silk fibroin-based biomaterials for biomedical applications: a review, polymers. 11(12) (2019) 1 - 25.

J. Saha, Md.I.H. Mondal, Md.R.K. Sheikh, Md.A. Habib, Extraction, Structural and functional properties of silk sericin biopolymer from bombyx mori silk cocoon waste, J. text. sci. eng. 9(1) (2019) 1 – 5.

I.M. Badawy, B.A. Ali, W.A. Abbas, N.K. Allam, Natural silk for energy and sensing applications: a review, Environ. Chem. Lett. 19(3) (2021) 2141 – 2155.

N. Johari, A. Khodaei, A. Samadikuchaksaraei, R.L. Reis, Subhas C. Kundud, Lorenzo Moroni, Ancient fibrous biomaterials from silkworm protein fibroin and spider silk blends: Biomechanical patterns, Acta. Biomater. 153(2022) (2022) 38 – 67.

M. Aparna, N. Goutham, Mud Dyeing and Printing Technique on Sustainable Fabrics, Int. j. creat.res. Thoughts. 11(5) (2023) 336 – 342.

S. Borah, P.M. Bhuyan, B. Sarma, S. Hazarika, A. Gogoi, P. Gogoi, Sustainable dyeing of mulberry silk fabric using extracts of green tea (Camellia sinensis): Extraction, mordanting, dyed silk fabric properties and silk-dye interaction mechanism. Ind Crops Prod IND CROP PROD. 205(1) (2023) 117517. https://doi.org/10.1016/j.indcrop.2023.117517

B. Pizzicato, S. Pacifico, D. Cayuela, G. Mijas, M. Riba-Moliner, Advancements in Sustainable Natural Dyes for Textile Applications: A Review, Molecules 28(16) (2023) 1 – 22.

P.S. Kumarmath, A. Kawatal, K. Nimbargi, A Review On Extraction Of Dye From Terminalia catappa Hull: A Substitute To Synthetic Dyes, JETIR. 9(2) (2022) e59 - e64.

Natural Dyes: Application,Identification and Standardization, https://primastoria.files.wordpress.com/2014/09/natdyes-identification1.pdf, 24 September 2022

R. Satpathy, R. Behera, C. Padhi, Dyeplantdb: a database of dye yielding plants, Agrica. 8(1) (2019) 37 - 40.

N.A.F.Md. Fadzli, W.S. Ruznan, S.A. Suhaimi, M.R.A.M.I.A. Kadir, M.A.M. Nor, S. Ariffin, Colourfastness properties of natural dye from tagetes erecta on silk fabric using different dyeing techniques, J. acad. 9(1) (2021) 166 - 172.

A. Lohar, J. Majumder, Silk dyeing with natural dye extracted from floral parts of African marigold (Tagetes erecta L.) and its fastness, J Pharm Innov. 8(3) (2019) 517 - 520.

P. Chitichotpanya, N. Vuthiganond, T. Inprasit, B. Klaykruayat, S. Srisuk, Extraction of lutein dye from Tagetes erecta garland waste for green dyeing of hemp fabric using response surface methodology, JMMM. 32(4) (2022) 47 - 58.

Prasat Muang tum, https://www.google.co.th/intl/th/earth/, 27 October 2022.

Kuti Ruesi Bankhokmuang, http://www.m-culture.in.th/album/157510/, 27 October 2022.

P. Panchal, N. Parvez, Phytochemical analysis of medicinal herb (Ocimum sanctum), Int. j. nanomater. nanotechnol. nanomedicine. 5(2) (2019) 008 - 011.

A.V. Kurkina, A.E. Savel’eva, V.A. Kurkin, Quantitative determination of total flavonoids in Tagetes patula marigold flowers, Pharm. Chem. J. 55(2) (2021) 46 - 50.

E. Rodríguez-Arce, M. Saldías, Antioxidant properties of flavonoid metal complexes and their potential inclusion in the development of novel strategies for the treatment against neurodegenerative diseases, Biomed. Pharmacother. 143(4) (2021) 1 - 9.

O. Deveoglu, R. Karadag, A. Spinella, E.T. Guzel, Examination of dyeing properties on silk of some flavonoids by spectroscopic techniques, J. Nat. Fibers.18(2) (2019) 1 - 12.

S. Manyim, A.K. Kiprop, J.I. Mwasiagi, A.C. Mecha, Eco-friendly dyeing of pretreated cotton fabric using a natural dye extract from Erythrina abyssinica, J. Nat. Fibers. 19(14) (2021) 1 - 13.

T. Hutakamol, P. Pisitsak, S. Thongmee, S. Srijanand, T. Somrus, Enhancing the color shade and depth of linen fabrics dyed with Caesalpinia sappan L. wood extract using metallic salt mordants, JMMM. 33(3) (2023) 1 - 9.

J. Saha, Md.I.H. Mondal, Md.R.K. Sheikh, Md.A. Habib, Extraction, Structural and functional properties of silk sericin biopolymer from bombyx mori silk cocoon waste, J Textile Sci Eng. 9(1) (2019) 1 - 6.

Y. Zhou, R.C. Tang, T. Xing, J.P. Guan, Z.H. Shen, A.D. Zhai, Flavonoids-metal salts combination: a facile and efficient route for enhancing the flame retardancy of silk, Ind Crops Prod. 130(2019) (2019) 580 - 591.

T. Hobanthad, Extraction of sericin from Thai native silk (Nangsew) yarn using mulberry (cv. Buriram 60) leaves extracts as a greener solvent, SNRUJST. 10(3) (2018) 156 - 164.

Downloads

Published

2024-05-01

How to Cite

Sainate, C. (2024). The influence of the main elemental constituents of thousand year old barai mud extension of shades of natural dyed silk from marigold flowers . Creative Science, 16(2), 253449. https://doi.org/10.55674/cs.v16i2.253499

Issue

Vol. 16 No. 2 (2024): Creative Science (May - August 2024)

Section

Research Article

Categories

License

Copyright (c) 2024 Creative Science

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.