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International Design Journal
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Volume Volume 15 (2025)
Issue Issue 3
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Kamel, S. (2025). Enhancing the Softness of Bamboo Fabric as a Sustainable Material through Silicon-Based Modifications". International Design Journal, 15(3), 489-499. doi: 10.21608/idj.2025.365188.1280
Shaimaa A Kamel. "Enhancing the Softness of Bamboo Fabric as a Sustainable Material through Silicon-Based Modifications"". International Design Journal, 15, 3, 2025, 489-499. doi: 10.21608/idj.2025.365188.1280
Kamel, S. (2025). 'Enhancing the Softness of Bamboo Fabric as a Sustainable Material through Silicon-Based Modifications"', International Design Journal, 15(3), pp. 489-499. doi: 10.21608/idj.2025.365188.1280
Kamel, S. Enhancing the Softness of Bamboo Fabric as a Sustainable Material through Silicon-Based Modifications". International Design Journal, 2025; 15(3): 489-499. doi: 10.21608/idj.2025.365188.1280

Enhancing the Softness of Bamboo Fabric as a Sustainable Material through Silicon-Based Modifications"

Article 36, Volume 15, Issue 3, May and June 2025, Page 489-499  XML PDF (394.26 K)
Document Type: Original Article
DOI: 10.21608/idj.2025.365188.1280
View on SCiNiTO View on SCiNiTO
Author
Shaimaa A Kamel email
Faculty of Applied Arts - Tanta university
Abstract
As global resource demands increase and the severe impacts of our ongoing dependence on fossil fuels become increasingly evident, there is a growing emphasis on sustainable, nature-based solutions to address the complex environmental challenges our planet faces. 1-2
The world is continually exploring and adopting innovative materials, with an increasing preference for eco-friendly products. One standout option among these sustainable materials is bamboo, known for being the fastest-growing woody plant on Earth3. This renewable resource is extensively cultivated across Asia and serves as the foundation for a wide variety of functional and decorative items. 4
This paper examines the properties and ecological benefits of bamboo fiber. Regenerated bamboo fibers, recognized for their high cellulose content, have gained significant popularity in the market, positioning bamboo as a fashionable and durable eco-friendly material for construction. Due to its exceptional properties, bamboo fiber is widely used to produce yarns and textiles5. These fibers are incorporated into a diverse range of products, including apparel such as underwear, activewear, t-shirts, and socks, as well as personal care items like sanitary pads, and are utilized in various sectors such as healthcare, military, industry, home decor, and furnishings.1-6
Keywords
bamboo; sustain; softeners compounds; PDMS
Supplementary Files
download 489-499-Kamal-abs.pdf
References

1-   Amjad AI. Bamboo fibre: A sustainable solution for textile manufacturing. Adv Bamboo Sci. 2024;7:100088. doi:10.1016/J.BAMBOO.2024.100088

2-   Liu D, Song J, Anderson DP, Chang PR, Hua Y. Bamboo fiber and its reinforced composites: Structure and properties. Cellulose. 2012;19(5):1449-1480. doi:10.1007/s10570-012-9741-1

3-   Barrile V, Genovese E. Bamboo structures: Innovative methods and applications for structural health monitoring and dissemination. Adv Bamboo Sci. 2024;7. doi:10.1016/J.BAMBOO.2024.100079

4-   Innes JL, Dai C. Future uses of bamboo. Adv Bamboo Sci. 2024;8:100103. doi:10.1016/J.BAMBOO.2024.100103

5-   do Amaral LM, Kadivar M, Paes JB, et al. Physical, mechanical, chemical, and durability assessment of water leaching treatment of bamboo. Adv Bamboo Sci. 2023;5. doi:10.1016/J.BAMBOO.2023.100040

6-   Afrin T, Tsuzuki T, Kanwar RK, Wang X. The origin of the antibacterial property of bamboo. J Text Inst. 2012;103(8):844-849. doi:10.1080/00405000.2011.614742

7-   Azeez MA, Orege JI, Azeez MA, Orege JI. Bamboo, Its Chemical Modification and Products. Bamboo - Curr Futur Prospect. Published online 30 May 2018. doi:10.5772/INTECHOPEN.76359

8-   Benton A. Priority Species of Bamboo. Published online 2015:31-41. doi:10.1007/978-3-319-14133-6_2

9-     Bal LM, Singhal P, Satya S, Naik SN, Kar A. Bamboo shoot preservation for enhancing its business potential and local economy: a review. Crit Rev Food Sci Nutr. 2012;52(9):804-814. doi:10.1080/10408398.2010.511321

10-  Amjad AI. Bamboo fibre: A sustainable solution for textile manufacturing. Adv Bamboo Sci. 2024;7. doi:10.1016/J.BAMBOO.2024.100088

11-  Altieri D, Molari L. Bamboo Scaffolding as a European Promising Opportunity: A Structural Feasibility Study. Sustain. 2024;16(2). doi:10.3390/SU16020915

12-  Akinlabi ET, Anane-Fenin K, Akwada DR. Bamboo: The multipurpose plant. Bamboo Multipurp Plant. Published online 24 July 2017:1-262. doi:10.1007/978-3-319-56808-9

13-  Acharya B, Behera A, Sahu PK, et al. Bamboo shoots: an exploration into its culinary heritage in India and its nutraceutical potential. J Ethn Foods. 2023;10(1). doi:10.1186/S42779-023-00190-7

14-  Wang Y, Chen J, Wang D, et al. A systematic review on the composition, storage, processing of bamboo shoots: Focusing the nutritional and functional benefits. J Funct Foods. 2020;71. doi:10.1016/J.JFF.2020.104015

15-  Patel HR, Mathakia R, Mangroliya UC, Mandaliya VB. Sustainable bamboo: Technological innovations and patent insights for a greener future. Adv Bamboo Sci. 2025;10:100127. doi:10.1016/J.BAMBOO.2025.100127

16-  Afrin T, Tsuzuki T, Kanwar RK, Wang X. The origin of the antibacterial property of bamboo. J Text Inst. 2012;103(8):844-849. doi:10.1080/00405000.2011.614742

17-  Prang Rocky B, Thompson AJ. Investigation and comparison of antibacterial property of bamboo plants, natural bamboo fibers and commercial bamboo viscose textiles. J Text Inst. 2021;112(7):1159-1170. doi:10.1080/00405000.2020.1807300

18-  Ali M, Mahmood AH, Hussain S, Ahmed F. An Investigation into the Antibacterial Properties of Bamboo/Cotton Blended Fabric and Potential Limitations of the Test Method AATCC 147. J Nat Fibers. 2021;18(1):51-58. doi:10.1080/15440478.2019.1612305

19-  Divya D, Indran S, Bharath KN. Bamboo: A Potential Natural Material for Bio-composites. Bamboo Fiber Compos. Published online 2021:15-37. doi:10.1007/978-981-15-8489-3_2

20-  Akinlabi ET, Anane-Fenin K, Akwada DR. Bamboo: The multipurpose plant. Bamboo Multipurp Plant. Published online 24 July 2017:1-262. doi:10.1007/978-3-319-56808-9/COVER

21-  Chruściel JJ. Modifications of Textile Materials with Functional Silanes, Liquid Silicone Softeners, and Silicone Rubbers—A Review. Polymers (Basel). 2022;14(20):4382. doi:10.3390/POLYM14204382

22-  (PDF) Review of silicon-based materials for cellulosic fabrics with functional applications. Accessed March 3, 2025. https://www.researchgate.net/publication/337867938_Review_of_silicon-based_materials_for_cellulosic_fabrics_with_functional_applications

23-  Hassabo A, Mohamed A. Review of silicon-based materials for cellulosic fabrics with functional applications. J Text Color Polym Sci. 2019;0(0):0-0. doi:10.21608/JTCPS.2019.18580.1030

24-  jang-yeh-1993-effects-of-silicone-softeners-and-silane-coupling-agents-on-the-performance-properties-of-cotton-fabrics (1).pdf.

25-  Jang KO, Yeh K. Effects of Silicone Softeners and Silane Coupling Agents on the Performance Properties of Cotton Fabrics. Text Res J. 1993;63(10):557-565. doi:10.1177/004051759306301001

26-  Artikboeva R, Wu Y, Yang M, et al. Preparation and Application of the Hydrophilic Amino-Silicone Softener by Emulsion Polymerization. Adv Chem Eng Sci. 2019;10(1):1-23. doi:10.4236/ACES.2020.101001

27-  Softeners in textile processing. Part 1: An overview†. Accessed March 3, 2025. https://www.researchgate.net/publication/229679703_Softeners_in_textile_processing_Part_1_An_overview

28-  Effect of Structures and Concentrations of Softeners on the Performance Properties and Durability to Laundering of Cotton Fabrics | Request PDF. Accessed March 3, 2025. https://www.researchgate.net/publication/231375574_Effect_of_Structures_and_Concentrations_of_Softeners_on_the_Performance_Properties_and_Durability_to_Laundering_of_Cotton_Fabrics

29-  Reddy N, Salam A, Yang Y. Effect of structures and concentrations of softeners on the performance properties and durability to laundering of cotton fabrics. Ind Eng Chem Res. 2008;47(8):2502-2510. doi:10.1021/IE071564F

30-  Siddique A, Hassan T, Abid S, et al. The Effect of Softeners Applications on Moisture Management Properties of Polyester/Cotton Blended Sandwich Weft-Knitted Fabric Structure. Coatings 2021, Vol 11, Page 575. 2021;11(5):575. doi:10.3390/COATINGS11050575

31-  Synthesis-of-Silicone-oil-and-Application-on-Knit-and-Woven-Cotton-Dyed-Fabrics.pdf.

32-  Zieba M, Małysa A, Wasilewski T, Ogorzałek M. Effects of chemical structure of silicone polyethers used as fabric softener additives on selected utility properties of cotton fabric. Autex Res J. 2019;19(1):1-7. doi:10.1515/AUT-2018-0009/MACHINEREADABLECITATION/RIS

33-  Peng W, Qian Y, Zhou T, Yang S, Jin J, Li G. Influence of Incorporated Polydimethylsiloxane on Properties of PA66 Fiber and Its Fabric Performance. Polym 2019, Vol 11, Page 1735. 2019;11(11):1735. doi:10.3390/POLYM11111735

34-  Silicone softeners for stain repellent and stain release fabric finishing - Fibre2Fashion. Accessed March 3, 2025. https://www.fibre2fashion.com/industry-article/2874/silicone-softeners-for-stain-repellent-and-stain-release-fabric-finishing

35-  Effect of silicone nano-emulsion softener on physical properties of cotton fabric | Request PDF. Accessed March 3, 2025. https://www.researchgate.net/publication/279654779_Effect_of_silicone_nano-emulsion_softener_on_physical_properties_of_cotton_fabric

36-  (PDF) Effect of nano-silicone softener on abrasion and pilling resistance and color fastness of knitted fabrics. Accessed March 3, 2025. https://www.researchgate.net/publication/286889258_Effect_of_nano-silicone_softener_on_abrasion_and_pilling_resistance_and_color_fastness_of_knitted_fabrics

37-  Zieba M, Małysa A, Wasilewski T, Ogorzałek M. Effects of chemical structure of silicone polyethers used as fabric softener additives on selected utility properties of cotton fabric. Autex Res J. 2019;19(1):1-7. doi:10.1515/AUT-2018-0009

38-  Wan H, Ye Y, Chen L, Chen J, Zhou H. Influence of Polyfluo-Wax on the Friction and Wear Behavior of Polyimide/Epoxy Resin–Molybdenum Disulfide Bonded Solid Lubricant Coating. Tribol Trans. 2016;59(5):889-895. doi:10.1080/10402004.2015.1118585

39-  Zia KM, Tabassum S, Barkaat-ul-Hasin S, Zuber M, Jamil T, Jamal MA. Preparation of rich handles soft cellulosic fabric using amino silicone based softener. Part-I: Surface smoothness and softness properties. Int J Biol Macromol. 2011;48(3):482-487. doi:10.1016/J.IJBIOMAC.2011.01.011

40-  Graiver D, Farminer KW, Narayan R. A Review of the Fate and Effects of Silicones in the Environment. J Polym Environ. 2003;11(4):129-136. doi:10.1023/A:1026056129717/METRICS

41-  (PDF) INFLUENCE OF THE FABRIC PROPERTIES ON FABRIC STIFFNESS FOR THE INDUSTRIAL FABRICS. Accessed March 4, 2025. https://www.researchgate.net/publication/267233556_INFLUENCE_OF_THE_FABRIC_PROPERTIES_ON_FABRIC_STIFFNESS_FOR_THE_INDUSTRIAL_FABRICS

42-  Seddik KM, Ali MA. Characterization of cotton woven compression bandages with different structures. Res J Text Appar. 2023;ahead-of-print(ahead-of-print). doi:10.1108/RJTA-07-2023-0077/FULL/PDF

43-  Effect of silicone nano-emulsion softener on physical properties of cotton fabric | Request PDF. Accessed March 4, 2025. https://www.researchgate.net/publication/279654779_Effect_of_silicone_nano-emulsion_softener_on_physical_properties_of_cotton_fabric

44-  Gupta P, Datta Roy M, Ghosh S. Effect of finishing chemicals on tearing strength of plain-woven cotton fabric. Res J Text Appar. 2020;24(3):229-243. doi:10.1108/RJTA-09-2019-0043

45-  Chowdhury KP. Performance Evaluation of Water Repellent Finishes   on Cotton Fabrics. Int J Text Sci. 2018;7(2):48-64. doi:10.5923/J.TEXTILE.20180702.03

46-  Hoefnagels HF, Wu D, De With G, Ming W. Biomimetic superhydrophobic and highly oleophobic cotton textiles. Langmuir. 2007;23(26):13158-13163. doi:10.1021/LA702174X

Vilčnik A, Jerman I, Vuk AŠ, et al. Structural properties and antibacterial effects of hydrophobic and oleophobic sol-gel coatings for cotton fabrics. Langmuir. 2009;25(10):5869-5880. doi:10.1021/LA803742C/SUPPL_FILE/LA803742C_S

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