Thermogravimetric Analysis of Biocomposites Based on Yucca gloriosa Modified with Organic Compounds
Vol. 6 No. 4 (2024), ARTICLES
Vol. 6 No. 4 (2024)

Thermogravimetric Analysis of Biocomposites Based on Yucca gloriosa Modified with Organic Compounds

ARTICLES
https://doi.org/10.52340/gs.2024.06.04.44
Published 2024-12-16
Mariam Mtchedlishvili
Sokhumi State University
Lali Tabatadze
Sokhumi State University
David Gventsadze
Tbilisi State University image/svg+xml
Antonina Mskhiladze
Sokhumi State University
Levan Londaridze
Tbilisi State University image/svg+xml
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Keywords

Environmental Protection
Renewable Raw Materials
Recycled Polymers
Biocomposite
Thermogravimetric Analysis

How to Cite

Mtchedlishvili, M., Tabatadze, L., Gventsadze, D., Mskhiladze, A., & Londaridze, L. (2024). Thermogravimetric Analysis of Biocomposites Based on Yucca gloriosa Modified with Organic Compounds. Georgian Scientists, 6(4), 469–477. https://doi.org/10.52340/gs.2024.06.04.44
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Abstract

In recent years, much attention has been paid to the efficient use of renewable plant materials in industrial and chemical technologies. At the present stage, the use of agricultural and household waste to obtain expensive industrial products is one of the pressing issues of the consumer market. Like other developing countries, Georgia has the opportunity to use local natural raw materials and commercially unsuitable polymer waste to produce various products with different performance properties. The article reviews thermos­gravimetric studies of biomaterials modified with organic silicon and polymer compounds from plant fiber ("Yucca gloriosa"). Several studies of thermal decomposition properties of various biopolymer composites reinforced with natural fibers were conducted. Thermogravimetric analysis (TGA) showed the effect of organic compounds on the thermal stability of the composite material. The modification improved the physical and mechanical properties of the samples.

https://doi.org/10.52340/gs.2024.06.04.44
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References

Nicola Careddu, Giampaolo Siotto, Riccardo Siotto, Caterina Tilocca. From landfill to water, land and life: The creation of the Centre for stone materials aimed at secondary processing. J. Resources Policy, 2013. V. 38(3), P. 258-265.

https://www.sciencedirect.com/science/article/abs/pii/S0301420713000378

Sidamonidze N. N., Tabatadze L. V., Vardiashvili R. O., Nutsubidze M. O., Iremashvili D. J., Chachua E. I., Shengelia N. G. (2023) Hydrosulphurisation Reactions of Allyl Derivatives of Altropyranose with Mercaptans. J. Oxidation Communications, 47(2):337-344.

https://scibulcom.net/en/journal/0209-4541/issue/2023-46-2/

Tabatadze L. V., Sidamonidze N. N., Pirveli N. O., Gakhokidze, R. A. (2005) Synthesis of Certain S-containing Disaccharide derivatives. J. Chemical Natural Compounds. 41(5):592-593

https://doi.org/10.1007/s10600-005-0215-7

Tabatadze L. V., Gakhokidze R. A., Lomtatidze Z Sh., Sidamonidze N. N., Sabauri N. A. (2007) Synthesis and antimicrobial activity of sulfur-containing glycosides. J. Pharmaceutical Chemistry This link is disabled. 41(8):407–408.

Sidamonidze N. N., Tabatadze L. V., Vardiashvili R. O., Nutsubidze M. O., Iremashvili D. J., Chachua E. I., Shengelia N. G. (2023) Hydrosulphurisation Reactions of Allyl Derivatives of Altropyranose with Mercaptans. J. Oxidation Communications, 47(2):337-344. https://scibulcom.net/en/journal/0209-4541/issue/2023-46-2/

Sidamonidze, N.N., Tabatadze, L.V., Vardiashvili, R.O. (2022) Condensation Reactions of 1-Chloro-2,3,4-tri-O-acetyl-ɑ-L-Arabinopyranose and 1-Chloro-2,3,4-tri-O-acetyl-ɑ-L-Rhamnopyranose with α-Pyrrolidone and ε-Caprolactame. Oxidation Communications. 45(4), 628–634.

https://scibulcom.net/en/article/iDO5QnqHP0kPfatsbXE1

Sidamonidze, N.N., Gakhokidze, R.A., Vardiashvili, R.O., Gelovani, T.D., Tabatadze, L.V. (2023) Synthesis and Biological Activity of some Derivatives of N-Glycosylamines. Oxidation Communications. 46(1), 87–95.

https://scibulcom.net/en/article/68tkrjXr3gCY4TLLSZhI

Ahmed Tara; Mouhja Bencharki; Angelique Gainvors-Claisse; Françoise Bersin; Omar Jbara; Sébastien Rondot. Investigating Degradation in Extrusion-Processed Bio-Based Composites Enhanced with Clay Nanofillers. J. Biomass 2024, 4(3), 658-670;

https://doi.org/10.3390/biomass4030036

Salthammer, T.; Mentese, S.; Marutzky, R. Formaldehyde in the Indoor Environment. Chem Rev. 2010, 110(4), 2536–2572. DOI: 10.1021/cr800399g

Turkadze, Ts.; Gventsadze, D.; Mumladze, T.; Gorgodze, G.; Bochoidze, I. Characterization of Polypropylene Composite Reinforced on Bio-waste from the Production of Tung Oil. Environmental Research, Engineering and Management, 2023, 79(4), 29–38. ISSN: 1392-1649. DOI:10.5755/j01.erem.79.4.33393

N. M. Nurazzi; M. R. M. Asyraf; M. Rayung; M. N. F. Norrrahim; S. S. Shazleen; M. S. A. Rani; A. R. Shafi; H. A. Aisyah; M. H. M. Radzi; F. A. Sabaruddin; R. A. Ilyas; E. S. Zainudin; K. Abdan. Thermogravimetric Analysis Properties of Cellulosic Natural Fiber Polymer Composites: A Review on Influence of Chemical Treatments. Polymers 2021, 13(16), 2710; https://doi.org/10.3390/polym13162710

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