Scopus
EXPORT DATE: 15 June 2026
Zhydenko I., Karbovnyk I., Klym H., Chalyy D.
AUTHOR FULL NAMES: Zhydenko, Illia (57210562226); Karbovnyk, Ivan (55911323100); Klym, Halyna (8644170300); Chalyy, Dmytro (55376731000)
57210562226; 55911323100; 8644170300; 55376731000
Thermal Analysis of Polymer Nanocomposites Reinforced with Carbon Nanotubes
(2025) Proceedings of the 2025 IEEE 15th International Conference "Nanomaterials: Applications and Properties", NAP 2025, pp. NS051 - NS054, Cited 0 times.
DOI: 10.1109/NAP68437.2025.11216272
https://www.scopus.com/inward/record.uri?eid=2-s2.0-105023668239&doi=10.1109%2fNAP68437.2025.11216272&partnerID=40&md5=9c8a0c992fb848f615981b9d601e9b42
AFFILIATIONS: Lviv State University of Life Safety, Fire Tactics and Emergency Rescue Work Dpt., Lviv, Ukraine; Ivan Franko National University of Lviv, Radiophysics and Computer Technology Dpt., Lviv, Ukraine; Lviv Polytechnic National University, Specialized Computer Systems Dpt., Lviv, Ukraine
ABSTRACT: The thermal characteristics of refractory nanocomposites embedded with single-walled carbon nanotubes (SWCNTs) were systematically examined utilizing a novel automated analytical approach. This method effectively accentuates the variations in thermal behavior of nanocomposites prepared with different processing parameters, specifically under controlled temperature gradients and applied thermal loads. Such insights are critical for optimizing these materials for integration into sensor technologies and applications demanding superior fire resistance. Experimental results revealed that nanocomposites subjected to a nanotube dispersion duration of two hours exhibited a maximum temperature differential of 55 °C, whereas samples processed with a one-hour dispersion time demonstrated a peak differential of 50 °C. Comparative evaluation of the heat transfer kinetics indicates that prolonging the dispersion time by an additional hour enhances the material's fire resistance by approximately 15%. © 2025 IEEE.
AUTHOR KEYWORDS: fire resistance; nanocomposites; single-walled carbon nanotubes; thermal properties
INDEX KEYWORDS: Dispersions; Heat resistance; Heat transfer; Single-walled carbon nanotubes (SWCN); Thermoanalysis; Thermodynamic properties; Yarn; Analysis of polymers; Analytical approach; Dispersion time; Polymer nanocomposite; Polymer-nanocomposite; Property; Single-walled carbon; Single-walled carbon nanotube; Thermal; Thermal characteristics; Fire resistance; Nanocomposites
FUNDING DETAILS: Ministry of Education and Science of Ukraine, MESU, 0125U001883
FUNDING DETAILS: Ministry of Education and Science of Ukraine, MESU
FUNDING TEXT 1: This work was supported by the Ministry of Education and Science of Ukraine (project No 0125U001883).
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CORRESPONDENCE ADDRESS: I. Zhydenko; Lviv State University of Life Safety, Fire Tactics and Emergency Rescue Work Dpt., Lviv, Ukraine; email: zhidenkoillia@gmail.com
PUBLISHER: Institute of Electrical and Electronics Engineers Inc.
CONFERENCE NAME: 15th IEEE International Conference "Nanomaterials: Applications and Properties", NAP 2025
CONFERENCE DATE: 7 September 2025 through 12 September 2025
CONFERENCE LOCATION: Bratislava
CONFERENCE CODE: 214550
ISBN: 979-833158799-4
LANGUAGE OF ORIGINAL DOCUMENT: English
ABBREVIATED SOURCE TITLE: Proc. IEEE Int. Conf. "Nanomater.: Appl. Prop.", NAP
DOCUMENT TYPE: Conference paper
PUBLICATION STAGE: Final
SOURCE: Scopus