1 Department of Humanities and Applied Science, School of Management Sciences, Lucknow, (UP), India.
2 Department of Physics, Nandini Nagar P.G. College, Nawabganj, Gonda, (UP), India.
3 Munna Lal Inter College, Wazirganj, budaun, (UP), India.
4 Department of Applied Science and Humanities, Goel Institute of Technology and Management, Lucknow (UP), India.
International Journal of Science and Research Archive, 2025, 17(03), 560-571
Article DOI: 10.30574/ijsra.2025.17.3.3274
Received on 08 November 2025; revised on 13 December 2025; accepted on 16 December 2025
This research explains how temperature acts in tiny particles, such as ZrO₂, Ag, ZnO, NiO, and Al, using some cool tools: the Dixit–Srivastava EOS, the Birch–Murnaghan EOS, and a heat-focused model. We're essentially using these models to predict how temperature changes as these nanoparticles expand, and then verifying if our predictions match real-world experiments. Turns out, the Dixit–Srivastava EOS usually nails it, giving us the most accurate forecasts for all the materials. Interestingly, metals seem to cool down faster due to their surface, but ionic oxides are tougher and hold onto their heat better. So, it seems these EOS models with nanoscale adjustments work well, and we can use this knowledge to create better nanomaterials for electronics, energy, and structures.
Equation of state; Volume thermal expansion coefficient; Nanomaterials; Anderson-Gruneisen parameter; Bulk modulus
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Anod Kumar Singh, Reetesh Srivastava, Harish Chandra Srivastava, Brijesh Kumar Pandey and Abhay P Srivastava. Explore the Impact of Dimensional Characteristics on the Thermal Behavior of Nanomaterials. International Journal of Science and Research Archive, 2025, 17(03), 560-571. Article DOI: https://doi.org/10.30574/ijsra.2025.17.3.3274.
Copyright © 2025 Author(s) retain the copyright of this article. This article is published under the terms of the Creative Commons Attribution Liscense 4.0
