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Lgaz, H. (2016). Investigating the Energy Efficiency of TEX High Energy Derivatives with Different Carbon Fuller Nano Structures under Different Temperature Conditions by DFT Method. International Journal of New Chemistry, 3(4), 137-144.
Helen Lgaz. "Investigating the Energy Efficiency of TEX High Energy Derivatives with Different Carbon Fuller Nano Structures under Different Temperature Conditions by DFT Method". International Journal of New Chemistry, 3, 4, 2016, 137-144.
Lgaz, H. (2016). 'Investigating the Energy Efficiency of TEX High Energy Derivatives with Different Carbon Fuller Nano Structures under Different Temperature Conditions by DFT Method', International Journal of New Chemistry, 3(4), pp. 137-144.
Lgaz, H. Investigating the Energy Efficiency of TEX High Energy Derivatives with Different Carbon Fuller Nano Structures under Different Temperature Conditions by DFT Method. International Journal of New Chemistry, 2016; 3(4): 137-144.

Investigating the Energy Efficiency of TEX High Energy Derivatives with Different Carbon Fuller Nano Structures under Different Temperature Conditions by DFT Method

Article 3, Volume 3, Issue 4, Autumn 2016, Page 137-144  XML PDF (1.3 MB)
Document Type: Research Paper
Author
Helen Lgaz*
Department of Chemistry, An-Najah National University, P. O. Box 7, Nablus, Palestine.
Abstract
In this study, high energy energy derivatives of TEX with different carbon-containing fullerenes at different temperature conditions were studied using density functional theory. For this purpose, the materials were first geometric optimized, then the thermodynamic parameters were calculated for all of them. Then, the process of changing the energy-dependent parameters such as specific heat capacity, enthalpy, entropy and Gibbs free energy relative to molecular mass, molecular volume and measured level in this study at a given temperature, were evaluated against each other.
Keywords
High energy energy derivatives; TEX; Functional density theory
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