International Journal of Innovative Research and Development

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Understanding of Lithium-Borosilicate Glass System through MOT



For the first time a qualitative approach is opted to understand the role of the chemical process of glass former and modifier through the concept of Molecular Orbital Theory (MOT). To begin with, systematically MO configurations and energy diagrams of di-lithium, boron and oxygen molecules along with Li2O, B2O3, and SiO2 followed by distribution of electrons/bonds by considering perfectly covalent and partially covalent bonds are given. Later, on addition of modifier Li2O to B2O3 and SiO2 bond restructuring and electron distribution and chemical bonding in Li2O:B2O3:SiO2 system along with the conditions of glass formation is dealt. It is understood that when glass formers have smaller softness value combined with modifiers having more hardness value then the bonds between them break, and forms the glass, systems possessing electrical conductivity due to mobility of cation (Li). Also glass structure is predicted on the basis of regression analysis.


Keywords

Molecular orbital theory. Valence bond theory. Lewis dot theory., aufbau principle. Paulis’ exclusion principle .Hunds’ rule. Configuration. Atomic number. Potential energy. Overlapping
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  • Understanding of Lithium-Borosilicate Glass System through MOT

Abstract Views: 124  |  PDF Views: 7

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Abstract


For the first time a qualitative approach is opted to understand the role of the chemical process of glass former and modifier through the concept of Molecular Orbital Theory (MOT). To begin with, systematically MO configurations and energy diagrams of di-lithium, boron and oxygen molecules along with Li2O, B2O3, and SiO2 followed by distribution of electrons/bonds by considering perfectly covalent and partially covalent bonds are given. Later, on addition of modifier Li2O to B2O3 and SiO2 bond restructuring and electron distribution and chemical bonding in Li2O:B2O3:SiO2 system along with the conditions of glass formation is dealt. It is understood that when glass formers have smaller softness value combined with modifiers having more hardness value then the bonds between them break, and forms the glass, systems possessing electrical conductivity due to mobility of cation (Li). Also glass structure is predicted on the basis of regression analysis.


Keywords


Molecular orbital theory. Valence bond theory. Lewis dot theory., aufbau principle. Paulis’ exclusion principle .Hunds’ rule. Configuration. Atomic number. Potential energy. Overlapping