ISSN: 2375-3765
American Journal of Chemistry and Application  
Manuscript Information
 
 
Interrelation of Thermodynamic Parameters and Structural Characteristics, with Halides of Groups 1 and 2 Elements as an Example
American Journal of Chemistry and Application
Vol.3 , No. 5, Publication Date: Aug. 27, 2016, Page: 28-32
3668 Views Since August 27, 2016, 1046 Downloads Since Aug. 27, 2016
 
 
Authors
 
[1]    

Nina V. Molchan, Research and Production Center “Pharmzashchita” FMBA of Russia (RPC “Pharmzashchita”), Khimki, Russia.

[2]    

Valery I. Fertikov, All-Russia Institute of Light Alloys (JSC “VILS”), Moscow, Russia.

 
Abstract
 

The calculations of the concentration of electrons (Celektr mole/cm3) for simple substances and binary compounds on the basis of reference data on the density of matter in the condensed state are presented. A correlation dependence of the concentration of electrons with the thermodynamic characteristics of the halides of the elements 1 and 2 groups is revealed. The concentration of electron is proposed to use as a structural characteristic of the materials. The established relationship between the structural characteristics and thermodynamic parameters has allowed to theoretically calculate the thermodynamic parameters missing in contemporary references. The using of the coefficient of consolidation based the same reference data on the density of substances in the condensed state to compare the changes of molecular volumes during chemical processes.


Keywords
 

Concentration of Electrons, Density, Enthalpy, Entropy, Gibbs Energy, Halides, Structure


Reference
 
[01]    

N. Molchan, V. Fertikov, Determination of Concentration of Electrons for Description of the Structure of Materials, w Sulfides as an Example, Journal of Materials Sciences and Applications 2 (2015) 38-44.

[02]    

N. Molchan, V. Fertikov, Concentration of electrons as a structural characteristic of oxides, Technique and technology of silicates 2 (2016) 8-13.

[03]    

N. Molchan, V. Fertikov, Compressibility of Substances and Dimensions of Atoms, Materials Science 6 (2011) 2-6.

[04]    

J. Martin, Concise Encyclopedia of the Structure of Materials, Elsevier Limited, Amsterdam, 2007.

[05]    

O. Sirotkin, The Princiles of Innovative Material Science. INFRA-M, Moscow, 2011.

[06]    

International Centre for Diffraction Data. JCPDS PCPDFWIN (2002) V. 2.03.

[07]    

Key Properties of Inorganic, Organic and Element Organic Compounds. The New Reference Book for Chemists and Technologists, NPO "Professional", Saint-Petersburg, 2007.

[08]    

A. Babichev, N. Babushkina, A. Bratkovsky et al., Physical Quantities, Energoatomizdat, Moscow, 1991.

[09]    

N. Molchan, V. Fertikov, A Method of Estimation of Reactivity of Hydrogen, Boron, Carbon, and Nitrogen, Technology of Low-Density Alloys 2 (2009) 47-56.

[10]    

N. Molchan, V. Fertikov, Electron Density and Mechanical Characteristics of Substances, Materials of conference "TestMat-2013" FSUE “VIAM”, Moscow, 2013.

[11]    

N. Molchan, V. Fertikov, Control of the Structure of an Aluminum Alloy by Atomic Emission Spectroscopy, Russian metallurgy (Metally) 5 (2012) 428-430.

[12]    

N. Molchan, I. Polkin, V. Fertikov, Ability to Control a Titanium-alloy Structure by Atomic-Emission Spectroscopy, Journal of Applied Spectroscopy 2 (2014) 169-173.

[13]    

R. Lidin, L. Andreeva, L. Molochko, Constants of Mineral Substances, Reference book, Drofa, Moscow, 2006.

[14]    

P. Müller, P. Neumann, R. Storm, Tafeln der mathematischen Statistik, VEB Fachbuchverlag, Leipzig, 1979.





 
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