Abstract
This work deals with a thermodynamic approach to the ideality of gases in a systematic and organized way. Important aspects are presented regarding the understanding of the behavior of gases and their properties, such as the properties of the physical state of matter, in which the gas is in the simplest state according to the arrangement of its molecules. It was highlighted the topics that led the scientists to arrive at the knowledge currently available, through experimental results observed by them, resulting in empirical laws that helped to understand the behavior of the gases in diverse situations, as in the cases of variations of temperature and pressure. These laws, which combined proportionately, resulted in a mathematical equation called the perfect or ideal gas equation, a law that strictly follows the formulated empirical mathematical relations and which is the starting point for the deduction of what is really the ideal or perfect gas. The gas model quoted is the basis of the kinetic theory of gases, which theory has a well-developed theoretical understanding to explain the behavior of an ideal gas. Also exposed in this work is the definition of real gases that present different behavior of the ideal gases due to the interactions that can occur between their molecules. For a better understanding of the real gases we explained ways of studying the intermolecular forces in these gases, such as the compressibility factor and the Van der Waals equation. Also, the transformations occurring in the gaseous state, such as liquefaction, are discussed. The present work was done on the basis of bibliographical research in order to have a favorable knowledge about the study of gases from the thermodynamic point of view, aiming to establish the necessary definitions of the study of the phases of matter.
References
ATKINS .P, PAULA.J. Físico-Química Fundamentos. 5ª ed. Editora LTC: Rio de Janeiro, 2011.
ATKINS .P, PAULA.J. Físico-Química, 8ª ed. Editora LTC: Rio de Janeiro, 2012.
ATKINS, P.; JONES, L. Principles of chemistry: questionaring of life and enviromental. Oxford, 2010.
PADUA, A. B. de et al. Termodinâmica clássica ou termodinâmica do equilíbrio: aspectos conceituais básicos. Semina: Ciências Exatas e Tecnológicas.
DE PADUA, A. B. et al. A História da Termodinâmica: uma Ciência Fundamental. Londrina: EDUEL, 2009.
SANDER, R., “Complication of Henry’s Law Constants for Inorganic and Organic Species of Potential Importance in Environmental”. Air Chemistry Department – Max Planck Institute of Chemistry, 1999.
BROWN.T.L, et al. Química a Ciência Central, 9ªed. São Paulo: Editora Pearson Prentice Hall, 2005.
CASTELLAN.G. Fundamentos de Fisico-Quimica 1ª ed. Rio de Janeiro: Editora LTC, 2011
CHANG,R.; GOLDSBY, K. A. Química, 11ª ed. Porto Alegre: McGraw Hill, 2013 FELTRE.R. Química, 6ª ed. São Paulo: Editora moderna LTDA, 2004
GUIDINI. F. P, MENDES.T. Força de Van der Waals. Mecânica Quântica. Disponível em: http://www.ifsc.usp.br. Acesso em: 14 Out. 2018.
MAHAN.B.M, MYERS.R.J. Química um curso universitário, 4ª ed. Editora Edgard Blucher. Ltda: São Paulo, 2014.
MASTERTON, W. L.; HURLEY, C. N.; HETH, E. J. Chemistry principles and reation, 7a. ed, Cengage, Belmont, 2012.
RUSSEL.J.B. Química Geral. 2ª ed. Editora: Pearson Makron Books: São Paulo, 1994.
ROCHA, José Fernando M. Origens e Evolução das ideias da Física. Salvador: EDUFBA, 2002.