P (kPa) X1 y1 85.265 82.202 0.0579 0.0253 76.719 0.1665 0.0804 72.422 0.2482 0.1314 68.005 0.3322 0.1975 65.096 0.388 0.2457 59.651 0.5036 0.3686 56.833 0.5749 0.4564 53.689 0.6736 0.5882 51.620 0.7676 0.7176 50.455 0.8476 0.8238 49.926 0.9093 0.9002 49.720 0.9529 0.9502
Ideal and Real Gases
Ideal gases obey conditions of the general gas laws under all states of pressure and temperature. Ideal gases are also named perfect gases. The attributes of ideal gases are as follows,
Gas Laws
Gas laws describe the ways in which volume, temperature, pressure, and other conditions correlate when matter is in a gaseous state. The very first observations about the physical properties of gases was made by Robert Boyle in 1662. Later discoveries were made by Charles, Gay-Lussac, Avogadro, and others. Eventually, these observations were combined to produce the ideal gas law.
Gaseous State
It is well known that matter exists in different forms in our surroundings. There are five known states of matter, such as solids, gases, liquids, plasma and Bose-Einstein condensate. The last two are known newly in the recent days. Thus, the detailed forms of matter studied are solids, gases and liquids. The best example of a substance that is present in different states is water. It is solid ice, gaseous vapor or steam and liquid water depending on the temperature and pressure conditions. This is due to the difference in the intermolecular forces and distances. The occurrence of three different phases is due to the difference in the two major forces, the force which tends to tightly hold molecules i.e., forces of attraction and the disruptive forces obtained from the thermal energy of molecules.
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Suggest other types of excess Gibbs energy model that can be used to calculate the activity coefficient as well as to predict pressure and composition from vapor liquid equilibrium data for the given system.
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