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Saturday, October 26, 2019

Grahams Law :: physics chemistry graham grahams law

In chemistry and in physics, the movement of particles becomes very important. One way in which particles move is through effusion. The formula for the rate of effusion of gas molecules was developed by a chemist by the name of Thomas Graham in the 19th century. December 21, 1805ï ¿ ½September 16, 1869. Thomas Graham was born in December of 1805 in Glasgow, Scotland. His father was a workman who desired that his son enter the Church of Scotland. However, Graham became a student at the University of Glasgow in 1819, where he became interested in the field of chemistry. He left the university in 1826 and went off to be a professor of chemistry at several universities, two of which were the Royal College of Science and Technology and the University of London. In 1841, he founded the Chemical Society of London, of which he was the first president. His study in the field of colloids (a type of homogenous mixture) led to the discovery of dialysis and his earning of the name ï ¿ ½the father of colloid chemistry.ï ¿ ½ Another of Grahamï ¿ ½s accomplishments was in his study of diffusion and effusion of gases. His formula for the effusion of gases even carries his name; it is called Grahamï ¿ ½s Law. Grahamï ¿ ½s Law ï ¿ ½Physics. The flow of a gas through a small orifice at such a density that the mean distance between the molecules is large compared with the diameter of the orificeï ¿ ½ (ï ¿ ½effusionï ¿ ½). In other words, effusion is the flow of individual gas molecules through a hole that is smaller than the mean free path, which is ï ¿ ½the average distance [a] particle travels between collisions with other particlesï ¿ ½ (ï ¿ ½Mean free pathï ¿ ½). This means that in effusing through the hole the gas molecules do not collide with one another. efï ¿ ½fuï ¿ ½sion ï ¿ ½noun One of the postulates of the Kinetic Molecular Theory states that average kinetic energy of gas particles depends solely on the temperature of the gas. Since this is the case, the kinetic energy of two gas molecules, hydrogen and oxygen for example, may be written as the following. When simplified the equation becomes this. Rearranging yields this equation. And taking the square root of both sides gives us the following. This formula is a simplified version of Grahamï ¿ ½s Law which states ï ¿ ½that the rate of effusion of a gas is inversely proportional to the square root of the mass of its particlesï ¿ ½ (ï ¿ ½Grahamï ¿ ½s Lawï ¿ ½).

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