Kinetic Molecular Theory kinetic 1 pertaining to motion

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Kinetic Molecular Theory ki⋅net⋅ic 1. pertaining to motion. 2. caused by motion. 3. characterized

Kinetic Molecular Theory ki⋅net⋅ic 1. pertaining to motion. 2. caused by motion. 3. characterized by movement: Running and dancing are kinetic activities. Origin: 1850– 55; < Gk kīnētikós moving, equiv. to kīnē(verbid s. of kīneîn to move) + -tikos Source: Websters Dictionary

CA Standards Students know the random motion of molecules and their collisions with a

CA Standards Students know the random motion of molecules and their collisions with a surface create the observable pressure on that surface. Students know the random motion of molecules explains the diffusion of gases.

The Nature of Gases q Gases expand to fill their containers q Gases are

The Nature of Gases q Gases expand to fill their containers q Gases are fluid – they flow q Gases have low density q 1/1000 the density of the equivalent liquid or solid q Gases are compressible q Gases effuse and diffuse

Kinetic Molecular Theory q Particles of matter are ALWAYS in motion q Volume of

Kinetic Molecular Theory q Particles of matter are ALWAYS in motion q Volume of individual particles is zero. q Collisions of particles with container walls cause the pressure exerted by gas. q Particles exert no forces on each other. q Average kinetic energy is proportional to Kelvin temperature of a gas.

Kinetic Energy of Gas Particles At the same conditions of temperature, all gases have

Kinetic Energy of Gas Particles At the same conditions of temperature, all gases have the same average kinetic energy. m = mass v = velocity At the same temperature, small molecules move FASTER than large molecules

Diffusion q Diffusion describes the mixing of gases. The rate of diffusion is the

Diffusion q Diffusion describes the mixing of gases. The rate of diffusion is the rate of gas mixing. q Diffusion is the result of random movement of gas molecules q The rate of diffusion increases with temperature q Small molecules diffuse faster than large molecules

Graham’s Law of Diffusion M 1 = Molar Mass of gas 1 M 2

Graham’s Law of Diffusion M 1 = Molar Mass of gas 1 M 2 = Molar Mass of gas 2

Purification of Uranium-235 Using Gaseous Diffusion

Purification of Uranium-235 Using Gaseous Diffusion