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Kinetic Molecular Theory. ki⋅net⋅ic. Origin: 1850–55; < Gk kīnētikós moving, equiv. to kīnē - ( verbid s. of kīneîn to move) + - tikos. Source: Websters Dictionary. So far we have considered “what happens,” but not “why.” In science, “what” always comes before “why.”.
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Kinetic Molecular Theory ki⋅net⋅ic Origin: 1850–55; < Gk kīnētikós moving, equiv. to kīnē- (verbid s. of kīneîn to move) + -tikos Source: Websters Dictionary
So far we have considered “what happens,” but not “why.” • In science, “what” always comes before “why.”
The Nature of Gases • Gases expand to fill their containers • Gases are fluid – they flow • Gases have low density • 1/1000 the density of the equivalent liquid or solid • Gases are compressible • Gases effuse and diffuse
Kinetic Molecular Theory • Particles of matter are ALWAYS in motion • Volume of individual particles is zero. • Collisions of particles with container walls cause the pressure exerted by gas. • Particles exert no forces on each other. • Average kinetic energy is proportional to Kelvin temperature of a gas.
Postulates of the Kinetic Molecular Theory 1) The particles are so small compared with the distances between them that the volume of the individual particlescan be assumed to be negligible (zero).
Postulates of the Kinetic Molecular Theory • The particles are in constant motion. • The collisions of the particles with the walls of the container are the cause of the pressure exerted by the gas.
Postulates of the Kinetic Molecular Theory 4)The particles are assumed to exert no forces on each other; they are assumed neither to attract nor to repel each other and engage in elastic collisions.
Postulates of the Kinetic Molecular Theory 5) The average kinetic energy of a collection of gas particles is assumed to be directly proportional to the Kelvin temperature of the gas.
Kinetic Energy of Gas Particles At the same conditions of temperature, all gases have the same average kinetic energy. This calc is on REF SHEET. m = mass v = velocity At the same temperature, small molecules move FASTER than large molecules
Root Mean Square Velocity • Avg velocity of a gas is actually the avg of the squares of the particle velocities. • The square root of this is the root mean square velocity
Root Mean Square Velocity – Maxwell-Boltzmann Distribution Curve
What does this tell us? • At any given temp, gas mlcls have both high & low speeds (think ppl in hallway) • As temp incrs, the distribution of speeds is found to be across a wider range • As temp incrs, a greater # of mlcls are traveling faster. @ 2273K, mcls traveling 1500-3000m/s, but at 273K, they can’t be in that range.
RMS Velocity • The RMS velocity, temperature, & molar mass are related. • You won’t have to use the calculation, BUT. • Know that RMS is dependent upon molar mass • Heavier particles move more slowly • Know that RMS is dependent upon temperature • Particles at high temps move more quickly
Root Mean Square Velocity R = 8.3145 J/K·mol (J = joule = kg·m2/s2) T = temperature of gas (in K) M = mass of a mole of gas in kg • Final units are in m/s.