Behavior of Gases Ch 12 – Prentice Hall. Kinetic Theory Gases are composed of SMALL, SEPARATE particles called MOLECULES. Gas molecules are in CONSTANT.

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Presentation transcript:

Behavior of Gases Ch 12 – Prentice Hall

Kinetic Theory Gases are composed of SMALL, SEPARATE particles called MOLECULES. Gas molecules are in CONSTANT MOTION All COLLISIONS between particles are PERFECTLY ELEASTIC The MOLECULES of a gas display no ATTRACTION or REPULSION for one another.

Kinetic Theory The AVERAGE KINETIC ENERGY of the molecules is DIRECTLY PROPORTIONAL to the KELVIN temperature of the gas.

Ideal Gas Gas whose BEHAVIOR conforms to the KINETIC THEORY -it is THEORETICAL.

Gas Pressure: Pressure = FORCE ÷ AREA= ____ atm Atmospheric Pressure - the PRESSURE the earth’s ATMOSPHERE exerts due to its WEIGHT. Barometer: Instrument used to measure ATMOSPHERIC PRESSURE Invented by TORRICALLI

The Combined Gas Law Combines the following laws and equations together:

Charles law Variation of gas volume with temperature while pressure is kept constant V 1 /T 1 = V 2 /T 2 T (K) = t ( 0 C) Temperature must be in Kelvin

P 1 V 1 = P 2 V 2 Boyle’s Law Constant temperature Constant amount of gas Pressure and volume units can be any variant of pressure and volume HOWEVER the units MUST agree for both pressures and both volumes!

Combined Gas Law Expresses the relationship between the PRESSURE, VOLUME and TEMPERATURE of a FIXED amount of GAS. Equation: P 1 V 1 = P 2 V 2 T 1 T 2

STANDARD TEMPERATURE AND PRESSURE STP CONDITIONS 273 K 1 atm = 760 mmHg

Combined Gas Law Ex: A sample of gas has a volume of 201 L when its temperature is 293 K and its pressure is 224 mmHg. What volume will the gas occupy at STP? V1 = 201 L V2 = ? T1 = 293 K T2 = 273 K P1 = 224 mmHg P2 = 760 mmHg (224) (201) = (760) x (293) (273) (224) (201) (273) = (293) (760) x X = 55 L

Diffusion The RAPID spreading of a GAS Graham’s Law of Diffusion Under the same conditions of TEMPERATURE and PRESSURE, gases DIFFUSE at a rate INVERSLEY proportional to the SQUARE ROOT of their DENSITIES (or MOLAR MASS) Equation:

Ideal Gas Equation Equation: PV = nRT New variables: n = AMOUNT of gas in MOLES R = UNIVERSAL GAS CONSTANT * PROPORTIONALLY constant * value depends on UNITS used for PRESSURE and VOLUME * value of R when using kPa and L R = L. kPa / Mol. K

Ex: The average lung capacity for a female student is 3.9 L. At normal body temperature, 37 o C, and 110 kPa, how many moles of air could her lungs hold? P = 110 kPa V = 3.9 L T = 310 K ( ) n = X R = L. kPa / Mol. K (110)(3.9) = x (310)(8.314) (110)(3.9) = 0.17 mol (310)(8.314)

Avogadro’s Law Equal VOLUMES of different GASES under the SAME conditions have the SAME number of PARTICLES. Conversely, if samples of DIFFERENT GASES at the same TEMPERATURE and PRESSURE contain the SAME number of PARTICLES, then the VOLUMES of all the SAMPLES must be EQUAL. At STP, one MOLE of any gas occupies a VOLUME of 22.4 L. 22.4 L is the MOLAR VOLUME of a gas.

Dalton’s Law of Partial Pressures The PRESSURE of a gas MIXTURE is the SUM of the INDIVIDUAL PRESSURES of each gas ALONE. Equation: P T = P 1 + P 2 + P 3 …

Ex: Oxygen gas has been collected over water at a total pressure of 95.0 kPa and a temperature of 25 o C. What is the pressure of the dry oxygen gas? P T = 95 kPa P vapor = 3.17 kPa P oxygen = X 95 = x kPa = x

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