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Combined Gas Law The pressure and volume of a gas are inversely proportional to each other, but directly proportional to the temperature of that gas. Table.

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Presentation on theme: "Combined Gas Law The pressure and volume of a gas are inversely proportional to each other, but directly proportional to the temperature of that gas. Table."— Presentation transcript:

1 Combined Gas Law The pressure and volume of a gas are inversely proportional to each other, but directly proportional to the temperature of that gas. Table T of Reference Tables Temperature must be in K (Kelvin).

2 Temperature Table T of Reference Tables Water Freezes Water Boils Absolute Zero

3 Combined Gas Law Temperature = Volume x Pressure / Constant Volume = Constant x Temperature / Pressure Pressure = Constant x Temperature / Volume Pressure x Volume/Temperature = Constant Substituting in variables, the formula is: PV/T=K K is a constant = n (amount) R (gas constant)

4 Combined Gas Law Because the formula is equal to a constant, it is possible to solve for a change in volume, temperature, or pressure using a proportion:

5 Using Gas Law Equation: At a temperature of 27°C and a pressure of 50.65 kPa, 60.0 mL of a gas is collected. What would the volume of the gas be at STP? STP is 273 K and a pressure of 101.3 kPa Set up the equation:

6 Using the Gas Law Equation: Temp. must be in Kelvin, so convert: 27°C + 273 = 300 K T 1 is 300K V 1 is 60.0 mL P 1 is 50.65 kPa T 2 is standard temperature 273 K P 2 is standard pressure 101.3 kPa V 2 is ?

7 Solution: (50.65 kPa)(60.0 mL) (101.3 kPa)(V 2 ) = 300 K 273 K

8 Solution: 3039 kPa mL (101.3 kPa)(V 2 ) = 300 K 273 K

9 Solution: 10.13 kPa mL = (101.3 kPa)(V 2 ) K 273 K

10 Solution: (273 K) 10.13 kPa mL = 101.3 kPa (V 2 )(273K) K 273 K

11 Solution: 2765.49 kPa mL = 101.3 kPa (V 2 ) 101.3 kPa 101.3 kPa V 2 = 27.3 mL

12 Learning Check A gas has a volume of 25.0L at a temperature of 27°C and a pressure of 1.00 atm. The gas is allowed to expand to a new volume of 50.0 L. The pressure is now 0.40 atm. What is the final temperature? T 2 = 240 K

13 Boyle’s Law Temperature is Constant

14 Boyle’s Law Boyle's Law and Syringe Video In the mid 1600's, Robert Boyle studied the relationship between the pressure p and the volume V of a confined gas held at a constant temperature. Boyle observed that the product of the pressure and volume are observed to be nearly constant.

15 Boyle’s Law

16 Boyle’s Law – Balloon Demo Inflating a Sealed Balloon Video

17 Learning Check A balloon contains 30.0 L of helium gas at 103 kPa. What will the volume be if the pressure is changed to 25 kPa at constant temperature? P 1 V 1 = P 2 V 2 (103 kPa)(30.0 L) = 25 kPa (V 2 ) 3090 kPa L = 25 kPa (V 2 ) 3090 kPa L = V 2 25 kPa V 2 = 123.6 L

18 Boyle’s Law Pressure increases then Volume decreases Pressure decreases then Volume increases

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