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The Gas Laws u Describe HOW gases behave. u Can be predicted by the theory. u Amount of change can be calculated with mathematical equations.

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Presentation on theme: "The Gas Laws u Describe HOW gases behave. u Can be predicted by the theory. u Amount of change can be calculated with mathematical equations."— Presentation transcript:

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3 The Gas Laws u Describe HOW gases behave. u Can be predicted by the theory. u Amount of change can be calculated with mathematical equations.

4 The effect of adding gas. u When we blow up a balloon we are adding gas molecules. u Doubling the the number of gas particles doubles the pressure. (of the same volume at the same temperature).

5 Pressure and the number of molecules are directly related u More molecules means more collisions. u Fewer molecules means fewer collisions. u Gases naturally move from areas of high pressure to low pressure because there is empty space to move in.

6 1 atm u If you double the number of molecules

7 u You double the pressure. 2 atm

8 u As you remove molecules from a container 4 atm

9 u As you remove molecules from a container the pressure decreases 2 atm

10 u As you remove molecules from a container the pressure decreases u Until the pressure inside equals the pressure outside u Molecules naturally move from high to low pressure 1 atm

11 Changing the size of the container u In a smaller container molecules have less room to move. u Hit the sides of the container more often. u As volume decreases pressure increases.

12 1 atm 4 Liters u As the pressure on a gas increases

13 2 atm 2 Liters u As the pressure on a gas increases the volume decreases u Pressure and volume are inversely related

14 Temperature u Raising the temperature of a gas increases the pressure if the volume is held constant. u The molecules hit the walls harder. u The only way to increase the temperature at constant pressure is to increase the volume.

15 u If you start with 1 liter of gas at 1 atm pressure and 300 K u and heat it to 600 K one of 2 things happens 300 K

16 u Either the volume will increase to 2 liters at 1 atm 300 K 600 K

17 300 K 600 K Or the pressure will increase to 2 atm. Or someplace in between

18 Ideal Gases u In this chapter we are going to assume the gases behave ideally. u Does not really exist but makes the math easier and is a close approximation. u Particles have no volume. u No attractive forces.

19 Ideal Gases u There are no gases for which this is true. u Real gases behave this way at high temperature and low pressure.

20 Daltons’ Law of Partial Pressures u The total pressure inside a container is equal to the partial pressure due to each gas. u The partial pressure is the contribution by that gas. u P Total = P 1 + P 2 + P 3 u For example

21 u We can find out the pressure in the fourth container. u By adding up the pressure in the first 3. 2 atm 1 atm 3 atm 6 atm

22 Examples u What is the total pressure in a balloon filled with air if the pressure of the oxygen is 170 mm Hg and the pressure of nitrogen is 620 mm Hg? u In a second balloon the total pressure is 1.3 atm. What is the pressure of oxygen if the pressure of nitrogen is 720 mm Hg?

23 Boyle’s Law u At a constant temperature pressure and volume are inversely related. u As one goes up the other goes down  P x V = K(K is some constant) u Easier to use P 1 x V 1 =P 2 x V 2

24 P V

25 u A balloon is filled with 25 L of air at 1.0 atm pressure. If the pressure is change to 1.5 atm what is the new volume? u A balloon is filled with 73 L of air at 1.3 atm pressure. What pressure is needed to change to volume to 43 L? Examples

26 Charles’ Law u The volume of a gas is directly proportional to the Kelvin temperature if the pressure is held constant.  V = K x T (K is some constant)  V/T= K u V 1 /T 1 = V 2 /T 2

27 V T

28 Examples u What is the temperature of a gas that is expanded from 2.5 L at 25ºC to 4.1L at constant pressure. u What is the final volume of a gas that starts at 8.3 L and 17ºC and is heated to 96ºC?

29 Gay Lussac’s Law u The temperature and the pressure of a gas are directly related at constant volume.  P = K x T (K is some constant)  P/T= K u P 1 /T 1 = P 2 /T 2

30 P T

31 Examples u What is the pressure inside a 0.250 L can of deodorant that starts at 25ºC and 1.2 atm if the temperature is raised to 100ºC? u At what temperature will the can above have a pressure of 2.2 atm?

32 Putting the pieces together u The Combined Gas Law Deals with the situation where only the number of molecules stays constant. u (P 1 x V 1 )/T 1 = (P 2 x V 2 )/T 2 u Lets us figure out one thing when two of the others change.

33 Examples u A 15 L cylinder of gas at 4.8 atm pressure at 25ºC is heated to 75ºC and compressed to 17 atm. What is the new volume? u If 6.2 L of gas at 723 mm Hg at 21ºC is compressed to 2.2 L at 4117 mm Hg, what is the temperature of the gas?

34 u The combined gas law contains all the other gas laws! u If the temperature remains constant. P1P1 V1V1 T1T1 x = P2P2 V2V2 T2T2 x Boyle’s Law

35 u The combined gas law contains all the other gas laws! u If the pressure remains constant. P1P1 V1V1 T1T1 x = P2P2 V2V2 T2T2 x Charles’ Law

36 u The combined gas law contains all the other gas laws! u If the volume remains constant. P1P1 V1V1 T1T1 x = P2P2 V2V2 T2T2 x Gay-Lussac Law

37 The Fourth Part u Avagadro’s Hypothesis u V is proportional to number of molecules at constant T and P. u V is proportional to moles.  V = K n ( n is the number of moles. u Gets put into the combined gas Law

38 The Ideal Gas Law u P x V = n x R x T u Pressure times Volume equals the number of moles times the Ideal Gas Constant (R) times the temperature in Kelvin. u This time R does not depend on anything, it is really constant u R = 0.0821 (L atm)/(mol K)

39 u R = 62.4 (L mm Hg)/(K mol) u We now have a new way to count moles. By measuring T, P, and V. We aren’t restricted to STP. u n = PV/RT The Ideal Gas Law

40 Examples u How many moles of air are there in a 2.0 L bottle at 19ºC and 747 mm Hg? u What is the pressure exerted by 1.8 g of H 2 gas exert in a 4.3 L balloon at 27ºC?

41 Density u The Molar mass of a gas can be determined by the density of the gas. u D= mass = m Volume V u Molar mass = mass = m Moles n u n = PV RT

42 Density Continued u Molar Mass = m (PV/RT) u Molar mass = m RT V P u Molar mass = DRT P

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44 Ideal Gases don’t exist u Molecules do take up space u There are attractive forces u otherwise there would be no liquids

45 Real Gases behave like Ideal Gases u When the molecules are far apart u The molecules do not take up as big a percentage of the space u We can ignore their volume. u This is at low pressure

46 Real Gases behave like Ideal gases when u When molecules are moving fast. u Collisions are harder and faster. u Molecules are not next to each other very long. u Attractive forces can’t play a role.

47 Diffusion u Effusion Gas escaping through a tiny hole in a container. u Depends on the speed of the molecule. u Molecules moving from areas of high concentration to low concentration. u Perfume molecules spreading across the room.

48 Graham’s Law u The rate of effusion and diffusion is inversely proportional to the square root of the molar mass of the molecules. u Kinetic energy = 1/2 mv 2 u m is the mass v is the velocity. Chem Express

49 u bigger molecules move slower at the same temp. (by Square root) u Bigger molecules effuse and diffuse slower u Helium effuses and diffuses faster than air - escapes from balloon. Graham’s Law

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