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To understand the Ideal Gas Law and use it in calculations

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Presentation on theme: "To understand the Ideal Gas Law and use it in calculations"— Presentation transcript:

1 To understand the Ideal Gas Law and use it in calculations
Objectives To understand the Ideal Gas Law and use it in calculations To understand the relationship between the partial and total pressure of a gas mixture To do calculations involving Dalton’s Law of partial pressures To prepare for the Universal Gas Constant lab

2 A. The Kinetic Molecular Theory of Gases (IDEAL)

3 Boyle’s Law V = k (at constant T and n) P
A. The Ideal Gas Law Boyle’s Law V = k (at constant T and n) P Charles’s Law V = bT (at constant P and n) Avogadro’s Law V = an (at constant T and P) We can combine these equations to get

4 R = 0.08206 L atm **Found mol K Experimentally
A. The Ideal Gas Law Rearranging the equation gives the Ideal Gas Law PV = nRT R = L atm **Found mol K Experimentally

5 A sample of hydrogen gas, H2, has a volume of 8
A sample of hydrogen gas, H2, has a volume of 8.56 L at a temperature of 0 oC and a pressure of 1.5 atm. Calculate the number of moles of H2 present in this gas sample. Assume that the gas behaves ideally. PV=nRT P= V= n= R= T=

6 PV=nRT P= 1.5 atm **UNITS** V= 8.56 L n= ? R= Latm/molK T= 0 oC = 273 K n = PV RT n = (1.5 atm)(8.56 L) = 0.57 mol ( Latm/molK)(273 K)

7 What volume is occupied by 0.250 mol of CO2 gas at 25 oC and 371 torr?
PV=nRT P= V= n= R= T=

8 What volume is occupied by 0. 250 mol of CO2 gas at 25 oC and 371 torr
What volume is occupied by mol of CO2 gas at 25 oC and 371 torr? *(1 atm = 760 torr) PV=nRT P= 371 torr V= ? n= mol R= Latm/molK T= 25 oC = 298 K V = nRT P

9 What volume is occupied by 0. 250 mol of CO2 gas at 25 oC and 371 torr
What volume is occupied by mol of CO2 gas at 25 oC and 371 torr? *(1 atm = 760 torr) V = nRT = mol)( Latm/molK)(298K) P torr V = L ?? 371 torr 1 atm = atm 760 torr V = nRT =(0.250 mol)( Latm/molK)(298K) P atm V = 12.5 L ****Watch the units!!!****

10 n1T1 n2T2 Derive Boyle’s Law (P1V1 = P2V2) from IGL
PV=nRT PV = R = constant (LAB) nT P1V1 = P2V2 n1T1 n2T2 IGL Video, fire syringe

11 B. Dalton’s Law of Partial Pressures
What happens to the pressure of a gas as we mix different gases in the container? Dalton’s Law of Partial Pressures For a mixtures of gases in a container, the total pressure exerted is the sum of the partial pressures of the gases present. Ptotal = P1 + P2 + P3

12 B. Dalton’s Law of Partial Pressures
The pressure of the gas is affected by the number of particles but not the type of particles.

13 B. Dalton’s Law of Partial Pressures
Two crucial things we learn from this are: The volume of the individual particles is not very important. The forces among the particles must not be very important.

14 B. Dalton’s Law of Partial Pressures
A container holds a mixture of three gases that exhibit a total pressure of 1.8 atm. If gas A exerts 0.9 atm and gas B exerts 0.4 atm, what is the partial pressure of gas C? Ptotal = P1 + P2 + P3 Ptotal = P1 = P2 = P3 = ?

15 B. Dalton’s Law of Partial Pressures
Ptotal = P1 + P2 + P3 Ptotal = 1.8 atm P1 = 0.9 atm P2 = 0.4 atm P3 = ? P3 = Ptotal - P1 - P2 P3 = 1.8 atm – 0.9 atm – 0.4 atm = 0.5 atm

16 B. Dalton’s Law of Partial Pressures
Collecting a gas over water Total pressure is the pressure of the gas + the vapor pressure of the water.

17 B. Dalton’s Law of Partial Pressures
Collecting a gas over water How can we find the pressure of the gas collected alone? Ptotal = P1 + P2 Ptotal = atmospheric P1 = PH2O (from chart) P2 = P (gas collected)

18 To understand the ideal gas law and use it in calculations
Objectives Review To understand the ideal gas law and use it in calculations To understand the relationship between the partial and total pressure of a gas mixture To do calculations involving Dalton’s law of partial pressures To prepare for the Universal Gas Constant lab Work Session: 459 Practice Problem 13.8 460 Practice Problem 13.9 469 Practice Problem – PH2O ONLY 481 # 35, 36 PO2 ONLY Review # 3

19 To convert between pressure units using the unit analysis approach
Objectives To double check for unit agreement when working the 5-Step Problem Solving Method To convert between pressure units using the unit analysis approach To remember how to convert from gmol!!

20 Convert 5.2 atmospheres to mm Hg. 5.2 atm =
Pressure Unit Conversions, Unit Analysis Approach 1 atm = 760 mm Hg 760 mm Hg = 760 torr 1 atm = 101, 325 Pa Convert 5.2 atmospheres to mm Hg. 5.2 atm = Convert 5.2 atmospheres to torrs.

21 Convert 5.2 atmospheres to Pa. 5.2 atm = Convert 748 torrs to Pa
Pressure Unit Conversions, Unit Analysis Approach 1 atm = 760 mm Hg 760 mm Hg = 760 torr 1 atm = 101, 325 Pa Convert 5.2 atmospheres to Pa. 5.2 atm = Convert 748 torrs to Pa 748 torr =

22 Convert 7.48 g nitrogen gas to mol 7.48 g =
g  mol Conversions, Unit Analysis Approach Convert 5.2 g CH4 to mol CH4 5.2 g CH = Convert 7.48 g nitrogen gas to mol 7.48 g =

23 A sample of hydrogen gas, H2, has a volume of 9
A sample of hydrogen gas, H2, has a volume of 9.46 L at a temperature of 0 oC and a pressure of 988 torr. Calculate the number of grams of H2 present in this gas sample. PV=nRT P= V= n= R= T=

24 A sample of hydrogen gas, H2, has a volume of 9
A sample of hydrogen gas, H2, has a volume of 9.46 L at a temperature of 0 oC and a pressure of 988 torr. Calculate the number of grams of H2 present in this gas sample. PV=nRT P= 988 torr V= 9.46 L n= ? R= Latm/molK T= 0 oC = 273 K

25 A sample of hydrogen gas, H2, has a volume of 9
A sample of hydrogen gas, H2, has a volume of 9.46 L at a temperature of 0 oC and a pressure of 988 torr. Calculate the number of grams of H2 present in this gas sample. n = PV RT n = PV = (1.3 atm)(9.46 L) = 0.55mol RT ( Latm/molK) (273 K) n = 0.55 mol H2

26 To convert between pressure units using the unit analysis approach
Objectives Review To double check for unit agreement when working the 5-Step Problem Solving Method To convert between pressure units using the unit analysis approach To remember how to convert from gmol!! Work Session: Page 480 # Review # 2 (g mol)

27 To understand the molar volume of an ideal gas
Objectives To understand the molar volume of an ideal gas To learn the definition of STP To understand the relationship between laws and models (theories) To understand the postulates of the kinetic molecular theory To understand temperature To learn how the kinetic molecular theory explains the gas laws To describe the properties of real gases

28 Standard temperature and pressure (STP) 0oC and 1 atm
A1. Gas Stoichiometry Molar Volume Standard temperature and pressure (STP) 0oC and 1 atm For one mole of a gas at STP Molar volume of an ideal gas at STP L

29 A. Laws and Models (Theories) : A Review
A model (theory) is an approximation and is destined to be modified as we understand more or are able to better measure phenomena occurring around us. A model (theory) can never be proved absolutely true.

30 B. The Kinetic Molecular Theory of Gases

31 C. The Implications of the Kinetic Molecular Theory
Meaning of temperature – Kelvin temperature is directly proportional to the average kinetic energy of the gas particles Relationship between Pressure and Temperature – gas pressure increases as the temperature increases because the particles speed up Relationship between Volume and Temperature – volume of a gas increases with temperature because the particles speed up

32 D. Real Gases Gases do not behave ideally under conditions of high pressure and low temperature. Why?

33 B. The Kinetic Molecular Theory of Gases

34 At high pressure the volume is decreased
D. Real Gases At high pressure the volume is decreased Molecule volumes become important Attractions become important

35 Math Laws are still approximations….. PV = nRT ……. …..or does it?
D. Real Gases Math Laws are still approximations….. PV = nRT ……. …..or does it?

36 Calculate the pressure exerted by 0. 75 mol of He in a 1
Calculate the pressure exerted by 0.75 mol of He in a 1.0 L container at standard temperature. Use vdW… P= nRT – a(n/V)2 (V-nb) P = atm vs atm

37 To understand the molar volume of an ideal gas
Objectives Review To understand the molar volume of an ideal gas To learn the definition of STP To understand the relationship between laws and models (theories) To understand the postulates of the kinetic molecular theory To understand temperature To learn how the kinetic molecular theory explains the gas laws To describe the properties of real gases (PHet) Work session: Page Review # 1 - 5

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