Gas Laws

1. Gas Laws Q4U1 (13d) Mr. DiBiasio

2. Hindenburg

3. Airship called a Zeppelin (invented by Germans) • It used Hydrogen gas (dangerous!) • It exploded on May 6th, 1937. • It flew from Germany to New Jersey, USA. • It was almost as big as the Titanic.

4. Hindenburg Video http://www.youtube.com/watch?v=CgWHbpMVQ1U

5. THREE STATES OF MATTER

6. OBJECTIVE • Understand that the physical properties of a gaseous substance can be altered by external condition

7. General Properties of Gases • There is a lot of “free” space in a gas. • Gases can be expanded infinitely. • Gases fill containers uniformly and completely. • Gases diffuse and mix rapidly.

8. Properties of Gases Gas properties can be modeled using math. Model depends on— • V = volume of the gas (L) • T = temperature (K) • ALL temperatures in the entire chapter MUST be in Kelvin!!! No Exceptions! • n = amount (moles) • P = pressure (atmospheres)

9. Objective • Students will learn what a barometer is and its importance to air pressure • Students will calculate problems using knowledge of a barometer

10. Pressure Pressure of air is measured with a BAROMETER (developed by Torricelli in 1643) Hg rises in tube until force of Hg (down) balances the force of atmosphere (pushing up). (Just like a straw in a soft drink) P of Hg pushing down related to • Hg density • column height

11. Video of Barometer • http://www.youtube.com/watch?v=KRe_9PzeMQE&safety_mode=true&persist_safety_mode=1&safe=active

12. Gas Pressure • Gas Pressure is related to the mass of the gas and to the motion of the gas particles • Gas molecules move and bounce off the walls of their container • These collisions cause gas pressure • Pressure is a force per unit area • Standard Units of pressure = Pascal(Pa) • 1 Pa is the pressure of 1 Newton per square meter (N/m2) • Normal air pressure at sea level is 101.325 kilopascals (kPa) • 101.325 kPa = 760mm Hg, 1kPa = 7.5 mm Hg (1 kPa=1000Pa) • Other units of pressure, Atmosphere or psi • 1.00 atm = 760 mm Hg = 101.325 kPa =14.7 psi

13. Atmospheric Pressure • The pressure exerted on the Earth by the gasses in the atmosphere • Absolute pressure will include the pressure on a closed system, as indicated by a gauge PLUS the pressure exerted by the atmosphere. Ex. The pressure gauge on a bicycle tire reads 44 psi, what is the absolute pressure? 44psi+14.7psi =59 psi Convert to kPa; 59 psi X (101.3kPa/14.7 psi) =410kPa

14. Objective • Students will learn how to calculate open ended system problems

15. Barometer vs. Manometer: Both measure pressure Barometer: is always closed end

16. Calculations for Open Ended System • If mmHg is higher in open end • Pgas =Patmosphere + Ph3 Solve for gas pressure if: Ph3 = 185 mmHg Atmospheric pressure is 98.95 kPa • Convert mmHg to kPa # kPa = (185mm/1)(1kPa/7.50mm)=24.7 kPa • Add kPa to atmospheric pressure Pressure of gas = 98.95 +24.7= 124kPa

17. Closed system: Used to measure pressure of a gas • The closed arm is filled with gas, what is the pressure of the gas, in kPa? • The difference in the Hg level is 165 mm • 7.50 mm = 1 kPa • Pressure of gas = (165.0 mm/1) ( 1kPa/7.5 mm) = 22.0 kPa

18. Try some yourself • Closed manometer containing sulfur dioxide gas (SO2). Height difference in mmHg is 560, what is the pressure of SO2 in kPa? • An open monometer containing Hydrogen. Hg level is 78.0 mmHg in the arm connected to the air (open end), air pressure is 100.7kPa. What is the pressure of Hydrogen in kPa? • An open monometer containing Nitrogen. Hg level is 26.0 mmHg in the arm connected to the gas, air pressure is 99.6kPa. What is the pressure of nitrogen in kPa?

19. Answers • Pressure of SO2 = (560.0 mm/1) ( 1kPa/7.5 mm) = 74.6 kPa • # kPa = (78.0mm/1)(1kPa/7.50mm)=10.4 kPa Pressure of H2= 100.7kPa + 10.4kPa= 111.1 kPa • # kPa= (26.0mm/1)(1kPa/7.50mm)= 3.47kPa Pressure of N2 = -3.47kPa + 99.6 =96.1kPa notice the negative number, less than air pressure

20. Classwork • Complete section review #1-8 pg 379

21. Mathematic Relationships There is a Mathematical Relationship between Pressure, Temperature and Volume of a constant amount of gas • Gas volumes change significantly with small changes in temperature and pressure • These changes can be defined by equations called the gas laws. • Gas laws are only valid for ideal gasses • Ideal gases: do not exist, but are a model, they have no attractive force and no volume

22. Boyle’s Law P α 1/V This means Pressure and Volume are INVERSELY PROPORTIONAL if moles and temperature are constant (do not change). For example, P goes up as V goes down. P1V1 = P2 V2 Robert Boyle (1627-1691). Son of Earl of Cork, Ireland.

23. Boyle’s Law and Kinetic Molecular Theory P proportional to 1/V

24. Boyle’s Law A bicycle pump is a good example of Boyle’s law. As the volume of the air trapped in the pump is reduced, its pressure goes up, and air is forced into the tire.

25. Boyle’s Law Example Problems • If 425 mL of O2 are collected at a pressure of 9.80 kPa what volume will the gas occupy if the pressure is changed to 9.40 kPa? • the pressure decreases from 9.8 to 9.4 kPa. (V will increase) V2 = V1 X P1/P2 (425mL/1) ( 9.8 kPa/9.4 kPa) = 443.0 mL • Calculate the pressure of a gas that occupies a volume of 125.0 mL, if at a pressure of 95.0 kPa, it occupies a volume of 219.0 mL. • the volume decreases from 219.0 mL to 125.0mL.(P will increase) P2 = P1 X V1/V2 (95.0 kPa/1) (219.0 mL/125.0mL) = 166.0 kPa

26. Charles’s Law If n and P are constant, then V α T V and T are directly proportional. V1 V2 = T1 T2 • If one temperature goes up, the volume goes up! Jacques Charles (1746-1823). Isolated boron and studied gases. Balloonist.

27. Charles’s original balloon Modern long-distance balloon

28. Charles’s Law

29. Charles’s Law; relates Temperature and Volume • In an ideal gas, with constant pressure, if the temperature increases the volume will increase. • Charles’s Law: at a constant pressure, the volume of a gas is directly proportional to its Kelvin temperature. (you must express temp in degrees K) • New volume =old volume X degree K temp change V2 = V1 X T2/T1 • New temperature = old temp (K) X volume change T2 = T1 X V2/V1 - Mentally decide if the new volume is larger or smaller than the old, arrange the pressure ratio accordingly (If larger use fraction greater than 1, If smaller use fraction less than 1)

30. Charles’s Law Example Problem • What volume will a sample of nitrogen occupy at 28.0 degrees C if the gas occupies a volume of 457 mL at a temperature of 0.0 degrees C? Assume the pressure remains constant. convert temp to K K= 273 + degrees C K = 273 + 28.0 degrees C = 301 K and K = 273 + 0.0 C = 273 K (Temp increase means Volume increase: Ratio > than 1) New Volume = (457mL/1) (301 k/273 k) = 504 mL

31. Charles’s Law Example Problem #2 • If a gas occupies a volume of 733 mL at 10.0 dC, at what temperature in C degrees, will it occupy a volume of 1225 mL if the pressure remains constant? (increased volume means increased temperature) Convert °C to °K (°K = °C + 273) 10.0 °C = 283 °K T2 = T1 X V2/V1 = (283 °K/1) (1225 mL/733 mL) = 473 °K Convert °K to °C °C = 473 K – 273 = 200 °C

32. Practice use of Boyle’s Law • Complete the problem solving packet, Pg 12-16; problems 1-5 all parts • Show all work • Label all units • Due tomorrow (complete for homework if necessary)

33. Practice use of Charles’s Law • Complete the problem solving packet, Pg 17-20 problems 1-3 all parts • Show all work • Label all units • Due tomorrow (complete for homework if necessary)

34. Combined Gas Law: when both temperature and pressure change occur • Boyle’s and Charles’s laws used together make the combined gas law. • A pressure ratio and a Kelvin temperature ratio are needed to calculate the new volume. New Volume = old volume X pressure ratio X Kelvin temperature ratio V2 =V1(P1/P2)(T2/T1) *STP=273K and 101.3kPa • First: Construct a press-volume-temp data table

35. Practice: Combined Gas Law • Calculate the volume of a gas at STP if 502 mL of the gas are collected at 29.7 C and 96.0 kPa • Convert Celsius to Kelvin temps. ( 29.7 + 273 = 302.7) • Organize the data in the table. Calculate: V2 =V1(P1/P2)(T2/T1) V2 = 502 mL ( 96.0kPa/ 101.3kPa) (273K/ 302.7k) V2 = 429 mL

36. Try this on your own! • If 400 ml of oxygen are collected at 20.0C, and the atmospheric pressure is 94.7 kPa, what is the volume of the oxygen at STP? V2 =V1(P1/P2)(T2/T1) = 400 mL (94.7 kPa/101.3 kPa) (273 k/293 K) = 348 mL

37. Homework: Complete Handout, Pg 78-79 • #’s 10-14, all parts • Show all of your work • label all of your units • DUE TOMORROW!!!

38. Gay-Lussac’s Law If n and V are constant, then P α T P and T are directly proportional. P1 P2 = T1 T2 • If one temperature goes up, the pressure goes up! Joseph Louis Gay-Lussac (1778-1850)

39. Gas Pressure, Temperature, and Kinetic Molecular Theory P proportional to T

40. Gay- Lussac’s Law: relates Temperature and pressure • The Pressure of a gas is DIRECTLY proportional to the absolute temperature when the volume is unchanged. • P1T2=P2T1 or P1=P2 T1 T2 • When temp increases, pressure increases • Must use Kelvin temperatures!

41. Gay- Lussac’s Law Example A cylinder of gas has a pressure of 4.40 atm at 25 C. At what temperature, in Celsius, will it reach a pressure of 6.50 atm? P1 = 4.40atmP1T2=P2T1 T2= ? K and ?C 298 X 6.50 atm= 440 K P2 = 6.50 atm 4.40 atm T1 = 25+273=298 K 440.K = (440. – 273) C =167°C

42. Practice Problems; Gay- Lussac’s Law • Complete the problem solving packet, Pg20-24, problems 1-3 all parts • Show all work • Label all units

43. Avogadro’s Law; relates volume to moles • Avogadro's Law states: for a gas at constant temperature and pressure, the volume is directly proportional to the number of moles of gas. • Avogadro's law relates the quantity of a gas and its volume. • According to Avogadro's Law: V1n2 = V2n1 • When any three of the four quantities in the equation are known, the fourth can be calculated. • For example, if n1, V1 and V2 are known, the n2 can be solved by the following equation: • n2  = V2 x (n1/V1)

44. Avogadro’s Law Practice • Example #1: 5.00 L of a gas is known to contain 0.965 mol. If the amount of gas is increased to 1.80 mol, what new volume will result (at an unchanged temperature and pressure)? • Answer: this time I'll use V1n2 = V2n1 • (5.00 L) (1.80 mol) = (x) (0.965 mol)

45. Avogadro’s Law Practice Example #2: A cylinder with a movable piston contains 2.00 g of helium, He, at room temperature. More helium was added to the cylinder and the volume was adjusted so that the gas pressure remained the same. How many grams of helium were added to the cylinder if the volume was changed from 2.00 L to 2.70 L? (The temperature was held constant.) Solution: 1) Convert grams of He to moles: 2.00 g / 4.00 g/mol = 0.500 mol 2) Use Avogadro's Law: V1/n1 = V2/n2 2.00 L / 0.500 mol = 2.70 L / x x = 0.675 mol 3) Compute grams of He added: 0.675 mol - 0.500 mol = 0.175 mol 0.175 mol x 4.00 g/mol = 0.7 grams of He added

46. Progression of Laws • Boyles', Charles', and Avogadro's laws combine to form the ideal gas law, which is the uber law of gases. • The ideal gas law can be manipulated to explain Dalton's law, partial pressure, gas density, and the mole fraction. It can also be used to derive the other gas laws.

47. Ideal Gas Law • The ideal gas law is an ideal law. It operates under a number of assumptions. • The two most important assumptions are that the molecules of an ideal gas do not occupy space and do not attract each other. • These assumptions work well at the relatively low pressures and high temperatures, but there are circumstances in the real world for which the ideal gas law holds little value.

48. Ideal Gas Law • Equation: PV = nRT P is pressure in kPa V is volume in cubic decimeters T is temperature in K n represents the number of moles of the gas R is a constant , using these units, is 8.31 L kPa/mol K (R can have different units when needed) • This equation can be used to determine the molecular mass of a gas • Moles (n) = mass(m)/ molecular mass(M) PV = mRT M

49. IDEAL GAS LAW P V = n R T Brings together gas properties. Can be derived from experiment and theory. BE SURE YOU KNOW THIS EQUATION!

50. Amount of Gas Present • Amount of gas present is related to its pressure, temperature and volume using the Ideal Gas Law • Applying the gas law allows for the calculation of the amount of gaseous reactants and products in reactions