Presentation is loading. Please wait.

Presentation is loading. Please wait.

HL1-4.ppt Gas Laws. 1.4.4: Apply Avogadro’s law to calculate reacting volumes of gases. 1.4.5 :Apply the concept of molar volume at standard temperature.

Published byBethany Summers Modified over 8 years ago

Similar presentations

Presentation on theme: "HL1-4.ppt Gas Laws. 1.4.4: Apply Avogadro’s law to calculate reacting volumes of gases. 1.4.5 :Apply the concept of molar volume at standard temperature."— Presentation transcript:

1 HL1-4.ppt Gas Laws

2 1.4.4: Apply Avogadro’s law to calculate reacting volumes of gases. 1.4.5 :Apply the concept of molar volume at standard temperature and pressure in calculations 1.4.6: Solve problems involving the relationship between temperature, pressure and volume for a fixed mass of an ideal gas. 1.4.7:Solve problems relating to the ideal gas equation: PV=nRT 1.4.8Analyze graphs relating to the ideal gas equation.

3 Review – Avogadro’s Law Avogadro’s Law: Equal volumes of gases at the same T & P contain the same number of molecules. (which means that coefficients in a balanced equation can be ‘read’ as volumes of gases)

4 Review – Molar Volume 1 mole of any gas takes up 22.4 dm 3 of space at STP Standard Temperature (273K or 0 o C) & Pressure (101 kPa or 1 atm) V STP = 22.4 dm 3 / mol Which can be rearranged… n = V STP / 22.4 dm 3 mol

5 Review – Molar Volume 1 mole of any gas takes up 22.4 dm 3 of space at STP Standard Temperature (273K or 0 o C) & Pressure (101 kPa or 1 atm) V STP = 22.4 dm 3 / mol Which can be rearranged… n = V STP / 22.4 dm 3 mol

6 Other applications of Avagadro’s law &/or Molar Volume: 1. Determine number of moles (or g) of a given volume of gas at STP. (1.4.2 # 3, part of 5, part of 7) 2. Determine volume of a known quantity (mol or g) of a gas at STP (1.4.2 # 4, part of # 10) 3. Calculate molar mass given information about moles (or g) and volume… and knowing molar volume (1.4.2 # 8) 4. Determine density of a gas at STP (1.4.2 # 9)

7 The Ideal Gas Law  Q – Can all gases be considered ‘ideal’?  Most real gases act ideally under normal conditions.  They tend to act less ideally when: They have high molar masses Why? They are at very high pressures Why? They are at very low temperatures Why?

8 Which of these gases would act the least ideally?

9 The Ideal Gas Law  PV=nRT where P = pressure in kPa V = volume in dm 3 (Litres) n = moles of gas R = universal gas constant ○ (8.314 kPa dm 3 mol -1 K -1 ) ○ (0.0821 if you’re using atm, which you won’t in IB…) T = temperature in K

10 Pressure - You want pressure in kPa… What do you do if it is given in mm Hg? What do you do if it is given in atm?

11 The Ideal Gas Law  As long as you can remember PV=nRT, you can derive all of the other gas laws.  If the number of moles of gas is not changing, we can just solve for n. n=PV/RT  Since the moles aren’t changing, we can set the right side of the equation equal to itself. P 1 V 1 /RT 1 = P 2 V 2 /RT 2 and because R is the same… P 1 V 1 /T 1 = P 2 V 2 /T 2 (combined gas law)

12 If you have a problem where one of these variables is held constant, you can simplify the combined gas law by eliminating that variable: P 1 V 1 / T 1 = P 2 V 2 / T 2 P 1 V 1 = P 2 V 2 V 1 / T 1 = V 2 / T 2 P 1 / T 1 = P 2 / T 2

13 We now have this collection of gas laws:  P 1 V 1 /T 1 =P 2 V 2 /T 2 (Combined Gas Law)  P 1 V 1 =P 2 V 2 (Boyle’s Law)  V 1 /T 1 =V 2 /T 2 (Charles’ Law)  P 1 /T 1 =P 2 /T 2 (Gay Lussac’s Law)

14 Gas Laws TIP #1: Always use K for temperatures because it is an “absolute” scale (no negatives)T Gas Laws TIP #2: If P or V are on both sides, the units don’t matter as long as they are the same on both sides. Gas Laws TIP #3: You must be VERY careful with your units when using the Ideal Gas Law!

15 Your Assignment:  Read pp. 21-26  Do Ex 1.4.3 on pp. 25-26 # 1-10 Identify which gas law you are using to solve the problem… then solve the problem. Show your work…. (at minimum include the set up using some form of a gas law)

16

17 Charles Law  Charles's law is an experimental gas law which describes how gases tend to expand when heated. It was first published by French natural philosopher Joseph Louis Gay- Lussac in 1802, although he credits the discovery to unpublished work from the 1780s by Jacques Charles.gas lawgasesFrench natural philosopherJoseph Louis Gay- LussacJacques Charles

18 Charles Law  T  V  The following is a more useful way of expressing this law.

19 Create a hypothesis for what happened here.

20 Here’s what really happened. 1. Workers used hot pressurized water to clean the tanker car. 2. Tank was drained. 3. Door was closed and tanker was left overnight. 4. Temperature inside the car plummeted overnight. 5. V/T=V/T (Temp goes down, Volume must go down also)

Download ppt "HL1-4.ppt Gas Laws. 1.4.4: Apply Avogadro’s law to calculate reacting volumes of gases. 1.4.5 :Apply the concept of molar volume at standard temperature."

Similar presentations

Combined Gas Law Avogadro’s Principle

Combined Gas Law Avogadro’s Principle
Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro

Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro
HL1-8.ppt Gas Laws HL Chemistry.

HL1-8.ppt Gas Laws HL Chemistry.
GASES. 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. 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.
Section 2 – The Gas Laws Scientists have been studying physical properties of gases for hundreds of years. In 1662, Robert Boyle discovered that gas.

Section 2 – The Gas Laws Scientists have been studying physical properties of gases for hundreds of years. In 1662, Robert Boyle discovered that gas.
Gases Chapters 12.1 and 13.

Gases Chapters 12.1 and 13.
1 Pressure Pressure: Force applied per unit area. Barometer: A device that measures atmospheric pressure. Manometer: A device for measuring the pressure.

1 Pressure Pressure: Force applied per unit area. Barometer: A device that measures atmospheric pressure. Manometer: A device for measuring the pressure.
Gas Laws Chapter 10.

Gas Laws Chapter 10.
TOPICS 1.Intermolecular Forces 2.Properties of Gases 3.Pressure 4.Gas Laws – Boyle, Charles, Lussac 5.Ideal Gas Law 6.Gas Stoichiometry 7.Partial Pressure.

TOPICS 1.Intermolecular Forces 2.Properties of Gases 3.Pressure 4.Gas Laws – Boyle, Charles, Lussac 5.Ideal Gas Law 6.Gas Stoichiometry 7.Partial Pressure.
III. Ideal Gas Law (p. 334-335, 340-346) Ch. 10 & 11 - Gases.

III. Ideal Gas Law (p , ) Ch. 10 & 11 - Gases.
February 5, 2008  Go over Charles’s Law and Avogadro’s Law Homework  Introduce Combined Gas Law  Introduce Ideal Gas Law  Work Sample Problems  HOMEWORK:

February 5, 2008  Go over Charles’s Law and Avogadro’s Law Homework  Introduce Combined Gas Law  Introduce Ideal Gas Law  Work Sample Problems  HOMEWORK:
Volume (V)  The volume of a gas is simply the volume of the container it is contained in.  The metric unit of volume, liter (L), is often used. 

Volume (V)  The volume of a gas is simply the volume of the container it is contained in.  The metric unit of volume, liter (L), is often used. 
The Combined Gas Law Expresses the relationship between pressure, volume, and temperature of a fixed amount of gas. PV/T = k or P1V1/T1 = P2V2/T2 Charles’

The Combined Gas Law Expresses the relationship between pressure, volume, and temperature of a fixed amount of gas. PV/T = k or P1V1/T1 = P2V2/T2 Charles’
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.

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.
Chapter 13 The Gas Laws. Robert Boyle studied how gas volume varied with changes in pressure.

Chapter 13 The Gas Laws. Robert Boyle studied how gas volume varied with changes in pressure.
Gases Chapter 14.

Gases Chapter 14.
Lesson 13 Gases and Vapors Anything in black letters = write it in your notes (‘knowts’)

Lesson 13 Gases and Vapors Anything in black letters = write it in your notes (‘knowts’)
I. Characteristics of a Gas A) Gases assume the shape and volume of a container. B) Gases are the most compressible of all the states of matter. C) Gases.

I. Characteristics of a Gas A) Gases assume the shape and volume of a container. B) Gases are the most compressible of all the states of matter. C) Gases.
Gas Laws.

Gas Laws.
Gases and the Gas Laws Mythbuster – cansI Intro to gas laws

Gases and the Gas Laws Mythbuster – cansI Intro to gas laws

Similar presentations

Ads by Google