Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Gas Laws Do Now read pages 70-71. The Gas Laws What happens if the Pressure and Volume are changed and constant temperature.

Published byBeatrix Fowler Modified over 8 years ago

Similar presentations

Presentation on theme: "The Gas Laws Do Now read pages 70-71. The Gas Laws What happens if the Pressure and Volume are changed and constant temperature."— Presentation transcript:

1 The Gas Laws Do Now read pages 70-71

2 The Gas Laws What happens if the Pressure and Volume are changed and constant temperature

3 Pressure – A reminder Pressure is defined as the normal (perpendicular) force per unit area P = F/A It is measured in Pascals, Pa (N.m -2 )

4 Pressure – A reminder What is origin of the pressure of a gas?

5 Pressure – A reminder Collisions of the gas particles with the side of a container give rise to a force, which averaged of billions of collisions per second macroscopically is measured as the pressure of the gas Change of momentum

6 The behaviour of gases – Boyles Law When we compress (reduce the volume) a gas at constant temperature, what happens to the pressure? Why? Let’s do it!

7 The behaviour of gases When we compress (reduce the volume) a gas at constant temperature, what happens to the pressure? Why? pV = constant

8 The Boyle’s laws – copy We have found experimentally that; At constant temperature, the pressure of a fixed mass of gas is inversely proportional to its volume. If the volume halves the pressure doubles p α 1/V or pV = constant This is known as Boyle’s law

9 Explaining the behaviour of gases When we compress (reduce the volume) a gas at constant temperature, the pressure increases. Why?

10 Explaing the behaviour of gases When we compress (reduce the volume) a gas at constant temperature, the pressure increases. Why? A smaller volume increases the likelihood of a particle colliding with the container walls. Boyle’s Law

11 The Gas Laws Do Q1-3 page 71

12 pV = constant p 1 V 1 = p 2 V 2 (at constant temp) Can you answer the questions that Mr Porter is giving you?

13 Do Now finish Q2 p71 p 1 V 1 = p 2 V 2 In a vertical cylinder. The initial pressure of the trapped air is 1.0 x 10 5 Pa. The volume of the air decreases from 860 cm 3 to 645 cm 3 The temperature is constant. Calculate the final pressure.

14 Learning today Pressure Law Describe qualitatively the effect of a change of temperature on the pressure of a gas at constant volume Charles’ Law Describe qualitatively the effect of a change of temperature on the volume of a gas at constant pressure

15 p 1 V 1 = p 2 V 2 In a Vertical cylinder. The initial pressure of the trapped air is 1.0 x 10 5 Pa. The volume of the air decreases from 860 cm 3 to 645 cm 3 The temperature is constant. Calculate the final pressure.

16 Graph y-axis labelled θ / 0 C[1] plots occupying at least half of grid on suitable scale start at about 50 0 C on the y - axis[1] all plots correct to ½ square[1] well judged single, smooth curve line, not ‘point-to-point’ [1] thin line [1]

17 Graph Mark scheme

18 The behaviour of gases- Pressure Law http://phet.colorado.edu/sims/ideal-gas/gas-properties.jnlp Gas Laws http://phet.colorado.edu/sims/ideal-gas/gas-properties.jnlp Gas Laws When we heat a gas at constant volume, what happens to the pressure? Why? Let’s do it!

19 The behaviour of gases http://phet.colorado.edu/sims/ideal-gas/gas-properties.jnlp http://phet.colorado.edu/sims/ideal-gas/gas-properties.jnlp When we heat a gas at constant volume, what happens to the pressure? Why? P α T (if T is in Kelvin)

20 The Pressure law- copy Gas Laws Gas Laws At constant volume, the pressure of a fixed mass of gas is proportional p α T or p/T = constant This is known as the Pressure law If T is in Kelvin

21 Explaining the behaviour of gases http://phet.colorado.edu/sims/ideal-gas/gas-properties.jnlp http://phet.colorado.edu/sims/ideal-gas/gas-properties.jnlp When we heat a gas at constant volume, the pressure increases. Why?

22 Explaining the behaviour of gases When we heat a gas at constant volume, the pressure increases. Why? Increased average kinetic energy of the particles means there are more collisions with the container walls in a period of time and an increase in pressure. Pressure Law

23 The Results P T K P T o C A value for absolute zero

24 The Charles’ Law copy At constant pressure, the volume of a fixed mass of gas is proportional to its temperature; V α T or V/T = constant This is known as Charles’ law When the conditions are changed V 1 /T 1 = V 2 /T 2 If T is in Kelvin

25 Explaing the behaviour of gases When we heat a gas a constant pressure, the volume increases. Why?

26 Explaining the behaviour of gases When we heat a gas a constant pressure, the volume increases. Why? Increasing the volume reduces the chance of particles colliding with the container walls, so the pressure remains constant. Charles Law

27 The Results V T K V T o C A value for absolute zero

28 Absolute Zero and the Kelvin Scale w Charles’ Law and the Pressure Law suggest that there is a lowest possible temperature that substances can go w This is called Absolute Zero w The Kelvin scale starts at this point and increases at the same scale as the Celsius Scale

29 w Therefore -273 o C is equivalent to 0 K w ∆1 o C is the same as ∆1 K w To change o C to K, add 273 w To change K to o C, subtract 273

30 Questions! Homework Graph question. Due Monday 12 th March

31 The equation of state By combining these three laws pV = constant V/T = constant p/T = constant We get pV/T = constant Or p 1 V 1 =p 2 V 2 T 1 T 2 Remember, T must be in Kelvin

32 The Results P V P 1/ V PV P

33 An example At the top of Mount Everest the temperature is around 250K, with atmospheric pressure around 3.3 x 10 4 Pa. At sea level these values are 300K and 1.0 x 10 5 Pa respectively. If the density of air at sea level is 1.2 kg.m -3, what is the density of the air on Mount Everest? “Physics”, Patrick Fullick, Heinemann

34 An example At the top of Mount Everest the temperature is around 250K, with atmospheric pressure around 3.3 x 10 4 Pa. At seas level these values are 300K and 1.0 x 10 5 Pa respectively. If the density of air at sea level is 1.2 kg.m -3, what is the density of the air on Mount Everest? Take 1kg of air at sea level Volume = mass/density = 1/1.2 = 0.83 m 3. Therefore at sea level p 1 = 1.0 x 10 5 Pa, V 1 = 0.83 m 3, T 1 = 300K.

35 An example At the top of Mount Everest the temperature is around 250K, with atmospheric pressure around 3.3 x 10 4 Pa. At seas level these values are 300K and 1.0 x 10 5 Pa respectively. If the density of air at sea level is 1.2 kg.m -3, what is the density of the air on Mount Everest? Therefore at sea level p 1 = 1.0 x 10 5 Pa, V 1 = 0.83 m 3, T 1 = 300K. At the top of Mount Everest p 2 = 3.3 x 10 4 Pa, V 2 = ? m 3, T 1 = 250K.

36 An example At the top of Mount Everest the temperature is around 250K, with atmospheric pressure around 3.3 x 10 4 Pa. At seas level these values are 300K and 1.0 x 10 5 Pa respectively. If the density of air at sea level is 1.2 kg.m -3, what is the density of the air on Mount Everest? Therefore at sea level p 1 = 1.0 x 10 5 Pa, V 1 = 0.83 m 3, T 1 = 300K. At the top of Mount Everestp 2 = 3.3 x 10 4 Pa, V 2 = ? m 3, T 1 = 250K. p 1 V 1 /T 1 = p 2 V 2 /T 2 (1.0 x 10 5 Pa x 0.83 m 3 )/300K = (3.3 x 10 4 Pa x V 2 )/250K V 2 = 2.1 m 3, This is the volume of 1kg of air on Everest Density = mass/volume = 1/2.1 = 0.48 kg.m -3.

37 pV= constant T

38 The equation of state of an ideal gas Experiment has shown us that pV = nR T p - pressure (Pa) V - volume (m 3 ) n - number of mols R - molar gas constant ( 8.31 J mol -1 K -1 ) T - Temperature (K) Remember, T must be in Kelvin

39 Sample question A container of hydrogen of volume 0.1m 3 and temperature 25°C contains 3.20 x 10 23 molecules. What is the pressure in the container? K.A.Tsokos “Physics for the IB Diploma” 5 th Edition

40 Sample question A container of hydrogen of volume 0.1m 3 and temperature 25°C contains 3.20 x 10 23 molecules. What is the pressure in the container? # moles = 3.20 x 10 23 /6.02 x 10 23 = 0.53 K.A.Tsokos “Physics for the IB Diploma” 5 th Edition

41 Sample question A container of hydrogen of volume 0.1m 3 and temperature 25°C contains 3.20 x 10 23 molecules. What is the pressure in the container? # moles = 3.20 x 1023/6.02 x 1023 = 0.53 P = RnT/V = (8.31 x 0.53 x 298)/0.1 = 1.3 x 10 4 N.m -2 K.A.Tsokos “Physics for the IB Diploma” 5 th Edition

42 An Ideal Gas w Is a theoretical gas that obeys the gas laws w And thus fit the ideal gas equation exactly

43 Real Gases w Real gases conform to the gas laws under certain limited conditions w But they condense to liquids and then solidify if the temperature is lowered w Furthermore, there are relatively small forces of attraction between particles of a real gas w This is not the case for an ideal gas

Download ppt "The Gas Laws Do Now read pages 70-71. The Gas Laws What happens if the Pressure and Volume are changed and constant temperature."

Similar presentations

The kinetic theory of gases and the gas laws. Kinetic theory/ideal gas We can understand the behaviour of gases using a very simple model, that of an.

The kinetic theory of gases and the gas laws. Kinetic theory/ideal gas We can understand the behaviour of gases using a very simple model, that of an.
Gas Laws Law of Combining Gas Volumes The volume of gases taking part in a chemical reaction show simple whole number ratios to one another when those.

Gas Laws Law of Combining Gas Volumes The volume of gases taking part in a chemical reaction show simple whole number ratios to one another when those.
Pressure in Gases (Ideal Gases) Objectives (a) state Boyle’s law.

Pressure in Gases (Ideal Gases) Objectives (a) state Boyle’s law.
Honors Chem Chapters 10, 11, and 12. Kinetic Molecular Theory (KMT) Molecules are constantly in motion and collide with one another and the wall of a.

Honors Chem Chapters 10, 11, and 12. Kinetic Molecular Theory (KMT) Molecules are constantly in motion and collide with one another and the wall of a.
Gas Laws Chapter 14. Properties of Gases  Gases are easily compressed because of the space between the particles in the gas.

Gas Laws Chapter 14. Properties of Gases  Gases are easily compressed because of the space between the particles in the gas.
1 CHAPTER 12 Gases and the Kinetic-Molecular Theory.

1 CHAPTER 12 Gases and the Kinetic-Molecular Theory.
Physical Properties of Gases

Physical Properties of Gases
4.3.4 Ideal Gases.

4.3.4 Ideal Gases.
Gas Laws Quantitative Chemistry. Measurement of Molar Quantities 1 mole of a substance contains 6.02 x 10 23 particles.

Gas Laws Quantitative Chemistry. Measurement of Molar Quantities 1 mole of a substance contains 6.02 x particles.
Ideal Gases K Warne. The Gas Phase Covered in this presentation  Kinetic Theory of Matter - solids, liquids & gasses Boyle's law Kelvin & Celsius Temperatures.

Ideal Gases K Warne. The Gas Phase Covered in this presentation  Kinetic Theory of Matter - solids, liquids & gasses Boyle's law Kelvin & Celsius Temperatures.
Explanation Gas pressure is caused by collisions of gas molecules on the wall of the container. The molecule collide with one other , with the walls of.

Explanation Gas pressure is caused by collisions of gas molecules on the wall of the container. The molecule collide with one other , with the walls of.
The Gas Laws.

The Gas Laws.
1 Gases Chapter 12. 2 Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.

1 Gases Chapter Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.
3.2: The Gas Laws.

3.2: The Gas Laws.
Chapter 13 - GASES. Properties of gases 1.are compressible 2.occupy all available volume 3.one mole of gas at 0 o C and 1 atm pressure occupies 22.4 liters.

Chapter 13 - GASES. Properties of gases 1.are compressible 2.occupy all available volume 3.one mole of gas at 0 o C and 1 atm pressure occupies 22.4 liters.
Gases Notes. 12.1 A. Physical Properties: 1.Gases have mass. The density is much smaller than solids or liquids, but they have mass. (A full balloon weighs.

Gases Notes A. Physical Properties: 1.Gases have mass. The density is much smaller than solids or liquids, but they have mass. (A full balloon weighs.
The Gas Laws Section 3.2.  What happens to your lungs when you take a deep breath?

The Gas Laws Section 3.2.  What happens to your lungs when you take a deep breath?
1 Gases Chapter 12. 2 Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.

1 Gases Chapter Properties of Gases Expand to completely fill their container Take the Shape of their container Low Density –much less than solid.
Gas Laws. Gas Pressure ____________ is defined as force per unit area. Gas particles exert pressure when they ____________ with the walls of their container.

Gas Laws. Gas Pressure ____________ is defined as force per unit area. Gas particles exert pressure when they ____________ with the walls of their container.
Thermal Physics Topic 3.2 Modelling Gases Courtesy to Greengates school in mexico.

Thermal Physics Topic 3.2 Modelling Gases Courtesy to Greengates school in mexico.

Similar presentations

Ads by Google