PAL (IGCSE) – PHYSICS
Section 2 Thermal Physics
Thermal Physics
PAL (IGCSE) Single Science
Revision Book - Section 2
Name: ______
Teacher: ______
Syllabus Content______
Syllabus Details______
2.1 Simple kinetic molecular model of matter
2.1 (a) States of matter
Core
• State the distinguishing properties of solids, liquids and gases
2.1 (b) Molecular model
Core
• Describe qualitatively the molecular structure of solids, liquids and gases
• Interpret the temperature of a gas in terms of the motion of its molecules
• Describe qualitatively the pressure of a gas in terms of the motion of its molecules
• Describe qualitatively the effect of a change of temperature on the pressure of a gas at constant volume
• Show an understanding of the random motion of particles in a suspension as evidence for the kinetic molecular model of matter
• Describe this motion (sometimes known as Brownian motion) in terms of random molecular
Bombardment
· Smoke (oil droplets) are seen to move randomly
· This motion is evidence that the air particles are also moving randomly and colliding with the smoke droplets
· The air particles cannot be seen but their motion can be understood by the smoke droplets which can be seen
Supplement
• Relate the properties of solids, liquids and gases to the forces and distances between molecules and to the motion of the molecules
Property / Solid / Liquid / GasForces between particles / Strong bonds (strong forces) / Strong bonds (strong forces) / Essentially no bonding (v-weak forces)
Distances between particles / Fixed and short / Short but not fixed / Long
Motion of particles / Vibrating only / Vibrating and freely moving / Vibrating and freely moving
• Show an appreciation that massive particles may be moved by light, fast-moving molecules
2.1 (c) Evaporation
Core
• Describe evaporation in terms of the escape of more-energetic molecules from the surface of a liquid
• Relate evaporation to the consequent cooling
Supplement
• Demonstrate an understanding of how temperature, surface area and draught over a surface influence evaporation
Factor / InfluenceTemperature / Increases evaporation as more particles have sufficient kinetic energy to “escape” the surface
Draught / Increases evaporation as “removes” high KE particles from above the surface of the liquid
Surface area / Increases evaporation as more surface for particles to “escape” from
2.1 (d) Pressure changes
Core
• Relate the change in volume of a gas to change in pressure applied to the gas at constant temperature
Supplement
• Recall and use the equation pV = constant at constant temperature
2.2 Thermal properties
2.2 (a) Thermal expansion of solids, liquids and gases
Core
• Describe qualitatively the thermal expansion of solids, liquids and gases
Solids
· As the temperature increases the bonds in the solid vibrate more
· The average separation between particles increases and so the bulk solid expands
Liquids
· As the temperature increases the motion of the particles increase and so the kinetic energy
· The average separation between the particles increases so the volume of the bulk liquid increases
Gases
· The volume / dimensions of a gas are fixed by the container
· As the temperature increases the motion of the particles increase and so the kinetic energy
· The particles will collide with the container with more force and more often
· If the container dimensions are free to change the volume will increase
• Identify and explain some of the everyday applications and consequences of thermal expansion
State / Application / ConsequenceSolid / Railway lines
Jam jar lids / Railway lines to space to expand at the end of the line
If heated can be removed more easily
Liquid / In thermometers / As the liquid expands on heating this property can be used to measure temperature
Gas / Car tyres / After a long journey the pressure in your car tyres will increase as they become hot when driving
• Describe qualitatively the effect of a change of temperature on the volume of a gas at constant pressure
Supplement
• Show an appreciation of the relative order of magnitude of the expansion of solids, liquids and gases
State / Order of magnitude of expansionSolid / Small
Liquid / Small
Gas / Big
2.2 (b) Measurement of temperature
Core
• Appreciate how a physical property that varies with temperature may be used for the measurement of temperature, and state examples of such properties
Physics property / Effect of temperature / ExampleVolume of a liquid / Increases with increasing temperature / Mercury in glass thermometer
Resistance / Increases with temperature / Resistance thermometer
• Recognise the need for and identify fixed points
Fixed Points:
· Used to calibrate thermometers
· Boiling and melting water can be used as these 2 changes occur at fixed temperatures
· The thermometer can be placed in boiling water to make the 100oC mark and then ice to make the 0oC mark
• Describe the structure and action of liquid-in-glass thermometers
Supplement
• Demonstrate understanding of sensitivity, range and linearity
• Describe the structure of a thermocouple and show understanding of its use for measuring high temperatures and those that vary rapidly
Thermocouple Thermometer
· Consists of two metals connected as shown
· When one junction between the two metal types is at a higher temperature than the other a voltage is produced
· This voltage is dependent on the temperature difference between the junctions
· They have a very large temperature range and can record temperatures very quickly
2.2 (c) Thermal capacity
Core
• Relate a rise in the temperature of a body to an increase in internal energy
Internal Energy = Random Kinetic Energy + Potential Energy of the particles
· If temperature rises this indicates that the Kinetic energy of the particles has increased
· If the kinetic energy of the particles increases so does the internal energy
• Show an understanding of the term thermal capacity
Supplement
• Describe an experiment to measure the specific heat capacity of a substance
· Measure the temperature of a material before and after heating
· Measure the energy input from heating by measuring the voltage, current and time
· Remember that the block should be insulated as energy will be lost to the surroundings
2.2 (d) Melting and boiling
Core
• Describe melting and boiling in terms of energy input without a change in temperature
• State the meaning of melting point and boiling point
Melting point: The temperature at which solid and liquid phases both exist in equilibrium
Boiling point: The temperature at which a substance changes from a liquid to a gas throughout the bulk of the liquid
• Describe condensation and solidification
Condensation: As the kinetic energy of particles decreases the attractive forces between them “pull” them together into droplets. Bonds are formed.
Solidification: As the kinetic energy of particles decreases permanent bonds form between the particles so they are no longer able to move freely.
Supplement
• Distinguish between boiling and evaporation
Property / Boiling / EvaporationTemperature / Only at the boiling point / At all temperatures
Location / Throughout the liquid / Only at the surface
Particles / All particles / Only the particles with sufficient kinetic energy
Temperature of liquid / Remains the same / Reduces
• Use the terms latent heat of vaporisation and latent heat of fusion and give a molecular interpretation of latent heat
LATENT HEAT OF VAPORISATION: Energy change associated with a substance
Boiling or Condensing
LATENT HEAT OF FUSION: Energy change associated with a substance
Melting or Solidifying
Molecular Interpretation: At a phase transition bonds are being broken or
formed. This gives an associated intake or release of energy.
• Describe an experiment to measure specific latent heats for steam and for ice
SPECIFIC LATENT HEAT OF STEAM
· Take a volume of liquid to its boiling point
· Measure the mass of the liquid
· Boil the water for a fixed period and calculate the energy input by measuring the voltage and current for the heater
· Record the mass of the liquid after heating and calculate the mass turned to a gas
· SPECIFIC LATENT HEAT OF ICE
· Heat the ice until it starts to melt
· Capture the melted ice in the beaker on the balance
· Heat for a fixed length of time and calculate the energy input by measuring the voltage and current supplied to the heater
· Measure the mass of water melted in that period
2.3 Transfer of thermal energy
2.3 (a) Conduction
Core
• Describe experiments to demonstrate the properties of good and bad conductors of heat
· Coins or other objects can be attached to a object to be tested
· One end of the object is then heated
· The ability of the object to conduct heat can be judged by how quickly the wax melts and so coins are released
Supplement
• Give a simple molecular account of heat transfer in solids
2.3 (b) Convection
Core
• Relate convection in fluids to density changes and describe experiments to illustrate convection
2.3 (c) Radiation
Core
• Identify infra-red radiation as part of the electromagnetic spectrum
Supplement
• Describe experiments to show the properties of good and bad emitters and good and bad absorbers of infra-red radiation
PROPERTIES OF ABSORBERS PROPERTIES OF EMMITERS
2.3 (d) Consequences of energy transfer
Core
• Identify and explain some of the everyday applications and consequences of conduction, convection and radiation
Energy Transfer / Applications / ConsequencesConduction / Saucepan or wok / Made of copper or other good conductors
Convection / Air conditioner / Normally placed on the ceiling as cold air drops
Radiation / Paint / In hot climates houses are painted white
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