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PY 131 Chapter 16: Heat Transfer

Heat Transfer

  • Heat moves due to temperature differences.

  • Heat energy always moves from hot to cold.

  • Heat is transferred from one object to another via three mechanisms:

    • Conduction

    • Convection

    • Radiation

  • During conduction the atoms/molecules of the object transferring the heat do not move.

    • Conduction is the only method of moving heat through a solid.

  • During convection the atoms/molecules do move.

    • Convection occurs in liquids and gases.

  • During radiation heat (energy) is transferred through space by electromagnetic waves (light) or gravitational waves.

Conduction

  • Conduction is the flow of energy between objects or from one object to another due to collisions between the atoms/molecules and without net motion of the material.

    • No net motion means the body does not move as a whole i.e. there is no bulk flow.

  • Conduction can occur in solids, liquid and gases.

  • In a solid the atoms are largely confined and collisions are the main mechanism by which the heat flows.

  • In a liquid or gas the heat flows due to collisions of the atoms/molecules but also atoms/molecules can diffuse.

  • Materials through which heat travels easily are called (thermal) conductors.

    • Examples include metals, diamond (diamond is 250% better thermal conductor than copper).

  • Materials through which heat travels with difficulty are called (thermal) insulators.

    • Examples include glass, wood, plastic, air.

EXAMPLE 1

If you hold one end of a metal bar against a piece of ice, the end in your hand will become cold. In which direction is energy moving?

  • From your hand to the ice

Convection

  • Convection is heat transfer through an object due to the bulk motion of the material.

  • Convection requires there be a net force on a fluid element.

  • Convection can occur in different ways depending upon the force e.g. buoyant convection or forced convection.

    • In buoyant convection, the force is buoyancy so buoyant convection requires there be gravity – without it buoyant convection cannot occur.

    • Forced convection is when you blow or pump the fluid.

  • Consider a ‘fluid element’ with density ρb

    • Here b stands for ‘bubble’.

  • The surrounding fluid has the same density ρ.

  • What happens if this element moves upward by an amount Δy?

  • The density will change to ρb +Δρb .

  • At the new location, the surrounding fluid has a density ρ +Δρ.

  • If ρb +Δρb < ρ+Δρ then the element will continue to rise due to the buoyancy force and the fluid is unstable to convection.

  • Since ρb = ρ the criterion for instability is that Δρb < Δρ or Δρb Δ y ≤ Δρ Δ y A buoyantly convecting fluid forms Bénard (convection) cells.

  • High-resolution images of the Sun show its surface is broken up into granules: http://www.youtube.com/watch?v=W_Scoj4HqCQ

  • The Bénard cells on the Sun are huge: each is ~1000 km across and lives for ~ 10 minutes.

  • Careful observations indicate there are also supergranuales which are of order 30,000 km in size.

    • It is thought these may be the imprint of deeper lying convective cells.

  • Convection is responsible for sea breezes.

    • The land heats the air above it better than the water heats the air above it.

    • The density of the air over the land decreases causing it to float (rise).

    • The air over the sea is pushed in by pressure forces in to replace it.

Newton’s Law of Cooling

  • Consider two points in space separated by a distance Δx and with a temperature difference ΔT.

  • The ratio of ΔT to Δx is called the temperature gradient.

    • ΔT/Δx

  • The temperature gradient (which is a vector) will cause an amount of heat ΔQ to flow between the points in a time Δt.

  • The thermal current I is

    • I= ΔQ / Δt

  • It is found from the experiment that the thermal current is proportional to the temperature gradient.

    • I ∝ - (ΔT/Δx)

    • The minus sign is because heat flows from hot to cold.

  • This relationship is called Newton’s Law of Cooling.

  • The larger the temperature difference, the faster a hot object loses energy or a cool object gains it.

  • As the object cools, the heat flow slows down.

  • In addition to the temperature gradient, the thermal current depends on the contact area and what the material is.

    • The smaller the contact area the smaller the heat flow.

    • Heat finds it harder to pass through some materials than others.

  • Newton’s Law of Cooling works well for conduction. For convective cooling it works if the cooling liquid/gas is pumped/forced/blown: if the convective cooling is buoyancy driven then it doesn’t work as well.

    • It doesn’t take into account the fluid speed.

EXAMPLE 1

Why does it take an ice cube longer to melt on a winter day than on a summer day?

  • The atmosphere is cooler

Radiation

  • Heat Transfer by Radiation is the transfer of heat via the emission and absorption of light.

  • All objects with a temperature emit light.

    • This is not the light reflected from a light source e.g. the Sun.

  • Usually, we don’t notice this radiation because, at typical everyday temperatures, the emitted light is mostly infrared.

    • It takes temperatures of ~ 500 Celsius before the emitted light starts to become visible light.

    • At very high temperatures the emitted light can be UV or X-rays.

  • The emission of radiation causes an object to cool.

    • it’s the emission of radiation into space that cools the Earth at night.

  • The temperature of an object is related to the frequency or wavelength of the light it emits which has the maximum intensity

  • This relationship is known as Wien's Displacement Law.

  • When radiation is incident upon an object, some of the light is absorbed, some is reflected, and some passes through.

    • The absorbed radiation will cause an increase in the object’s temperature.

    • The absorption of radiation emitted by the Sun heats the Earth during the day.

  • An object which absorbs all the radiation incident upon it is called a blackbody.

  • Objects which are good emitters of radiation are also good absorbers of radiation (and vice versa).

  • To make life complicated, the amount of radiation absorbed and emitted depends on the type of light.

    • Some objects reflect visible light well but absorb all the IR, for example.

  • Assuming a black object is black for all types of light, and a white object is white for all types of light, a black object radiates energy faster than a white object.

  • An object’s opacity is a measure of the amount of light it absorbs as light travels through the object.

  • The opacity can change with the ‘type’ of light.

    • an object (e.g. glass) can be very transparent to visible light but not transparent (opaque) to infrared or UV.

  • The opacity of the atmosphere is very important to astronomers.

    • If the atmosphere is opaque, a telescope can’t see through it.

The Greenhouse Effect

  • It is the difference of the opacity of the atmosphere to visible and infrared light which keeps Earth warmer than it should be given our distance from the Sun.

  • If Earth were a blackbody with no atmosphere it would have an average temperature of ~ +5 °C.

  • Given that Earth reflects about 30% of the incident sunlight, an Earth without an atmosphere would have an average temperature of ~ -20 °C.

  • Earth’s actual average temperature is ~ +15 °C.

  • The Sun emits a lot of its light as visible light. Visible light can largely pass through the atmosphere and be absorbed by the Earth causing Earth to be heated.

  • Earth emits most of its radiation as infrared light.

  • This should cool the Earth but the atmosphere is opaque to infrared light so energy gets absorbed.

  • The heated atmosphere radiates some of its energy back toward the Earth.

  • The net effect is that radiation finds it difficult to escape and the Earth is warmer than it would be if it could easily escape.

  • This is called the Greenhouse Effect.

    • Even though actual greenhouses work slightly differently.

  • The same effects occur on other planets or moons with atmospheres.

    • On Venus the Greenhouse Effect has runaway and the temperature is 450 °C.

  • The gases in Earth’s atmosphere which absorb most of the infrared radiation are water vapor and carbon dioxide.

  • The amount of these gases in the atmosphere changes over time due to natural processes such as volcanoes, ice ages, sun cycles etc.

    • It even changes over the cycle of the year.

  • Over the last 200 years the amount of carbon dioxide in the atmosphere has roughly doubled.

  • Since 1960 the average temperature of the Earth has increased by ~1 °C.

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PY 131 Chapter 16: Heat Transfer

Heat Transfer

  • Heat moves due to temperature differences.

  • Heat energy always moves from hot to cold.

  • Heat is transferred from one object to another via three mechanisms:

    • Conduction

    • Convection

    • Radiation

  • During conduction the atoms/molecules of the object transferring the heat do not move.

    • Conduction is the only method of moving heat through a solid.

  • During convection the atoms/molecules do move.

    • Convection occurs in liquids and gases.

  • During radiation heat (energy) is transferred through space by electromagnetic waves (light) or gravitational waves.

Conduction

  • Conduction is the flow of energy between objects or from one object to another due to collisions between the atoms/molecules and without net motion of the material.

    • No net motion means the body does not move as a whole i.e. there is no bulk flow.

  • Conduction can occur in solids, liquid and gases.

  • In a solid the atoms are largely confined and collisions are the main mechanism by which the heat flows.

  • In a liquid or gas the heat flows due to collisions of the atoms/molecules but also atoms/molecules can diffuse.

  • Materials through which heat travels easily are called (thermal) conductors.

    • Examples include metals, diamond (diamond is 250% better thermal conductor than copper).

  • Materials through which heat travels with difficulty are called (thermal) insulators.

    • Examples include glass, wood, plastic, air.

EXAMPLE 1

If you hold one end of a metal bar against a piece of ice, the end in your hand will become cold. In which direction is energy moving?

  • From your hand to the ice

Convection

  • Convection is heat transfer through an object due to the bulk motion of the material.

  • Convection requires there be a net force on a fluid element.

  • Convection can occur in different ways depending upon the force e.g. buoyant convection or forced convection.

    • In buoyant convection, the force is buoyancy so buoyant convection requires there be gravity – without it buoyant convection cannot occur.

    • Forced convection is when you blow or pump the fluid.

  • Consider a ‘fluid element’ with density ρb

    • Here b stands for ‘bubble’.

  • The surrounding fluid has the same density ρ.

  • What happens if this element moves upward by an amount Δy?

  • The density will change to ρb +Δρb .

  • At the new location, the surrounding fluid has a density ρ +Δρ.

  • If ρb +Δρb < ρ+Δρ then the element will continue to rise due to the buoyancy force and the fluid is unstable to convection.

  • Since ρb = ρ the criterion for instability is that Δρb < Δρ or Δρb Δ y ≤ Δρ Δ y A buoyantly convecting fluid forms Bénard (convection) cells.

  • High-resolution images of the Sun show its surface is broken up into granules: http://www.youtube.com/watch?v=W_Scoj4HqCQ

  • The Bénard cells on the Sun are huge: each is ~1000 km across and lives for ~ 10 minutes.

  • Careful observations indicate there are also supergranuales which are of order 30,000 km in size.

    • It is thought these may be the imprint of deeper lying convective cells.

  • Convection is responsible for sea breezes.

    • The land heats the air above it better than the water heats the air above it.

    • The density of the air over the land decreases causing it to float (rise).

    • The air over the sea is pushed in by pressure forces in to replace it.

Newton’s Law of Cooling

  • Consider two points in space separated by a distance Δx and with a temperature difference ΔT.

  • The ratio of ΔT to Δx is called the temperature gradient.

    • ΔT/Δx

  • The temperature gradient (which is a vector) will cause an amount of heat ΔQ to flow between the points in a time Δt.

  • The thermal current I is

    • I= ΔQ / Δt

  • It is found from the experiment that the thermal current is proportional to the temperature gradient.

    • I ∝ - (ΔT/Δx)

    • The minus sign is because heat flows from hot to cold.

  • This relationship is called Newton’s Law of Cooling.

  • The larger the temperature difference, the faster a hot object loses energy or a cool object gains it.

  • As the object cools, the heat flow slows down.

  • In addition to the temperature gradient, the thermal current depends on the contact area and what the material is.

    • The smaller the contact area the smaller the heat flow.

    • Heat finds it harder to pass through some materials than others.

  • Newton’s Law of Cooling works well for conduction. For convective cooling it works if the cooling liquid/gas is pumped/forced/blown: if the convective cooling is buoyancy driven then it doesn’t work as well.

    • It doesn’t take into account the fluid speed.

EXAMPLE 1

Why does it take an ice cube longer to melt on a winter day than on a summer day?

  • The atmosphere is cooler

Radiation

  • Heat Transfer by Radiation is the transfer of heat via the emission and absorption of light.

  • All objects with a temperature emit light.

    • This is not the light reflected from a light source e.g. the Sun.

  • Usually, we don’t notice this radiation because, at typical everyday temperatures, the emitted light is mostly infrared.

    • It takes temperatures of ~ 500 Celsius before the emitted light starts to become visible light.

    • At very high temperatures the emitted light can be UV or X-rays.

  • The emission of radiation causes an object to cool.

    • it’s the emission of radiation into space that cools the Earth at night.

  • The temperature of an object is related to the frequency or wavelength of the light it emits which has the maximum intensity

  • This relationship is known as Wien's Displacement Law.

  • When radiation is incident upon an object, some of the light is absorbed, some is reflected, and some passes through.

    • The absorbed radiation will cause an increase in the object’s temperature.

    • The absorption of radiation emitted by the Sun heats the Earth during the day.

  • An object which absorbs all the radiation incident upon it is called a blackbody.

  • Objects which are good emitters of radiation are also good absorbers of radiation (and vice versa).

  • To make life complicated, the amount of radiation absorbed and emitted depends on the type of light.

    • Some objects reflect visible light well but absorb all the IR, for example.

  • Assuming a black object is black for all types of light, and a white object is white for all types of light, a black object radiates energy faster than a white object.

  • An object’s opacity is a measure of the amount of light it absorbs as light travels through the object.

  • The opacity can change with the ‘type’ of light.

    • an object (e.g. glass) can be very transparent to visible light but not transparent (opaque) to infrared or UV.

  • The opacity of the atmosphere is very important to astronomers.

    • If the atmosphere is opaque, a telescope can’t see through it.

The Greenhouse Effect

  • It is the difference of the opacity of the atmosphere to visible and infrared light which keeps Earth warmer than it should be given our distance from the Sun.

  • If Earth were a blackbody with no atmosphere it would have an average temperature of ~ +5 °C.

  • Given that Earth reflects about 30% of the incident sunlight, an Earth without an atmosphere would have an average temperature of ~ -20 °C.

  • Earth’s actual average temperature is ~ +15 °C.

  • The Sun emits a lot of its light as visible light. Visible light can largely pass through the atmosphere and be absorbed by the Earth causing Earth to be heated.

  • Earth emits most of its radiation as infrared light.

  • This should cool the Earth but the atmosphere is opaque to infrared light so energy gets absorbed.

  • The heated atmosphere radiates some of its energy back toward the Earth.

  • The net effect is that radiation finds it difficult to escape and the Earth is warmer than it would be if it could easily escape.

  • This is called the Greenhouse Effect.

    • Even though actual greenhouses work slightly differently.

  • The same effects occur on other planets or moons with atmospheres.

    • On Venus the Greenhouse Effect has runaway and the temperature is 450 °C.

  • The gases in Earth’s atmosphere which absorb most of the infrared radiation are water vapor and carbon dioxide.

  • The amount of these gases in the atmosphere changes over time due to natural processes such as volcanoes, ice ages, sun cycles etc.

    • It even changes over the cycle of the year.

  • Over the last 200 years the amount of carbon dioxide in the atmosphere has roughly doubled.

  • Since 1960 the average temperature of the Earth has increased by ~1 °C.