Specific Heat Capacity and Latent Heat AS level
![Specific Heat Capacity and Latent Heat AS level Physics Notes on: “Calculations involving change Specific Heat Capacity and Latent Heat AS level Physics Notes on: “Calculations involving change](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-1.jpg)
![Heat Travel Revision • Heat travels from hot to cold • The bigger the Heat Travel Revision • Heat travels from hot to cold • The bigger the](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-2.jpg)
![Internal Energy • The internal energy (sometimes called the random thermal energy) of a Internal Energy • The internal energy (sometimes called the random thermal energy) of a](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-3.jpg)
![Internal Energy • Potential energy is due to the interaction of neighbouring particles. • Internal Energy • Potential energy is due to the interaction of neighbouring particles. •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-4.jpg)
![Internal Energy • Kinetic energy is due to the movement of the particles in Internal Energy • Kinetic energy is due to the movement of the particles in](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-5.jpg)
![Specific Heat Capacity • When you give heat energy to a substance it gets Specific Heat Capacity • When you give heat energy to a substance it gets](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-6.jpg)
![Specific Heat Capacity • It makes sense that – the more of it you Specific Heat Capacity • It makes sense that – the more of it you](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-7.jpg)
![The Equation DQ = mc. Dq m = mass (kg) c = specific heat The Equation DQ = mc. Dq m = mass (kg) c = specific heat](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-8.jpg)
![Definition • The Specific Heat Capacity (c) of a substance is the quantity of Definition • The Specific Heat Capacity (c) of a substance is the quantity of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-9.jpg)
![SHC - c • The biggest changes in temperature of a given mass of SHC - c • The biggest changes in temperature of a given mass of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-10.jpg)
![Water • Water has a very large SHC • 4200 J kg-1 K-1 • Water • Water has a very large SHC • 4200 J kg-1 K-1 •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-11.jpg)
![Water • It makes an excellent heat store. • To store heat you want Water • It makes an excellent heat store. • To store heat you want](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-12.jpg)
![Water • Water has a large SHC • Therefore is makes an excellent coolant. Water • Water has a large SHC • Therefore is makes an excellent coolant.](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-13.jpg)
![Latent Heat • Means ‘hidden heat’ • Is absorbed or evolved when a substance Latent Heat • Means ‘hidden heat’ • Is absorbed or evolved when a substance](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-14.jpg)
![Heating Ice • If ice is heated steadily and its temperature recorded at regular Heating Ice • If ice is heated steadily and its temperature recorded at regular](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-15.jpg)
![A Level Physics LOJ March 2004 A Level Physics LOJ March 2004](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-16.jpg)
![Latent Heat – hidden heat that does not register as a temperature rise • Latent Heat – hidden heat that does not register as a temperature rise •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-17.jpg)
![Work • The heat energy is used to do work against intermolecular forces. • Work • The heat energy is used to do work against intermolecular forces. •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-18.jpg)
![Equation • It makes sense that the more of the substance you have to Equation • It makes sense that the more of the substance you have to](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-19.jpg)
![Equation DQ = ml l = specific latent heat (J/kg) m = mass (kg) Equation DQ = ml l = specific latent heat (J/kg) m = mass (kg)](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-20.jpg)
![Definitions • Specific latent heat is the energy required to change the state of Definitions • Specific latent heat is the energy required to change the state of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-21.jpg)
![Calculations • The layout of calculations is important • Think about what is happening. Calculations • The layout of calculations is important • Think about what is happening.](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-22.jpg)
![Example • A kettle of power 2 k. W holds 2 litres of water Example • A kettle of power 2 k. W holds 2 litres of water](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-23.jpg)
![A kettle of power 2 k. W holds 2 litres of water at room A kettle of power 2 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-24.jpg)
![A kettle of power 2 k. W holds 2 litres of water at room A kettle of power 2 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-25.jpg)
![A kettle of power 2 k. W holds 2 litres of water at room A kettle of power 2 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-26.jpg)
![A kettle of power 3 k. W holds 2 litres of water at room A kettle of power 3 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-27.jpg)
![A kettle of power 3 k. W holds 2 litres of water at room A kettle of power 3 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-28.jpg)
![A kettle of power 3 k. W holds 2 litres of water at room A kettle of power 3 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-29.jpg)
![Summary • You should be able to understand what is happening to the particles Summary • You should be able to understand what is happening to the particles](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-30.jpg)
![Summary • If the substance is remote from its melting or boiling point it Summary • If the substance is remote from its melting or boiling point it](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-31.jpg)
![Summary • The amount of heat energy required to make a temperature change of Summary • The amount of heat energy required to make a temperature change of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-32.jpg)
![Summary • If the substance is at its boiling/melting point the energy given/taken away Summary • If the substance is at its boiling/melting point the energy given/taken away](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-33.jpg)
![Summary • If being taken away, again it will not change the vibration of Summary • If being taken away, again it will not change the vibration of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-34.jpg)
![Summary • You should be able to do calculations involving heat being given and/or Summary • You should be able to do calculations involving heat being given and/or](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-35.jpg)
![Summary • You should be able to define specific heat capacity and latent heat Summary • You should be able to define specific heat capacity and latent heat](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-36.jpg)
![AQA Exam Question 1. 00 kg water is brought to the boil inside an AQA Exam Question 1. 00 kg water is brought to the boil inside an](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-37.jpg)
![Calculate the rate at which energy is supplied to convert water to steam if Calculate the rate at which energy is supplied to convert water to steam if](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-38.jpg)
![b) Estimate the rate at which the temperature increases just before the water reaches b) Estimate the rate at which the temperature increases just before the water reaches](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-39.jpg)
![c) State and explain the main reason why the rate of increase in temperature c) State and explain the main reason why the rate of increase in temperature](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-40.jpg)
![AEB Question from 1984 – Typical synoptic question. • An X-ray tube is operating AEB Question from 1984 – Typical synoptic question. • An X-ray tube is operating](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-41.jpg)
![(a) If only 1% of the electrical power is converted to X-rays, at what (a) If only 1% of the electrical power is converted to X-rays, at what](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-42.jpg)
![(b) If the target has a mass of 0. 3 kg and is made (b) If the target has a mass of 0. 3 kg and is made](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-43.jpg)
![(c) What assumption have you made in calculating the value for part b? • (c) What assumption have you made in calculating the value for part b? •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-44.jpg)
- Slides: 44
![Specific Heat Capacity and Latent Heat AS level Physics Notes on Calculations involving change Specific Heat Capacity and Latent Heat AS level Physics Notes on: “Calculations involving change](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-1.jpg)
Specific Heat Capacity and Latent Heat AS level Physics Notes on: “Calculations involving change of energy DQ = mc. Dq where m is the mass of the substance, c is its specific heat capacity and Dq is the change in temperature DQ = ml where l is specific latent heat and m is the mass of substance changing state. “ A Level Physics LOJ March 2004
![Heat Travel Revision Heat travels from hot to cold The bigger the Heat Travel Revision • Heat travels from hot to cold • The bigger the](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-2.jpg)
Heat Travel Revision • Heat travels from hot to cold • The bigger the temperature difference the faster the rate of transfer A Level Physics LOJ March 2004
![Internal Energy The internal energy sometimes called the random thermal energy of a Internal Energy • The internal energy (sometimes called the random thermal energy) of a](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-3.jpg)
Internal Energy • The internal energy (sometimes called the random thermal energy) of a substance is the sum of – the kinetic energy and – the potential energy of its particles. A Level Physics LOJ March 2004
![Internal Energy Potential energy is due to the interaction of neighbouring particles Internal Energy • Potential energy is due to the interaction of neighbouring particles. •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-4.jpg)
Internal Energy • Potential energy is due to the interaction of neighbouring particles. • This is therefore very significant in solids and liquids but less so in gases. • In fact ideal gases have NO potential energy – just kinetic! A Level Physics LOJ March 2004
![Internal Energy Kinetic energy is due to the movement of the particles in Internal Energy • Kinetic energy is due to the movement of the particles in](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-5.jpg)
Internal Energy • Kinetic energy is due to the movement of the particles in the substance. • The faster they move – the higher the KE and – the higher the temperature A Level Physics LOJ March 2004
![Specific Heat Capacity When you give heat energy to a substance it gets Specific Heat Capacity • When you give heat energy to a substance it gets](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-6.jpg)
Specific Heat Capacity • When you give heat energy to a substance it gets hotter if the heat is used to increase the KE of the particles. • How much hotter depends on two things: – Its mass and – What it is made of A Level Physics LOJ March 2004
![Specific Heat Capacity It makes sense that the more of it you Specific Heat Capacity • It makes sense that – the more of it you](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-7.jpg)
Specific Heat Capacity • It makes sense that – the more of it you have the more energy you would have to give it to raise the temperature a certain amount of a substance and that – different materials would need different amounts of heat to get hotter as their structure and the number of particles in a certain mass is different for each type. • Values are therefore quoted for the heat needed to raise the temperature of 1 kg of a substance by 1 K A Level Physics LOJ March 2004
![The Equation DQ mc Dq m mass kg c specific heat The Equation DQ = mc. Dq m = mass (kg) c = specific heat](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-8.jpg)
The Equation DQ = mc. Dq m = mass (kg) c = specific heat capacity (J kg-1 K-1) Q = heat energy (J) q = temperature (K) The D means ‘difference in’ because if you put heat in you get an increase – if heat comes out of the system the temperature goes down. You can therefore use signs to indicate gain or loss. A Level Physics LOJ March 2004
![Definition The Specific Heat Capacity c of a substance is the quantity of Definition • The Specific Heat Capacity (c) of a substance is the quantity of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-9.jpg)
Definition • The Specific Heat Capacity (c) of a substance is the quantity of energy required to raise the temperature of 1 kg of the substance by 1 K. A Level Physics LOJ March 2004
![SHC c The biggest changes in temperature of a given mass of SHC - c • The biggest changes in temperature of a given mass of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-10.jpg)
SHC - c • The biggest changes in temperature of a given mass of a substance will occur in those that have low specific heat capacities - because it doesn't take much energy for them to get hotter! A Level Physics LOJ March 2004
![Water Water has a very large SHC 4200 J kg1 K1 Water • Water has a very large SHC • 4200 J kg-1 K-1 •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-11.jpg)
Water • Water has a very large SHC • 4200 J kg-1 K-1 • This is about ten times that of a metal. A Level Physics LOJ March 2004
![Water It makes an excellent heat store To store heat you want Water • It makes an excellent heat store. • To store heat you want](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-12.jpg)
Water • It makes an excellent heat store. • To store heat you want the thing it is stored in not to get too hot – otherwise it will lose heat very quickly to the surroundings – remember heat loss to the surroundings depends on the diference in temperature between the object and its surroundings (DT) A Level Physics LOJ March 2004
![Water Water has a large SHC Therefore is makes an excellent coolant Water • Water has a large SHC • Therefore is makes an excellent coolant.](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-13.jpg)
Water • Water has a large SHC • Therefore is makes an excellent coolant. • A good coolant will take a lot of heat away from whatever you are trying to cool without getting too hot itself. • Once the coolant is the same temperature as the thing you want cooling it will stop taking heat from it! A Level Physics LOJ March 2004
![Latent Heat Means hidden heat Is absorbed or evolved when a substance Latent Heat • Means ‘hidden heat’ • Is absorbed or evolved when a substance](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-14.jpg)
Latent Heat • Means ‘hidden heat’ • Is absorbed or evolved when a substance changes state. • Doesn’t result in a change of temperature. • Some substances require more energy per kilogram to change the degree of freedom of their particles than others. • Relates to internal potential energy NOT the average kinetic energy of particles A Level Physics LOJ March 2004
![Heating Ice If ice is heated steadily and its temperature recorded at regular Heating Ice • If ice is heated steadily and its temperature recorded at regular](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-15.jpg)
Heating Ice • If ice is heated steadily and its temperature recorded at regular intervals an interesting graph is obtained. A Level Physics LOJ March 2004
![A Level Physics LOJ March 2004 A Level Physics LOJ March 2004](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-16.jpg)
A Level Physics LOJ March 2004
![Latent Heat hidden heat that does not register as a temperature rise Latent Heat – hidden heat that does not register as a temperature rise •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-17.jpg)
Latent Heat – hidden heat that does not register as a temperature rise • Thus heat is used to raise the temperature of something if it is not changing state. • If it IS changing state then that energy is used for that purpose and the substance does not get any hotter. • It gives the particles in the substance more ‘freedom’ rather than increasing their kinetic energy. • It is increasing their potential energy – the internal energy of the substance. A Level Physics LOJ March 2004
![Work The heat energy is used to do work against intermolecular forces Work • The heat energy is used to do work against intermolecular forces. •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-18.jpg)
Work • The heat energy is used to do work against intermolecular forces. • In substances that expand when they change state (not always the case!) the energy is used to do work against external forces A Level Physics LOJ March 2004
![Equation It makes sense that the more of the substance you have to Equation • It makes sense that the more of the substance you have to](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-19.jpg)
Equation • It makes sense that the more of the substance you have to melt/boil the more energy you will have to supply. • Therefore we have quoted values for how much energy is required to change the state of one kilogram of various substances • As the values relate to 1 kg the values are termed as the specific latent heat – symbol l (for latent!) • The unit of l is therefore J/kg DQ = ml A Level Physics LOJ March 2004
![Equation DQ ml l specific latent heat Jkg m mass kg Equation DQ = ml l = specific latent heat (J/kg) m = mass (kg)](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-20.jpg)
Equation DQ = ml l = specific latent heat (J/kg) m = mass (kg) Q = Heat energy (J) The D indicates that heat can be input to change ‘up’ a state or given out when a substance changes ‘down’ a state A Level Physics LOJ March 2004
![Definitions Specific latent heat is the energy required to change the state of Definitions • Specific latent heat is the energy required to change the state of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-21.jpg)
Definitions • Specific latent heat is the energy required to change the state of 1 kg of a substance. • Specific latent heat of fusion is the energy required to change the state of 1 kg of a substance form a solid to a liquid. • Specific latent heat of vaporisation is the energy required to change the state of 1 kg of a substance form a liquid to a gas. A Level Physics LOJ March 2004
![Calculations The layout of calculations is important Think about what is happening Calculations • The layout of calculations is important • Think about what is happening.](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-22.jpg)
Calculations • The layout of calculations is important • Think about what is happening. – What gains energy? – What loses energy? – List the energy gains and losses then equate them. • Use symbols for the unknowns and the answer will ‘all come out in the wash’! A Level Physics LOJ March 2004
![Example A kettle of power 2 k W holds 2 litres of water Example • A kettle of power 2 k. W holds 2 litres of water](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-23.jpg)
Example • A kettle of power 2 k. W holds 2 litres of water at room temperature – 20 o. C. • If the kettle is left on for 5 minutes will it boil dry? • Cwater = 4200 J kg-1 K-1 • l -1 = 2260 k. J kg water A Level Physics LOJ March 2004
![A kettle of power 2 k W holds 2 litres of water at room A kettle of power 2 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-24.jpg)
A kettle of power 2 k. W holds 2 litres of water at room temperature – 20 o. C. If the kettle is left on for 5 minutes will it boil dry? Cwater = 4200 J kg-1 K-1 lwater = 2260 k. J kg-1 • Where does the energy given to the water come from? • The electricity supply via the kettle’s electrical element • How much energy is given to the water? • 2000 J every second for 5 minutes • Calculate this! • 2000 x 5 x 60 = 6 x 105 J A Level Physics LOJ March 2004
![A kettle of power 2 k W holds 2 litres of water at room A kettle of power 2 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-25.jpg)
A kettle of power 2 k. W holds 2 litres of water at room temperature – 20 o. C. If the kettle is left on for 5 minutes will it boil dry? Cwater = 4200 J kg-1 K-1 lwater = 2260 k. J kg-1 • Energy input = 6 x 105 J • How much energy is required to bring the water to boiling point? • What equation do we need? DQ = mc. Dq • Okay, so how much energy is needed? • (Remember that 1 litre of water has a mass of 1 kg and the SHC of water is 4200 J kg-1 K-1) • Q = 2 X 4200 X 80 = 6. 72 x 105 J A Level Physics LOJ March 2004
![A kettle of power 2 k W holds 2 litres of water at room A kettle of power 2 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-26.jpg)
A kettle of power 2 k. W holds 2 litres of water at room temperature – 20 o. C. If the kettle is left on for 5 minutes will it boil dry? Cwater = 4200 J kg-1 K-1 lwater = 2260 k. J kg-1 • Energy input = 6 x 105 J • Energy required to boil the water = 6. 72 x 105 J • What does this mean? • The water wouldn’t even boil – let alone boil dry! A Level Physics LOJ March 2004
![A kettle of power 3 k W holds 2 litres of water at room A kettle of power 3 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-27.jpg)
A kettle of power 3 k. W holds 2 litres of water at room temperature – 20 o. C. If the kettle is left on for 5 minutes will it boil dry? Cwater = 4200 J kg-1 K-1 lwater = 2260 k. J kg-1 • What would happen if the power of the kettle used was 3 k. W instead? • Try it yourself! A Level Physics LOJ March 2004
![A kettle of power 3 k W holds 2 litres of water at room A kettle of power 3 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-28.jpg)
A kettle of power 3 k. W holds 2 litres of water at room temperature – 20 o. C. If the kettle is left on for 5 minutes will it boil dry? Cwater = 4200 J kg-1 K-1 lwater = 2260 k. J kg-1 • Energy supplied = 3000 x 5 x 60 = 9 x 105 J • Energy required to boil the water • = mc. Dq • = 2 x 4200 x 80 • = 6. 72 x 105 J • Energy left over to change water into steam • = (9. 00 – 6. 72) x 105 J • = 2. 28 x 105 J A Level Physics LOJ March 2004
![A kettle of power 3 k W holds 2 litres of water at room A kettle of power 3 k. W holds 2 litres of water at room](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-29.jpg)
A kettle of power 3 k. W holds 2 litres of water at room temperature – 20 o. C. If the kettle is left on for 5 minutes will it boil dry? Cwater = 4200 J kg-1 K-1 lwater = 2260 k. J kg-1 • Energy supplied = 3 000 x 5 x 60 = 9 x 105 J • Energy required to boil the water • = ml • = 2 x 2 260 000 • = 4 520 000 J • • Energy left over to change water into steam = 228 000 J A surplus of 228 000 – 4 520 000 = - 429000 J Therefore it would not boil dry, even then – but it would boil!! A Level Physics LOJ March 2004
![Summary You should be able to understand what is happening to the particles Summary • You should be able to understand what is happening to the particles](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-30.jpg)
Summary • You should be able to understand what is happening to the particles in a substance when heat is added to it or taken away. A Level Physics LOJ March 2004
![Summary If the substance is remote from its melting or boiling point it Summary • If the substance is remote from its melting or boiling point it](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-31.jpg)
Summary • If the substance is remote from its melting or boiling point it will change temperature (getting hotter or colder) as the particles vibrate faster or slower on absorbing the heat energy - the kinetic energy component changes significantly the potential energy component is virtually the same. . A Level Physics LOJ March 2004
![Summary The amount of heat energy required to make a temperature change of Summary • The amount of heat energy required to make a temperature change of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-32.jpg)
Summary • The amount of heat energy required to make a temperature change of 1 K will depend on the mass of the substance • The more you have the more energy you will need, natch! • It will also depend on what it is. • Some structures react to heat input more dramatically than others (this is indicated in the SHC 'c' of the substance) - low 'c' substances have particles that are easier to 'vibrate'! A Level Physics LOJ March 2004
![Summary If the substance is at its boilingmelting point the energy giventaken away Summary • If the substance is at its boiling/melting point the energy given/taken away](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-33.jpg)
Summary • If the substance is at its boiling/melting point the energy given/taken away will not be used to get hotter or colder. • It will be used to change state. • If absorbed at the change of state point (given to the substance) it will not make the particles vibrate any faster, but will make them freer from each other. A Level Physics LOJ March 2004
![Summary If being taken away again it will not change the vibration of Summary • If being taken away, again it will not change the vibration of](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-34.jpg)
Summary • If being taken away, again it will not change the vibration of the particles but rather will make them more structured - less free - and change their state to do that. • So when latent heat is involved we are looking at the change of potential energy not kinetic energy. A Level Physics LOJ March 2004
![Summary You should be able to do calculations involving heat being given andor Summary • You should be able to do calculations involving heat being given and/or](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-35.jpg)
Summary • You should be able to do calculations involving heat being given and/or taken away. • Remember to add up all of the components that have been 'given energy' and all of those that have 'given energy away' and equate them in an exchange of heat problem. A Level Physics LOJ March 2004
![Summary You should be able to define specific heat capacity and latent heat Summary • You should be able to define specific heat capacity and latent heat](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-36.jpg)
Summary • You should be able to define specific heat capacity and latent heat and recall the equations. A Level Physics LOJ March 2004
![AQA Exam Question 1 00 kg water is brought to the boil inside an AQA Exam Question 1. 00 kg water is brought to the boil inside an](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-37.jpg)
AQA Exam Question 1. 00 kg water is brought to the boil inside an electric kettle. Throughout the heating process the heating element supplies energy at a constant rate. Assume that the energy supplied to the kettle itself is negligible. a) Calculate the rate at which energy is supplied to convert water to steam if 0. 50 g of steam is produced each second after the water has reached boiling point. b) Estimate the rate at which the temperature increases just before the water reaches boiling point. c) State and explain the main reason why the rate of increase in temperature is not constant during the heating process. A Level Physics LOJ March 2004
![Calculate the rate at which energy is supplied to convert water to steam if Calculate the rate at which energy is supplied to convert water to steam if](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-38.jpg)
Calculate the rate at which energy is supplied to convert water to steam if 0. 50 g of steam is produced each second after the water has reached boiling point. • 0. 5 g water turns to steam each second. • l = 2260 k. J kg-1 = 2260 J g-1 • Therefore energy required to do this is 2 260 000 x 0. 5/1000 = 1 130 J • This is supplied each second therefore the rate is 1. 13 k. W A Level Physics LOJ March 2004
![b Estimate the rate at which the temperature increases just before the water reaches b) Estimate the rate at which the temperature increases just before the water reaches](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-39.jpg)
b) Estimate the rate at which the temperature increases just before the water reaches boiling point. • To raise 1 kg water by 1 K you need 4200 J • 1130 J is supplied in a second… • Therefore the number of degrees Kelvin that the temperature increases by, in that last second is: • 1130/4200 = 0. 27 K • And the rate of increase is 0. 27 K/s A Level Physics LOJ March 2004
![c State and explain the main reason why the rate of increase in temperature c) State and explain the main reason why the rate of increase in temperature](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-40.jpg)
c) State and explain the main reason why the rate of increase in temperature is not constant during the heating process. • Heat loss to the surroundings depends on the temperature difference between the hot body and the temperature of the surroundings. • The bigger the difference the greater the rate at which heat loss will occur. A Level Physics LOJ March 2004
![AEB Question from 1984 Typical synoptic question An Xray tube is operating AEB Question from 1984 – Typical synoptic question. • An X-ray tube is operating](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-41.jpg)
AEB Question from 1984 – Typical synoptic question. • An X-ray tube is operating at a potential of 125 k. V and 10 m. A. • (a) If only 1% of the electrical power is converted to X-rays, at what rate is the target being heated per second? • (b) If the target has a mass of 0. 3 kg and is made of a material with a specific heat capacity of 150 J kg-1 K-1 at what rate does its temperature rise? • (c) What assumption have you made in calculating the value for part b? A Level Physics LOJ March 2004
![a If only 1 of the electrical power is converted to Xrays at what (a) If only 1% of the electrical power is converted to X-rays, at what](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-42.jpg)
(a) If only 1% of the electrical power is converted to X-rays, at what rate is the target being heated per second? • Energy from electrical supply per second = power P = IV = 10 X 10 -3 x 125 000 = 1250 W 99% used in heating = 1240 W (3 sf) A Level Physics LOJ March 2004
![b If the target has a mass of 0 3 kg and is made (b) If the target has a mass of 0. 3 kg and is made](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-43.jpg)
(b) If the target has a mass of 0. 3 kg and is made of a material with a specific heat capacity of 150 J kg-1 K-1 at what rate does its temperature rise? • E = mc. Dq • Each second 1240 J energy is supplied to the anode target. • 1240 = 0. 3 x 150 x Dq • Therefore the temperature rises at a rate of: Dq = 1240/(0. 3 x 150) = 27. 6 K per second A Level Physics LOJ March 2004
![c What assumption have you made in calculating the value for part b (c) What assumption have you made in calculating the value for part b? •](https://slidetodoc.com/presentation_image_h/fd21cbf0f7ab101242beb270bd7e6593/image-44.jpg)
(c) What assumption have you made in calculating the value for part b? • The assumption is that there are no thermal losses to the surroundings. A Level Physics LOJ March 2004
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