Energy

Question 1

List the 8 energy stores.

Answer 1

Thermal, kinetic, gravitational potential, elastic potential, chemical, magnetic, electrostatic and nuclear.

Question 2

How is energy transferred?

Answer 2

Mechanically (force doing work), electrically (work done by moving charges), heating and radiation (light or sound).

Question 3

What is a system?

Answer 3

A single object or group of objects. When a system changes, energy is transferred.

Question 4

What is a closed system?

Answer 4

A system wher no matter nor energy can enter or leave. The net change in the total energy of a closed system is always zero.

Question 5

How do you calculate kinetic energy?

Answer 5

Kinetic energy (J) = 1/2 x mass (kg) x velocity² (m/s)²
or E=1/2mv².

Question 6

How do you calculate gravitational potential energy?

Answer 6

GPE (J) = mass (kg) x gravitational field strength (N/kg) x height (m) or E=mgh.

Question 7

How are gpe and kinetic energy connected?

Answer 7

When there is no air resistance, energy lost from gpe store = energy gained in the kinetic store.

Question 8

How do you calculate elasic potential energy?

Answer 8

Elastic potential energy (J) = 1/2 x spring constant (n/m) x extension² (m) or E=1/2ke².

Question 9

What is the limit of proportionality?

Answer 9

When the extension is no longer proportional to the force.

Question 10

What is specific heat capacity?

Answer 10

The amount of energy needed to raise the temperature of 1 kg of a substance by 1°C.

Question 11

What equation links energy transferred to specific heat capacity?

Answer 11

Change in thermal energy (J) = mass (kg) x specific heat capacity (J/kg°C) x temperature change (°C) or ΔE=mcΔθ.

Question 12

How would you investigate the specific heat capacity of different solid materials?

Answer 12

1. You will need a block of the material with two holes in it for the heater and thermometer.
2. Measure the mass of the block, then wrap it in an insulating layer to reduce the energy transferred from the block to the surroundings. Insert the thermometer and heater.
3. Measure the initial temperature of the block and set the potential difference of the power supply to 10V. Turn on the the power supply and start a stopwatch.
4. When you turn on the power, the current in the circuit does work on the heater, transferring energy electrically from the power supply to the heater’s thermal energy store. This energy is then transferred to the material’s thermal energy store by heating, causing the materials temperature to increase.
5. As the block heats up, take readings of the temperature and current every minute for 10 minutes.
6. Turn off the power supply once you have collected enough readings. Calculate power supplied to the heater using P=VI. You can then calculate how much energy is transferred to the heater (E=Pt).
7. You can then plot a graph and calculate specific heat capacity.
8. Then repeat this experiment with different materials to compare.

Question 13

What is the conservation of energy principle?

Answer 13

Energy can be transferred usefully, stored or dissipated, but can never be created or destroyed.

Question 14

How can you calculate power?

Answer 14

P=E/t or P=W/t.

Question 15

What is conduction?

Answer 15

The process where vibrating particles transfer energy to neighbouring particles.

Question 16

What is thermal conductivity?

Answer 16

A measure of how quickly energy is transferred through a material.

Question 17

What is convection?

Answer 17

Where energetic particles move away from hotter to cooler regions.

Question 18

How does convection work?

Answer 18

When you heat a region of liquid or gas, the particles move faster and the space between the individual particles increases. This causes the density of the region being heated to decrease. The warmer less dense region will rise above the denser, cooler regions. A convection current is created if there is a constant heat source.

Question 19

How does a radiator heat a room (convection currents)?

Answer 19

1. Energy transferred from the radiator to the particles nearby.
2. The air by the radiator becomes warmer and less dense.
3. The warm air rises and is replaced by cooler air. The cooler air is then heated by the radiator.
4. Previously heated air transfers energy to the surroundings, cools, becomes denser and sinks.
5. The cycle repeats.

Question 20

How can you reduce wasted energy from friction?

Answer 20

Lubricants like oil.

Question 21

How can you reduce energy loss through heating?

Answer 21

Thick walls that are made from a material with a low thermal conductivity.
Use thermal insulation:
- cavity walls (air gap in the middle filled with foam)
- lost insulation
- double glazing
- draught excluders.

Question 22

How can you calculate efficiency?

Answer 22

Efficiency = useful output energy transfer/ total input energy transfer.
or efficiency = useful power output/ total power input.

Question 23

How can you improve the efficiency of energy transfers?

Answer 23

Insulating objects, lubricating them, making them more streamlined.

Question 24

What are the three main fossil fuels?

Answer 24

1. Coal.
2. Oil.
3. Natural Gas.

Question 25

What are the 7 main renewable energy resources?

Answer 25

1. Solar, 2. Wind, 3. Water waves, 4. Hydro-electricity, 5. Bio-fuel, 6. Tides, 7. Geothermal.

Question 26

How are non-renwables used in transport?

Answer 26

Petrol and diesel powered vehicles use fuel created from oil. Coal is used in old fashioned steam trains which boil water to produce steam.

Question 27

How are renewables used in transport?

Answer 27

Vehicles that run on pure biofuels or a mix of biofuel and petrol or diesel.