Physics: Energy Part 1

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Aneesha

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  • 4.2 describe energy transfers involving energy stores:
    • energy stores: chemical, kinetic, gravitational, elastic, thermal, magnetic, electrostatic, nuclear
    energy transfers: mechanically, electrically, by heating, by radiation (light and sound)
    Chemical: Anything that can release energy by a chemical reaction (eg; food, fuel)
    Kinetic: Anything moving has energy in its kinetic energy store.
    Gravitational: Anything that has the potential to fall has GPE.
    Elastic: Anything stretched (eg; springs, rubber bands)
    Thermal: Any object has thermal energy- the hotter it is, the more energy
    Magnetic: Energy stored when two magnets attract or repel each other.
    Electrostatic: Energy stored when charges repel or attract each other
    Nuclear: The energy stored within the nucleus of atoms.
  • energy transfers
    Mechanically: A force moves an object through a distance
    Electrically: Charges move due to a potential difference
    By heating: Energy transferred from a hotter object to a colder object
    By radiation (light and sound): Energy is transferred as a wave
  • 4.3 use the principle of conservation of energy
    The Principle of conservation of energy states that Energy is not created or destroyed in any process. It is just transferred from one store to another.
  • 4.4 know and use the relationship between efficiency, useful energy output and total energy output:

    Efficiency = (useful energy output / total energy output) x 100

    Energy is only useful when it is transferred from one store to a useful store. The less energy that is wasted by normally heat or sound energy, the more efficient the device is.
  • 4.5 describe a variety of everyday and scientific devices and situations, explaining the transfer of the input energy in terms of the above relationship, including their representation by Sankey diagrams
    A bat hitting a ball:
    Some energy is usefully transferred mechanical from the kinetic energy store of the bat tot he kinetic energy store of the ball. The rest of the energy is wasted. Some energy in the kinetic energy store of the bat is transferred mechanically to the thermal energy stores of the bat, the ball and their surroundings. The remaining energy is carried away by sound.

    Battery-powered toy car:
    Energy is usefully transferred electrically from the chemical energy store of the battery to the kinetic energy store of the car and is carried away by light from the headlights. Wasteful energy transfers also occur to thermal energy stores of the car and surroundings, and by sound.
  • Sankey diagram
    Sankey diagrams make it easy to see how much of the input energy is being usefully employed compared with how much is being wasted. The thicker the arrow, the more energy it represents. The energy flow is shown by arrows who's width is proportional to the amount of energy involved.
  • 4.11 know and use the relationship between work done, force and distance moved in the direction of the force:

    Work done = force x distance moved in the direction of the force
  • 4.12 know that work done is equal to energy transferred
    Work done = energy transferred
  • 4.13 know and use the relationship between gravitational potential energy, mass, gravitational field strength and height:
    gravitational potential energy = mass × gravitational field strength × height GPE = m × g × h

    Gravitational potential energy = mass x gravitational field strength x height
  • 4.14 know and use the relationship: kinetic energy = 12 × mass × speed2

    Kinetic energy = 1/2 x mass x speed^2
  • 4.15 understand how conservation of energy produces a link between gravitational potential energy, kinetic energy and work

    he conservation of energy produces a link between gravitational potential energy, kinetic energy and work:

    Lifting an object in a gravitational field requires work. This causes a transfer of energy to the gravitational potential energy store of the raised object. The higher the object is lifted, the more energy is transferred to this store.
    The amount of energy in a g.p.e store depends on the object's mass, it's height and the strength of the gravitational field the object is in.

    When something falls, energy from its gravitational potential energy store is transferred to its kinetic energy store.
    For a falling object when there's no air resistance: Energy lost from the GPE store = energy gained in the kinetic energy store
    In real life, air resistance acts against all falling objects- it causes some energy to be transferred to other energy stores
  • 4.16 describe power as the rate of transfer of energy or the rate of doing work

    Power is the rate of transfer of energy and the rate of doing work.
  • 4.17 use the relationship between power, work done (energy transferred) and time taken:

    Power = work done (energy transferred) / time taken
  • 4.18P, 4.19P describe the energy transfers involved in generating electricity using:
    wind
    Wind turbines use energy from the kinetic energy store of moving air to generate electricity. Wind turns the blades, which turn a generator inside it.

    - Wind turbines are renewable and produces no greenhouse gases
    - But can only be harvested in regions where the wind blows with enough energy
    - Spoils the view, contributes to noise pollution, unreliable
  • water
    Wave energy:
    As waves come into the shore they provide an up and down motion which can be used to drive a generator. Energy is transferred from the kinetic energy store of the waves to the kinetic energy store of the turbine, and used to generate electricity through a generator.

    - Renewable, produces no greenhouse gases
    - Spoils the view and is a hazard to boats
    - Semi unreliable as waves tend to die out when the wind drops

    Tidal power:
    As the tide comes in, the estuary is filled to a height of several metres. This water can then be allowed out through turbines at a controlled speed. The energy is transferred from the kinetic energy stores of the water to the kinetic energy store of the turbine, and used to generate electricity.

    - Renewable energy, no greenhouse gases
    - Prevents free access by boats, alters the habitat of the wildlife, not available continuously

    Hydroelectric power:
    Hydroelectric power often requires the flooding of a valley by building a big dam. Rainwater is caught and allowed out through turbines, transferring energy from the gravitational potential energy store of the water to kinetic energy stores as it falls, which is used to generate electricity.

    - Renewable, no greenhouse gases, can respond very quickly to changes in the demand for electricity
    - Loss of habitat due to the flooding of a valley, spoils the landscape, expensive to create
  • Geothermal resources
    Water is pumped in pipes down to the hot rocks and forced back up due to pressure to turn a turbine which drives a generator. The energy is transferred from thermal energy stores to kinetic energy stores and used to generate electricity. In some places, geothermal energy is used to heat buildings directly.

    - Only possible in certain places where hot rocks lie quite near to the surface.
    - Free, renewable energy
    - Expensive to drill down and to build a power plant
  • Solar heating
    Solar water heating panels are black water pipes inside a glass box. The glass lets energy from the Sun in, which is then absorbed by the black pipes and heats up the water.

    - Renewable and free after setting up
    - Only for small-scale energy production

    Curved mirrors are used to focus thermal radiation onto a boiler or pipes containing water to produce steam. The mirrors are controlled to select the Sun's heat onto the central tower throughout the day. The steam can be sued to drive turbines which be used to drive electricity generators.
  • Solar cells
    Solar cells (photocells) use energy from the sun to directly generate electricity.

    - They are renewable and don't produce greenhouse gases
    - They need enough sunlight
    -Provides small scale electricity
  • Fossil fuels
    The three fossil fuels are coal, oil, and natural gas. Coal produces the most CO2, and natural gas produces the least.

    1. As the fossil fuel burns (in oxygen) the energy in its chemical energy store is transferred to the thermal energy store of the water by heating
    2. The water boils to form steam, which turns a turbine, transferring energy mechanically to the kinetic energy store of the turbine.
    3. As the turbine revolves, so does the generator , which produces an electric current. The generator transfers the energy electrically away from the power station, via the national grid

    Disadvantages:
    - Fossil fuels release carbon dioxide into the atmosphere when burned in power stations. This CO2 contributes to global warming and climate change.
    - Burning coal and oil also releases sulphur dioxide into the atmosphere, which combines with water to form acid rain. This can damage plants, people, and buildings.
    - Fossil fuels are non- renewable.

    Advantages:
    - Burning fossil fuels releases a lot of energy, relatively cheaply
    - It is a reliable energy source
  • Nuclear power
    Nuclear reactors use uranium to produce energy. The fission o uranium produces the heat to drive turbines. During the process, energy is transferred from nuclear energy stores to thermal energy stores by heating, then mechanically to kinetic energy stores, and finally transferred electrically through the national grid.

    - Non-Renewable, possibility of radioactive waste
    - Expensive to build and maintain
    - No greenhouse gases, produces a lot of energy
  • Work done = force x distance moved (J)
  • Energy can be transferred between objects by doing work on them or heating them up
  • Power = work done / time taken (W)
  • Efficiency = useful output / total input × 100%
  • Units
    • kilogram (kg)
    • joule (J)
    • metre (m)
    • metre/second (m/s)
    • metre/second2 (m/s2)
    • newton (N)
    • second (s)
    • watt (W)
  • Energy stores
    • Chemical
    • Kinetic
    • Gravitational
    • Elastic
    • Thermal
    • Magnetic
    • Electrostatic
    • Nuclear
  • Energy transfers
    • Mechanically
    • Electrically
    • By heating
    • By radiation (light and sound)
  • Use the principle of conservation of energy
  • Efficiency
    Useful energy output / Total energy output x 100%
  • Describing a variety of everyday and scientific devices and situations
    1. Explain the transfer of the input energy in terms of the efficiency relationship
    2. Represent using Sankey diagrams
  • Work done
    Force x Distance moved in the direction of the force
  • Work done is equal to energy transferred
  • Gravitational potential energy
    Mass x Gravitational field strength x Height
  • Kinetic energy
    1/2 x Mass x Speed^2
  • Conservation of energy produces a link between gravitational potential energy, kinetic energy and work
  • Power
    Rate of transfer of energy or rate of doing work
  • Power
    Work done / Time taken