Physics paper 1

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Created by
Femifayo Babajide

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  • Energy is transferred between stores
    Thermal, kinetic, gravitational potential, elastic potential, chemical, magnetic, electrostatic, nuclear
  • Energy is transferred...
    Mechanically (by a force doing work), electrically (work done by moving charges), by heating or by radiation (like light or sound)
  • kinetic energy
    energy of motion - the greater an object's mass and the faster it is going, the more energy there will be in its kinetic energy store. Ek (j) = 1/2m(kg)v(m/s) squared
  • Raised objects store energy in gravitational potential energy stores

    lifting an object in a gravitational field requires work, causing an energy transfer to the the GPE store of the object. Ep(j) = m(kg)g(n/kg)h(m)
  • Falling objects transfer energy
    Falling objects transfer energy from its GPE store to its kinetic energy store. When there's no air resistance, energy lost from the GPE store = energy gained in the kinetic energy store
  • Stretching transfers energy to elastic potential energy stores
    As long as the limit of proportionality has not been exceeded, Ee (j) = 1/2 k (N/m) e (m) squared
  • specific heat capacity
    the energy required to raise the temperature of one gram of a substance by one degree Celsius. 🔼E (j) = m(kg) c(j/kgdegree) 🔼theta (degrees Celsius)
  • Conservation of energy principle
    Energy can be transferred but can never be created of destroyed
  • Dissipated energy
    energy used up in a system, typically lost due to work done by friction, 'wasted energy
  • Phone energy
    When you use the phone, energy is usefully transferred from the chemical energy store of the battery in the phone, but some of this energy is dissipated to thermal energy
  • Closed system energy transfer
    A cold spoon is dropped into hot soup in an insulated flask, which is then sealed. Energy is transferred from the thermal energy store of the soup to the useless thermal energy of the spoon
  • Power

    The rate at which work is done (watts). P(w) = E(j) / t(s)
  • Conduction occurs mainly in solids
    Conduction is the process where vibrating particles transfer energy to neighbouring particles.
  • thermal conductivity
    the Mrs sure of the rate at which thermal energy can travel through a material
  • Convection occurs only in liquids and gases
    Convection is where energetic particles move away from hotter to cooler regions
  • Radiators - convection currents
    Energy is transferred from the radiator to nearby air particles by conduction. The air by the radiator becomes warmer and less dense. This warm air rises and is replaced by cooler air. At the same time, the previously heated air transfers energy to the surrounding and cools, becomes denser, and sinks. This cycle repeats and causes a flow of air to circulate around the room
  • How to reduce unwanted energy transfers
    Lubrication and thermal insulation
  • Insulation reduces the rate of energy transfer by heating
    Things to do to prevent energy loss through heating...
    - have think walls made from low thermal conductivity material. This makes the rate of energy transfer slower, so the building will cool more slowly.
    - use thermal insulation
  • Most energy transfers involve some waste energy
    Efficiency = useful output energy transfer / total input energy transfer OR efficiency = useful power output / total power input
  • Non renewable energy resources will one day run out

    Fossil fuels and nuclear fuels. Fossil fuels are typically burnt to provide coal, oil, and natural gas. They damage the environment but provide most of our energy
  • Renewable energy resources will never run out
    These are: the sun, wind, water waves, hydro-electricity, bio-fuel, tides, geothermal. Most of them do damage to the environment, but in less nasty ways than non renewables. However, they don't provide much energy and some are unreliable as they depend on the weather
  • Energy resources can be used for transport
    Non renewable - petrol and diesel powered vehicles use fuel from oil. Coal can be used in old fashioned steam trains to boil water for steam.
    Renewable - vehicles running on bio-fuels or a mix of a bio-fuel and petrol/diesel.
    Electricity sometimes powers vehicles and can be generated using renewable or non renewable resources
  • Energy resources can also be used for heating
    Non renewable - natural gas is widely used for heating homes. The gas heats water, which gets pumped into radiators. Coal is commonly burnt in fireplaces. Electric heaters use electricity generated from non renewable resources.
    Renewable - a geothermal heat pump uses geothermal energy resources to heat buildings. Solar water heaters use to the sun to heat water, which gets pumped into radiators.
  • Wind power
    This involves putting up lots of wind turbines in an exposed place, like on coasts. The turbines have a generator inside them - the rotating blades turn the generator to produce electricity.
  • wind power advantages
    There's limited pollution (only when they're first manufactured), no fuel costs and minimal running costs, no permanent damage to the landscape
  • wind power disadvantages
    They spoil the view, very noisy, unreliable as they depend on the weather, initial costs are quite high
  • Solar cells
    They generate electric currents from the sun. They are often the best energy source to charge calculator or watch batteries, as they don't use much electricity.
  • solar power advantages
    There's no pollution (although they use a lot of energy to manufacture), reliable in sunny countries in the daytime, energy is free and running cost extremely low
  • solar power disadvantages
    Unreliable because they depend on weather, can't increase power output when there is extra demand, initial costs are high school
  • Geothermal power
    This is energy in underground thermal energy stores. It is possible in volcanic areas or where hot rocks lie close to the surface. The source of a lot of this energy is the slow decay of various radioactive elements deep inside the earth
  • Geothermal power advantages
    Free energy that is reliable and does very little damage to the environment. Can be used to generate electricity or heat buildings
  • Geothermal power disadvantages
    There aren't many suitable locations for power plants, and the cost of building a power plant is high compared to the amount of energy that it produces
  • hydroelectric power used falling water
    It tends to require the flooding of a valley by building a dam. Water is allowed out through turbines
  • Hydro-electric power advantages
    There is no pollution and it can provide an immediate response to an increased demand for electricity. It is reliable and there are no fuel costs and minimal running costs
  • Hydro-electric power disadvantages
    There is a big environmental impact from the valley flooding (rotting vegetation releases methane and CO2) and loss of habitat for some species. Initial costs are high
  • Water power
    Lots of small wave-powered turbines around the coast. The moving turbines are connected to a generator
  • Water power advantages
    There is no pollution, no fuel costs and minimal running costs. Can be useful on small islands
  • Water power disadvantages
    It disturbs the seabed and the marine animals' haibitats. Spoils the view, hazard to boats, fairly unreliable, initial costs are high
  • Tidal barrages
    Tidal barrages are big dams across river estuaries, with turbines in them. As the tide comes in the estuary gets filled up. The water is then allowed out through turbines at a controlled speed. Tides are produced by the gravitational pull of the moon and sun
  • Tidal barrages advantages
    There is no pollution, pretty reliable as they always happen twice a day, no fuel floats and minimal running costs