Edexcel Physics IGCSE Topic 2: Electricity Summary Notes PDF
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These summary notes cover Topic 2: Electricity for Edexcel Physics IGCSE. The document explains key concepts like current, potential difference, and resistance. It also details series and parallel circuits, and the dangers of electricity.
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Edexcel Physics IGCSE Topic 2: Electricity Summary Notes (Content in bold is for physics only) This work by PMT Education is licensed under https://bit.ly/pmt-cc https://bit.ly/pmt-edu-cc CC BY-NC-ND 4.0...
Edexcel Physics IGCSE Topic 2: Electricity Summary Notes (Content in bold is for physics only) This work by PMT Education is licensed under https://bit.ly/pmt-cc https://bit.ly/pmt-edu-cc CC BY-NC-ND 4.0 https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Energy and voltage in circuits Current Current I is measured in amperes (A) and is the rate of flow of charge at a point in the circuit. The current is given by I=Q/t, where Q is measured in coulombs (C) and t in seconds (s). In metals, current is due to a flow of electrons. In solutions it can be the flow of ions. Conventional current is the rate of flow of positive charge - this is in the opposite direction to the flow of electrons because electrons are negatively charged. Current is conserved at a junction in a circuit because charge is always conserved. Current is measured with an ammeter connected in series with the component. Potential difference Potential difference V is measured in volts (V where 1 V = 1 JC ) and is the work done per unit -1 charge in moving between two points in a circuit. The potential difference is given by V=E/Q. It is measured with a voltmeter placed in parallel across the component. The higher the potential difference, the greater the current (V = IR). Resistance The resistance of a component is measured in ohms (Ω) and is given by the potential difference across it divided by the current through it, i.e. R=V/I. The greater the resistance, the harder it is for current to flow through the component. In an ohmic conductor (such as a resistor at a constant temperature), the current is directly proportional to the voltage (i.e. it has constant resistance). In a non-ohmic conductor (such as a filament lamp), the resistance changes as the voltage and current changes. In a filament lamp, this is because as the current increases through the filament, so does the temperature, which means electrons and ions vibrate more and collide more, increasing resistance. A thermistor is a resistor whose resistance decreases as the temperature increases. A light dependent resistor is a resistor whose resistance decreases as light intensity increases. Electric circuits Series: Components are connected end to end in one loop The same current flows through every component https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc The potential difference is shared across each component - depending upon their resistance (i.e. the sum of the p.d.s across the components is equal to the total p.d. across the supply) - components with a higher resistance have a greater PD across. The total resistance in series is the sum of the resistances of each component R = R + R T 1 2 … Parallel: Components are connected to the power supply in separate branches The current is shared between each branch (i.e. the sum of the currents in the separate branches is equal to the current through the source) - because charge can only flow one way. The potential difference is the same across every branch Connecting lamps in parallel is advantageous because if one breaks, current can still pass through the rest. Mains electricity Dangers of electricity Hazards: Damaged insulation – contact with the wire due to gaps in the insulation can cause an electric shock or pose a fire hazard by creating a short circuit. Overheating of cables – high currents passing through thin wire conductors cause the wires to heat up to very high temperatures which could melt the insulation and cause a fire. Damp conditions – water can conduct a current so wet electrical equipment can cause an electric shock. Fuses and circuit breakers: A fuse is a thin piece of wire which overheats and melts if the current is too high, protecting the circuit. They have a current rating which should be slightly higher than the current used by the device in the circuit. The most common are 3A, 5A and 13A. Circuit breakers consist of an automatic electromagnet switch which breaks the circuit if the current rises over a certain value. This is better than a fuse as it can be reset and used again, and they operate faster. Earthing metal cases: Earth wires create a safe route for current to flow through in the case of a short circuit, preventing electric shocks. Earth wires have a very low resistance so a strong current surges through them which breaks the fuse and disconnects the appliance. Double insulation: Appliances with double insulation have either plastic casings completely covering their electrical components, or have been designed so that the earth wire cannot touch the metal casing, preventing them from giving an electric shock. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Electrical transfer of energy Energy, measured in joules (J), is transferred from chemical energy in the battery to electrical energy used by circuit components and then to the surroundings. The power of a component is measured in watts (W) and is given by P=IV (by using V=IR, this can be shown to be equivalent to P=I2R and P=V2/R). Using this equation, the energy transferred is given by E=IVt. Alternating current and direct current In a direct current, the current only flows in one direction whereas in an alternating current, the current continuously changes direction. Mains electricity is an alternating current (a.c.) whereas the current supplied by a cell or battery is direct current (d.c.). https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Electric charge Charge is measured in coulombs, C. There are positive and negative charges; opposite charges attract and like charges repel. Atoms are composed of protons, electrons and neutrons. Protons have a charge of +1, electrons have a charge of -1 and neutrons have a charge of 0. Charging a body involves the addition or removal of electrons - charging atoms creates ions. Conductors such as metals allow electrons to flow through them whereas insulators such as plastics impede the flow of electrons. o When two insulators are rubbed together, friction causes electrons to move from one to the other and they become charged. The material that loses electrons becomes positively charged and the material that gains electrons becomes negatively charged. o The magnitude of the charge on each material is equal, since they lose/gain the same number of electrons. o For example, when a rod is rubbed with a cloth, electrons are transferred from the rod onto the cloth and the rod becomes positively charged. The charges cannot move within the insulator so they build up - this is known as static electricity. Consequences of static electricity can be seen in a number of phenomena. Lightning: ○ Electrostatic charge can build up on clouds due to friction. ○ When this charge becomes large enough, the clouds discharge through the air to the earth. This results in lightning. Charged balloon on a wall: ○ A positively charged balloon will stick to a wall if moved close enough. ○ Positive charges in the wall are repelled by the balloon and move to other parts of the wall. This leaves a negative charge on the area of the wall closest to the balloon. ○ The attraction between the negatively charged wall and the positively charged balloon makes the balloon stick. Comb picking up bits of paper: ○ Rubbing a comb against an insulator will cause it to pick up an electrostatic charge due to the transfer of electrons. ○ The charge on the comb repels like-charged in the paper, leaving the paper closest to the comb with an electrostatic charge opposite to the comb. ○ This end of the paper is then attracted to the comb. Electrostatic phenomena caused by the movement of electrons have many useful applications but also pose many risks. Dangers of electrostatic charges include: o Static charges pose a risk of electric shock. If a person touches an object with a large amount of static charge, electrons will flow through the person’s body to the earth. o When fuelling aircraft and tankers, if enough charge builds up on the vehicle or pump it can create a spark. This can ignite the fuel and cause a fire or explosion. For safety, an earthing wire can be attached so that the charge instead flows into the earth. Safety measures when using electrostatic charges include: o Earthing involves offering electrons an alternative pathway to the earth. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc o This prevents too much electrostatic charge form building up on the surface of an insulator. Less electrostatic charge reduces the risk of electric shock, or the harm it can cause. Uses of electrostatic charges include: o In an inkjet printer, droplets of ink are charged and pass between two charged metal plates, one of which has a positive charge and the other a negative charge. The droplets are attracted to the plate with the opposite charge and repelled by the plate with the same charge and deflected towards a specific place on the paper. o In a photocopier, the image of a document is projected onto a positively charged plate; where light falls onto the plate, the charge leaks away. Negatively charged toner particles are attracted to the remaining positive areas. Paper is then placed over the plate and the toner is transferred to it, making the photocopy. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc