Module 1:

Section 3.1.3 - Current Electricity

 

 
Useful background
You should be able to:

Charge, current and potential difference

Electrical current as the rate of flow of charge

Potential difference as the work done per unit charge

Know that resistance is defined by

 

Charge (Q) measured in coulomb (C),

Current (I) measured in amperes or amps (A),

Potential difference (V) (sometimes called 'voltage' but use the proper term!) measured in volts (V)


Resistance (R) measured in ohms (Ω)

 

- realise that current is a resultant flow of electrons in a particular direction due to an applied P.D.and that without the P.D. the electrons are still in constant movement but these movements are random and cancel out the effects of each other.

- think of potential difference in terms of difference in 'electrical level (or height)'

- analyse a simple circuit, marking on 'potential drops' (even between strands) and calculating currents flowing in strands

- use 'croc clips' to help with practice of circuit analysis

- recall the equations from memory

- remember the 'physical meaning' of each letter

- use the correct units and their abbreviations

- manipulate the equations and perform calculations with them

- sketch graphs to represent the relationship between factors in the equations

- use the term 'direct proportionality' for a graph which goes through the origin.

- know how to measure potential difference across a component by using a voltmeter in parallel with that component

- know how to measure current through a component by using an ammeter in series with that component

- be aware of the meters available in the lab, their ranges and characteristics, advantages and disadvantages: multimeter use, dual scale moving coil meter use, shunts

- know how to check the reliability of a meter

- be able to wire up a circuit to check that current through a strand of a circuit is constant, potential is shared out in the same ratio as resistance and to determine p.d. across strands of a circuit

Look at this animation of electron behaviour in a metal filament.

V=IR Spreadsheet

Current/voltage characteristics for:

an ohmic conductor

a semiconductor diode

and a filament lamp

 

Candidates should have experience of the use of a current sensor and a voltage sensor with a datalogger to capture data from which to determine V/I curves

- know how to set up the experiment to determine a characteristic curve (including the use of the voltage/current sensor equipment)

- appreciate the errors involved in such an experiment and how to minimise them.

- know how to use 'croc clips' to make measurements - computer modelling opportunity

- sketch (from memory) the characteristics of the ohmic conductor, diode and filament lamp

- explain the shape of the characteristic in terms of the device's construction and physical make-up (construction is not needed for the diode)

Ohm's Law understood as a special case where I is proportional to V  

- Quote Ohm's law as 'Ohm's Law states that the current flowing through an Ohmic resistor is directly proportional to the potential difference across its ends providing that physical conditions (such as temperature) remain constant.'

- Realise that the equation V=I R is simply used to calculate the resistance of a material as a ratio and, in all other cases than a metallic conductor under constant conditions, does NOT relate to the gradient of the graph - that is a coincidence!

Resistance is the ratio!

Resistivity

Use of



Description of the qualitative effect of temperature on the resistance of metal conductors and thermistors. Applications, e.g. temperature sensors

Superconductivity as a property of certain materials which have zero resistivity at and below a critical temperature which depends on the material. Applications (e.g. very strong electromagnets, power cables)

Resistivity r

- although you don't have to recall the equation from memory
remember the 'physical meaning' of each letter

- know how to use a micrometer screwgauge and vernier calipers

- use the correct units and their abbreviations
manipulate the equations and perform calculations with them

- sketch graphs to represent the relationship between factors in the equation (including inverse proportionality!)

- relate behaviour of metals with physical properties (cross sectional area, length and how tightly are held the valence electrons of the atom).

- understand the structure of semiconductors and how temperature effects the resistivity of them.

- quote Ohm's law in words (not forgetting the proviso about temperature!) - never say simply V= IR!

- know how to use a micrometer (See Gibbs page 5)

- know how to design and carry out an experiment, mindful of minimising errors and identifying anomalies

- be aware of systematic and random errors (Gibbs pages 6-7)

- be able to estimate errors on measurements made

Resistivity Spreadsheet

Circuits

Series

and

parallel resistor circuits

- know how to work out combinations of resistors in series and in parallel

- know that a parallel resistor network has a net value of less than the value of any one resistor in that arrangement

- derive the equations for resistors in series and in parallel

- analyse a series/parallel combination circuit, marking on 'potential drops' and calculating currents flowing in strands

- wire up a practical circuit to investigate current and p.d. in combination circuits

- make use of the interactive spreadsheet.

Recall and use of

Energy and power in simple d.c. circuits

Application, e.g. understanding of high current requirement for a starter motor in a motor car

Conservation of charge and energy in simple d.c. circuits

The relationships between currents, voltages and resistances in series and parallel circuits, including cells in series and identical cells in parallel;

questions will not be set which require the use of simultaneous equations to calculate currents or potential difference

Kirchhoff's laws (Kirchhoff's first law was met pre-GCSE)

- derive E = V I t and P=I2R from known GCSE equations

- analyse circuits and find the power dissipated in any component (or the energy dissipated in a given time

- Understand that car batteries have low voltage so to provide the energy needed to ignite the petrol in a short time a high current is needed.

Interactive Spreadsheet

- understand how a potential divider can be used to supply a variable p.d.

- know and quote that 'Kirchhoff's First Law states that the algebraic sum of the currents in a circuit is zero' (charge is conserved)

- know that energy is conserved within a circuit and quote that 'According to Kirchhoff's Second Law, energy supplied by a power supply is equal to the sum of the energies of power dissipation in a circuit'. In other words the algebraic sum of the EMFs is equal to the algebraic sum of the product of the current and pd across circuit components in any ring of a circuit.

- analysis of simple circuits

 

Potential divider

The potential divider used to supply variable p.d. e.g. application as an audio 'volume' control.

Examples should include the use of variable resistors, thermistors and L.D.R.'s. The use of the potentiometer as a measuring instrument is not required.

 

- analysis of simple circuits

- sharing out 'voltage' in proportion to resistance across a strand in a circuit.

- Make use of the interactive spreadsheet

Electromotive force
Internal resistance r


Applications; e.g. low internal resistance for a car.

- perform calculations with circuits where an internal resistance of a cell is present.

- Appreciate that if the external resistance is large compared to the internal resistance the 'lot volts' will be negligible.

- define electromotive force as 'the energy given to each coulomb of charge by a battery. This is measured by a voltmeter connected across the battery terminals when it is connected in 'open circuit' (no current is flowing in the external circuit).'

- define internal resistance as 'the resistance of the battery itself within the circuit. When a battery is connected so as to drive a current through an external circuit, a drop in voltmeter reading is recorded on a voltmeter connected across the battery terminals. This is termed 'lost volts'. The volts are not really lost but are the potential drop across the internal resistance. Therefore this drop can be used to calculate the value using 'Lost volts = I t'

Make use of the interactive spreadsheet.

Sinusoidal voltages and currents only; root mean square, peak and peak-to-peak values, for sinusoidal waveforms:

Alternating currents



Application to calculation of mains electricity peak and peak-to-peak voltage values

 

- understand that power dissipation by an AC signal of given RMS signal is the same as the DC signal of the same numerical value
sketch a sinusoidal trace when given peak (amplitude, peak to peak or RMS) current/voltage and the frequency

- sketch the trace for mains voltage (recalling 230V rms is 330V peak and the frequency is 50Hz)

- perform calculations changing rms into peak and vice versa

Oscilloscope

Use of an oscilloscope as a d.c. and a.c. voltmeter, to measure time intervals and frequencies, and to display waveforms.

No details of the structure of the instrument is required but familiarity with the operation of the controls is expected.

- set up the oscilloscope to investigate an electrical signal

- determine the amplitude and frequency of a signal (AC/DC) as displayed on an oscilloscope

- describe 'how' to use an oscilloscope - what to connect where and what dials to turn to make the reading easier and more accurate.