Current & Circuits (DP IB Physics)

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  • True or False?

    This circuit symbol represents a battery.

    A simple circuit diagram symbol  consisting of two parallel lines with a gap between them, intersected perpendicularly by a single horizontal line.

    False.

    This circuit symbol represents a cell.

    A simple circuit diagram symbol consisting of two parallel lines of different lengths with a gap between them, intersected perpendicularly by a single horizontal line.
  • Draw the symbol for a switch.

    The symbol for a switch is:

    A simple circuit symbol  with a straight horizontal line connected to a two-segment line forming an angle pointing downward.
  • True or False?

    This circuit symbol represents a light dependent resistor.

    A simple schematic symbol of a rectangle, with a diagonal arrow crossing it.

    False.

    This circuit symbol represents a variable resistor.

    A simple schematic symbol of a rectangle, with a diagonal arrow crossing it.
  • Draw the circuit symbol for a battery.

    The circuit symbol for a battery is two or more cells joined together.

    Circuit diagram symbol representing two cells connected in series
  • Draw the symbol for a voltmeter.

    The symbol for a voltmeter is:

    Diagram symbol of a circle with a "V" inside and short lines extending horizontally from each side of the circle.
  • What does this circuit symbol represent?

    A rectangle with horizontal lines extending from its sides and an arrow pointing downward to its top edge.

    This circuit symbol represents a potentiometer.

    A rectangle with horizontal lines extending from its sides and an arrow pointing downward to its top edge.
  • Draw the symbol for a thermistor.

    The symbol for a thermistor is:

    A line drawing of a rectangular box with a diagonal line intersecting through it with a short horizontal end.
  • True or False?

    This circuit symbol represents a heating element.

    A rectangular symbol with four rectangles inside.

    True.

    This circuit symbol represents a heating element.

    A rectangular symbol with four rectangles inside
  • Draw the symbol for an ammeter.

    The symbol for an ammeter is:

    A simple electrical diagram symbol showing a circle with the letter 'A' inside and a straight line passing horizontally behind it
  • What does this circuit symbol represent?

    Symbol showing a triangle pointing to the right with a vertical line at the tip. Two arrows point diagonally upward away from the triangle.

    This circuit symbol represents a light emitting diode (LED).

    Symbol showing a triangle pointing to the right with a vertical line at the tip. Two arrows point diagonally upward away from the triangle.
  • What does a thermistor do?

    A thermistor is a resistor whose resistance changes depending on its temperature.

  • What does this circuit symbol represent?

    A rectangle with two lines on either side and two arrows pointing towards it.

    This circuit symbol represents a light dependent resistor (LDR).

    A rectangle with two lines on either side and two arrows pointing towards it.
  • What does a potentiometer do?

    A potentiometer is a resistor with a sliding contact that forms an adjustable voltage divider.

  • Define electric current.

    Electric current is the rate of flow of charge carriers.

  • What are the charged particles that flow in electrical circuits?

    The charged particles that flow in electrical circuits are electrons.

  • Define conventional current.

    Conventional current is the flow of positive charge from the positive terminal of a cell to the negative terminal.

  • Define direct current.

    Direct current (d.c.) flows around a circuit in one direction.

  • State the equation for current as the flow of charge.

    The equation for current as the flow of charge is: I space equals space fraction numerator increment q over denominator increment t end fraction

    Where:

    • I = current, measured in amps (A)

    • increment q = change in charge, measured in coulombs (C)

    • increment t = change in time, measured in seconds (s)

  • True or False?

    Electrons flow around a circuit towards the positive terminal, but conventional current flows around a circuit towards the negative terminal.

    True.

    Electrons do flow around a circuit towards the positive terminal, while conventional current flows towards the negative terminal. It is electrons that actually form the current, but the idea of conventional current was in use before the electron was discovered.

  • 10 C of charge passes a fixed point in a circuit per second.

    What is the current in the circuit?

    The current in the circuit is 10 A.

    • I space equals space fraction numerator increment q over denominator increment t end fraction space equals space 10 over 1 space equals space 10 space straight A

  • An ammeter records a current of 0.3 A for 10 s. How much charge has passed through the ammeter in this time?

    The amount of charge that has passed through the ammeter in this time is 3 C.

    • increment q space equals space I increment t space equals space 0.3 space cross times space 10 space equals space 3 space straight C

  • Define electric potential difference.

    Electric potential difference is the work done per unit charge on moving a positive charge between two points along the path of the current.

  • State the equation linking potential difference, work done and charge.

    The equation linking potential difference, work done and charge is V space equals fraction numerator space W over denominator q end fraction

    Where:

    • V = potential difference, measured in volts (V)

    • W = work done, measured in joules (J)

    • q = charge, measured in coulombs (C)

  • True or False?

    One volt is equal to one joule per coulomb.

    True.

    One volt is equal to one joule per coulomb, 1 V = 1 J C–1.

  • True or False?

    A cell or battery provides the source of potential difference in an a.c. circuit.

    False.

    A cell or battery provides the source of potential difference in a d.c. circuit.

  • True or False?

    Electrons are stored in the cell and flow through the wires when the circuit is closed.

    False.

    The electrons in the circuit are the delocalised electrons in the metal of the wires and components. They flow around the closed circuit when a potential difference is applied.

  • Define the electronvolt.

    The electronvolt is the amount of energy needed to move an electron through a potential difference of one volt.

  • State the value of one electronvolt in joules.

    One electronvolt is equal to 1.6 cross times 10 to the power of negative 19 end exponent space straight J.

    • W space equals space q V space equals space 1.6 cross times 10 to the power of negative 19 end exponent space cross times space 1 space equals space 1.6 cross times 10 to the power of negative 19 end exponent space straight J

  • Convert 12 eV into J.

    12 eV in J is

    • W space equals space q V space equals space 1.6 cross times 10 to the power of negative 19 end exponent space cross times space 12 space equals space 1.9 cross times 10 to the power of negative 18 end exponent space straight J space

  • What is an electrical conductor?

    An electrical conductor is a material that allows charge (usually electrons) to flow through it easily.

  • Give one example of an electrical conductor.

    Examples of electrical conductors are:

    • copper

    • silver

    • aluminium

    • steel

    • gold

  • Why are metals good electrical conductors?

    Metals are good electrical conductors because metals have delocalised electrons that flow when a potential difference is applied.

  • What is an electrical insulator?

    An electrical insulator is a material that has no delocalised electrons, so it does not allow charge to flow easily.

  • Give one example of an electrical insulator.

    Examples of electrical insulators are:

    • rubber

    • plastic

    • glass

    • wood

  • What is static electricity?

    Static electricity occurs when charge builds up on the surface of an insulator and is discharged when brought into contact with a conductor.

  • Define an ideal ammeter.

    An ideal ammeter has zero resistance, such that all the current passes through it.

  • Define an ideal voltmeter.

    An ideal voltmeter has infinite resistance, such that no current passes through it.

  • Define the resistance of a component.

    The resistance of a component is the ratio of the potential difference across the component to the current flowing through it.

  • State the equation for resistance known as Ohm's law.

    The equation for resistance known as Ohm's law is R space equals fraction numerator space V over denominator I end fraction

    Where:

    • R = resistance of component, measured in ohms (Ω)

    • V = potential difference, measured in volts (V)

    • I = current, measured in (A)

  • True or False?

    The greater the resistance of a component, the higher the current flowing through it.

    False.

    The greater the resistance of a component, the lower the current flowing through it.

  • State the SI base units for 1 Ω.

    The SI base units for 1 Ω are kg m–2 s–3 A–2.

  • True or False?

    For resistance calculations, mA and kV must be converted into A and V.

    True.

    For resistance calculations, mA and kV must be converted into A and V.

  • True or False?

    Resistance is caused by collisions between flowing electrons and the metal ions in the conductor.

    True.

    Resistance is caused by collisions between flowing electrons and the metal ions in the conductor.

  • State the factors affecting resistance.

    The factors affecting resistance are:

    • material

    • length

    • cross-sectional area

    • temperature

  • True or False?

    The resistance of a wire is directly proportional to its length.

    True.

    The resistance of a wire is directly proportional to its length.

  • True or False?

    The resistance of a wire is directly proportional to its cross-sectional area.

    False.

    The resistance of a wire is inversely proportional to its cross-sectional area.

  • Define resistivity.

    Resistivity is the electrical resistance of a conductor of unit cross-sectional area and unit length.

  • State the equation for resistivity.

    The equation for resistivity is rho space equals space fraction numerator R A over denominator L end fraction

    Where:

    • rho = resistivity, measured in ohm metres (Ω m)

    • R = resistance, measured in ohms (Ω)

    • A = cross-sectional area, measured in metres squared (m2)

    • L = length, measured in metres (m)

  • Do metals have high or low values of resistivity?

    Metals have low values of resistivity, and insulators have high values.

  • State the equation for the cross-sectional area of a circle.

    The equation for the cross-sectional area of a circle is A space equals space straight pi r squared

    Where:

    • A = cross-sectional area, measured in metres squared (m2)

    • r = radius of circle, measured in metres (m)

  • State the equation for the cross-sectional area of a circle in terms of the diameter.

    The equation for the cross-sectional area of a circle in terms of diameter is A space equals fraction numerator straight pi d to the power of italic 2 over denominator 4 end fraction

    Where:

    • A = cross-sectional area, measured in metres squared (m2)

    • d = diameter of circle, measured in metres (m)

  • What does the gradient of an I-V graph represent?

    The gradient of an I-V graph represents the resistance of a component.

  • What does a linear I-V graph show?

    A linear I-V (current-voltage) graph shows

    • the relationship between current and potential difference is directly proportional

    • the resistance of the component is constant

  • Which component has the following I-V graph?

    Graph showing current on the vertical axis and potential difference on the horizontal axis, with a blue line indicating a linear relationship.

    This is the I-V graph for a fixed resistor or a wire (at a constant temperature).

  • Which component has the following I-V graph?

    Graph showing current on the vertical axis and potential difference on the horizontal axis, with a blue curve indicating a non-linear relationship.

    This is the I-V graph for a filament lamp.

  • Which component has the following I-V graph?

    Graph showing current on the vertical axis and potential difference on the horizontal axis, with a red curve rising sharply.

    This is the I-V graph for a diode.

  • True or False?

    As the current through a filament lamp increases, the resistance decreases.

    False.

    As the current through a filament lamp increases, the resistance increases.

  • Why does the resistance of a filament lamp change when the voltage is changed?

    The resistance of a filament lamp increases as the voltage is increased because

    • as the voltage increases, current increases, and the lamp heats up

    • as the temperature increases, metal ions in the filament wire vibrate more

    • the number of collisions between the ions and free electrons increases

  • What are the main features of an I-V graph for a diode?

    The I-V graph for a diode shows they have

    • a high resistance when the current flows in one direction

    • a low resistance when the current flows in the opposite direction

  • True or False?

    Current is different at different points in a series circuit.

    False.

    Current is the same everywhere in a series circuit.

  • True or False?

    In a parallel circuit, the current from the power source is larger than the current in each branch.

    True.

    In a parallel circuit, the current from the power source is larger than the current in each branch.

  • True or False?

    The amount of current flowing in a series circuit depends on the potential difference and resistance in the circuit.

    True.

    The amount of current flowing in any circuit depends on the potential difference and resistance in the circuit.

  • True or False?

    Current is conserved at a junction in a parallel circuit.

    True.

    Current is conserved at a junction in a parallel circuit because charge is always conserved.

  • True or False?

    Current always splits equally at a junction in a parallel circuit.

    False.

    Current will only split equally at a junction if the resistance in each branch is equal.

  • What is the rule for determining the current in a series circuit?

    The current in a series circuit is the same through all the components.

    This can be expressed mathematically as: I space equals space I subscript 1 space equals space I subscript 2 space...

  • What is the rule for determining the current in a parallel circuit?

    The total current through the components in a parallel circuit is equal to the sum of the individual currents through each branch.

    This can be expressed mathematically as: I space equals space I subscript 1 space plus space I subscript 2 space plus space...

  • True or False?

    When several cells are connected in series, the potential difference across them all is the product of the separate potential differences.

    False.

    When several cells are connected in series, the potential difference across them all is the sum of the separate potential differences.

  • What is the rule for determining the total potential difference in a series circuit?

    The total potential difference across the components in a series circuit is equal to the sum of the individual potential differences across each component.

    This can be expressed mathematically as: V space equals space V subscript 1 space plus space V subscript 2 space plus space...

  • What is the rule for determining the total potential difference in a parallel circuit?

    The total potential difference across an arrangement of parallel resistances is the same as the potential difference across one branch in the arrangement of the parallel resistances.

    This can be expressed mathematically as: V space equals space V subscript 1 space equals space V subscript 2 space...

  • True or False?

    The combined resistance of two resistors in parallel is less than that of either resistor by itself.

    True.

    The combined resistance of two resistors in parallel is less than that of either resistor by itself.

  • What is the rule for calculating the combined resistance of two or more resistors in series?

    When two or more resistors are connected in series, the combined resistance is the sum of the individual resistances.

    This can be expressed mathematically as: R subscript s space equals space R subscript 1 space plus space R subscript 2 space plus space...

  • What is the rule for calculating the combined resistance of two or more resistors in parallel?

    When two or more resistors are connected in parallel, the combined resistance is the sum of the reciprocals of the individual resistances.

    This can be expressed mathematically as: 1 over R subscript p space equals space fraction numerator space 1 space over denominator R subscript 1 end fraction space plus space fraction numerator space 1 space over denominator R subscript 2 end fraction space plus space...

  • If the potential difference of the power source remains constant, but more components are added to a circuit, what effect does this have on the current?

    Adding components to a circuit increases the total resistance of the circuit, so the current would decrease (for a constant potential difference).

  • If the potential difference of the power source is increased, but everything else in the circuit remains constant, what effect does this have on the current?

    If the potential difference of the power source is increased, but everything else in the circuit remains constant, the current will increase.

  • Define electrical power.

    Electrical power is the rate at which energy is transferred or dissipated by a resistor.

  • True or False?

    Work is done when energy is transferred by moving charges in a circuit.

    True.

    Work is done when energy is transferred by moving charges in a circuit.

  • State the equation linking electrical power, P, potential difference, V, and current, I.

    The equation for electrical power is: P space equals space I V

    Where:

    • P = electrical power, measured in watts (W)

    • V = potential difference, measured in volts (V)

    • I = current, measured in amps (A)

  • State the equation linking electrical power, P, current, I, and resistance, R.

    The equation for electrical power is: P space equals space I squared R

    Where:

    • P = electrical power, measured in watts (W)

    • I = current, measured in amps (A)

    • R = resistance, measured in ohms (Ω)

  • State the equation linking electrical power, P, potential difference, V, and resistance, R.

    The equation for electrical power is: P space equals space V squared over R

    Where:

    • P = electrical power, measured in watts (W)

    • V = potential difference, measured in volts (V)

    • R = resistance, measured in ohms (Ω)

  • State the equation linking energy transferred, E, potential difference, V, current, I, and time, t.

    The equation for energy transferred is: E space equals space V I t

    Where:

    • E = electrical power, measured in watts (W)

    • V = potential difference, measured in volts (V)

    • I = current, measured in amps (A)

    • t = time, measured in seconds (s)

  • How are chemical cells used as an energy source in circuits?

    Chemical cells use the energy stored in chemicals to arrange charges in a way that produces a potential difference.

  • How are solar cells used as an energy source in circuits?

    Solar cells use the radiant energy from the Sun to produce a potential difference.

  • How are electrical generators used as a source of electrical energy?

    Electrical generators use the energy from burning fuels to convert kinetic energy into electric potential energy to produce a potential difference.

  • How are wind generators used as a source of electrical energy?

    Wind generators use the energy from moving air to convert the kinetic energy of wind into electric potential energy to produce a potential difference.

  • State two advantages of single-use alkaline batteries.

    Advantages of single-use alkaline batteries are:

    • the chemicals used have a high energy density

    • they are a convenient source of energy used in everyday appliances

    • they are a portable source of electrical energy

    • several batteries can be combined in series to increase p.d.

    • they are very inexpensive

  • State two disadvantages of single-use alkaline batteries.

    Disadvantages of single-use alkaline batteries are:

    • they are non-rechargeable and need to be replaced often

    • they have a high internal resistance

    • they contribute to pollution when disposed

    • they are made from non-renewable materials

  • State two advantages of lithium-ion batteries.

    Advantages of lithium-ion batteries are:

    • they have a very high energy density

    • they have a high electrical efficiency

    • they are a convenient source of energy used in everyday appliances (e.g. laptops, phones)

    • they are rechargeable and have a long lifetime

    • they have a fast charging time

    • they are a portable source of electrical energy

    • they have a low internal resistance

  • State two disadvantages of lithium-ion batteries.

    Disadvantages of lithium-ion batteries are:

    • the charge capacity of the cell degrades over time

    • the internal resistance increases over time

    • they are expensive compared to other types of battery

  • State two advantages of lead-acid batteries.

    Advantages of lead-acid batteries are:

    • they are relatively cheap

    • they are rechargeable

    • they are able to deliver very high currents in a short time which is useful for starting up vehicles

  • State two disadvantages of lead-acid batteries.

    Disadvantages of lead-acid batteries are:

    • they have a low energy density

    • the internal resistance increases as the battery degrades over time

    • they have a limited number of full discharge cycles

    • they contribute to pollution when disposed as they contain toxic and corrosive materials

    • they are made from non-renewable materials

  • State two advantages of photovoltaic cells.

    Advantages of photovoltaic cells are:

    • they provide a virtually unlimited supply of energy

    • they are a clean energy supply and do not contribute to pollution

    • the energy source (the Sun) is freely available everywhere

    • they are cheap to maintain

    • no input of fuel is required

  • State two disadvantages of photovoltaic cells.

    Disadvantages of photovoltaic cells are:

    • the output can be variable due to dependence on weather conditions

    • energy output can be significantly impacted by poor weather

    • they have a low efficiency

    • they can only generate energy during daylight hours

    • each cell only produces a small amount of electricity

    • solar farms are required for large scale electricity production

  • State two advantages of wind generators.

    Advantages of wind generators are:

    • they provide a virtually unlimited supply of energy

    • they are a clean energy supply and do not contribute to pollution

    • the energy source (the wind) is freely available everywhere

    • they are cheap to maintain

    • no input of fuel is required

  • State two disadvantages of wind generators.

    Disadvantages of wind generators are:

    • the output can be variable due to dependence on weather conditions

    • energy output can be significantly impacted by lack of wind

    • they have a low efficiency

    • they contribute to noise and visual pollution

  • State two advantages of fossil fuel generators.

    Advantages of fossil fuel generators are:

    • there is already an extensive infrastructure in place

    • the fuels used have a high energy density

    • they are highly reliable and provide energy consistently

    • they are a well-known and developed technology

  • State two disadvantages of fossil fuel generators.

    Disadvantages of fossil fuel generators are:

    • they produce significant greenhouse gas emissions which contribute to global warming

    • they produce other polluting gases which contribute to acid rain and other environmental issues

    • fossil fuels are a non-renewable energy source

  • Define electromotive force (emf).

    Electromotive force (emf) is the total energy transferred in a source of electrical energy per unit charge passing through it.

  • Define internal resistance.

    Internal resistance is the resistance of a source of electrical energy, such as batteries, as they are not perfect conductors.

  • Define terminal potential difference.

    Terminal potential difference is the potential difference across the terminals of a source of electrical energy when it is supplying a current to a circuit.

  • What are 'lost volts'?

    'Lost volts' refer to the voltage drop, or decrease in potential difference, that occurs when a source of electrical energy supplies a current to a circuit.

  • State the equation linking emf and internal resistance.

    The equation linking emf and internal resistance is: epsilon space equals space I open parentheses R space plus space r close parentheses

    Where:

    • epsilon = electromotive force (emf), measured in volts (V)

    • I = current, measured in amps (A)

    • R = resistance available to the rest of the circuit, measured in ohms (Ω)

    • r = internal resistance, measured in ohms (Ω)

  • True or False?

    When the internal resistance is zero, the terminal p.d. of a cell is less than its emf.

    False.

    When the internal resistance is zero, the terminal p.d. of a cell is equal to its emf. This is when no current flows.

  • True or False?

    When a current flows, the terminal p.d. of a cell will be less than its emf.

    True.

    When a current flows, the terminal p.d. of a cell will be less than its emf. This is because there will be a potential drop across the internal resistance.

  • What is a thermistor?

    A thermistor is a temperature-dependent resistor.

    This means its resistance changes depending on its temperature.

    The circuit symbol for a thermistor.
  • How does the resistance of a thermistor change when its temperature is increased?

    When the temperature of a thermistor is increased, its resistance decreases.

  • What is an LDR?

    LDR stands for light-dependent resistor.

    This means its resistance changes depending on the intensity of light on it.

    The circuit symbol for a light-dependent resistor.
  • How does the resistance of an LDR change when the intensity of light on it is increased?

    When light intensity on an LDR is increased, its resistance decreases.

    (Remember: Light Decreases Resistance - LDR)

  • Sketch a graph to show the relationship between resistance and temperature for a thermistor.

    For a thermistor, the relationship between resistance and temperature is

    Graph showing resistance decreasing with increasing temperature. At low temperatures, the resistance is high. At high temperatures, the resistance is low.
  • Sketch a graph to show the relationship between resistance and light intensity for an LDR.

    For an LDR, the relationship between resistance and light intensity is

    Graph showing resistance decreasing with increasing light intensity. At low intensities, the resistance is high. At high intensities, the resistance is low.
  • What is a variable resistor?

    A variable resistor is a resistor that can change the resistance by changing the length of the wire that makes up the circuit.

    This is because a longer length of wire has more resistance than a shorter length of wire.

  • What is a potentiometer?

    A potentiometer is a type of variable resistor that uses a sliding contact to vary the potential difference in a circuit.