Electric & Magnetic Fields (DP IB Physics)

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  • Define 1 coulomb (C).

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Cards in this collection (108)

  • Define 1 coulomb (C).

    1 coulomb is the charge carried by an electric current of one ampere in one second.

  • True or False?

    Charge is a vector quantity.

    False.

    Charge is a scalar quantity. It has magnitude only, not direction.

  • How is this carbon atom electrically neutral?

    A carbon atom with labelled components: neutrons (green), protons (blue) in the nucleus, and electrons (red) around the nucleus.

    The carbon atom contains:

    • 6 positive protons

    • 6 negative electrons

    • 6 neutral neutrons

    The amount of positive and negative charge is equal, so the carbon atom is electrically neutral.

  • How is charge quantised?

    Charge is quantised because any quantity of charge will always equal a whole number of protons or electrons, which have a charge equal to ±1.60 × 10−19 C.

  • Is the electric force between two charges of the same type attractive or repulsive?

    The electric force on two charges of the same type is repulsive (directed away from each other).

  • Is the electric force between two opposite charges attractive or repulsive?

    The electric force on two opposite charges is attractive (directed towards each other).

  • What is the law of conservation of charge?

    The law of conservation of charge states that the total charge in an isolated system remains constant.

  • True or False?

    When two charged spheres come into contact, the charges are shared between them until they are evenly distributed.

    True.

    When two charged spheres come into contact, the charges are shared between them until they are evenly distributed. As a result, both spheres will have an equal charge.

  • What is the final charge on two spheres of initial charge +1 C and +9 C when brought into contact?

    According to the law of conservation of charge, the final charge on each sphere is equal to the average of the two charges

    Q space equals space fraction numerator 1 space plus space 9 over denominator 2 end fraction space equals space plus 5 space straight C

  • What is the final charge on two spheres of initial charge +4 C and -4 C when brought into contact?

    According to the law of conservation of charge, the final charge on each sphere is equal to the average of the two charges 0 C

    • Q space equals space fraction numerator 4 space minus space 4 over denominator 2 end fraction space equals space 0 space straight C

  • What does Millikan's oil drop experiment provide evidence for?

    Millikan's oil drop experiment provides evidence for the quantisation of charge.

  • What is meant by the term fundamental charge?

    The fundamental charge (or elementary charge) is the charge of a single proton (+1.60 × 10−19 C) or electron (-1.60 × 10−19 C).

  • In Millikan's experiment, why are oil drops used instead of water?

    In Millikan's experiment, oil drops are used as they do not evaporate quickly like water. This allows the mass of the drops to remain constant throughout the experiment.

  • In Millikan's experiment, how do the oil drops become charged?

    In Millikan's experiment, the oil drops can become charged by

    • friction (using a spray nozzle)

    • ionisation (using X-rays)

  • In Millikan's experiment, what happens to the oil drops in the absence of an electric field?

    In Millikan's experiment, when no electric field is applied, the oil drops fall under gravity until they reach a terminal velocity.

  • What is the role of the uniform electric field in Millikan's experiment?

    In Millikan's experiment, the uniform electric field provides an electric force which is equal and opposite to the gravitational force on an oil drop. The resultant force will then be zero and the drop will become stationary.

  • In Millikan's experiment, what quantities are needed to calculate the charge of an oil drop?

    In Millikan's experiment, the charge of an oil drop is calculated by equating the gravitational and electric forces

    F space equals space m g space equals space E q space equals space fraction numerator V q over denominator d end fraction

    Therefore, the quantities needed to calculate the charge, q, are:

    • the mass of the drop, m

    • the potential difference between the metal plates, V

    • the distance between the metal plates, d

  • What was the conclusion of Millikan's experiment?

    The conclusion of Millikan's experiment was:

    • the charges of all drops were found to be multiples of the same number (-1.60 × 10−19 C)

    • therefore, electric charge must be a quantised quantity

  • What is charging by friction?

    Charging by friction is the transfer of charge (electrons) when two insulating substances move past one another.

    One substance gains an excess of positive charge and the other gains an excess of negative charge.

  • What is charging by contact?

    Charging by contact is the transfer of charge (electrons) between two substances when there is physical contact between them.

    The excess, or deficit, of electrons, is shared between the two substances.

  • What is charging by induction?

    Charging by induction is the separation of charge caused by the influence of a nearby charged object without any physical contact.

    The charged object causes electrons near the surface of the uncharged substance to be either repelled or attracted.

  • Describe the movement of electrons when an uncharged acetate rod is rubbed with an uncharged cloth.

    Two illustrations: 
1. Uncharged plastic rod with an uncharged cloth.
2. Negatively charged cloth and positively charged rod shown with plus and minus symbols.

    When an uncharged acetate rod is rubbed with an uncharged cloth:

    • electrons are transferred from the acetate rod to the cloth by friction

    • the cloth becomes negatively charged because it gains electrons

    • the acetate rod becomes positively charged because it loses electrons

  • True or False?

    Earthing a charged body causes it to discharge until its potential drops to half its initial value.

    False.

    Earthing a charged body causes it to discharge until it has a potential of 0 V.

  • How can a metal sphere become charged by induction?

    A metal sphere can become charged by induction by

    • bringing a charged rod near the sphere without touching it (this separates the charges)

    • earthing the sphere (this allows electrons to flow to or from the sphere)

    • removing the earth connection and the rod (this leaves an excess charge)

  • True or False?

    A metal sphere can become positively charged by induction by using a positively charged rod.

    False.

    A metal sphere can become positively charged by induction by using a negatively charged rod.

    When inducing a charge on a metal sphere, its final charge will always be opposite to the rod.

  • How can a metal sphere become charged by contact?

    A metal sphere can become charged by contact by

    • bringing a charged rod into contact with the sphere (this allows electrons to flow to or from the sphere)

    • removing the rod (this leaves an excess charge)

  • How can sparks occur when refuelling an aircraft?

    Sparks can occur when

    • there is a large build-up of charge on the aircraft

    • the potential difference becomes large enough for current to travel through the air

  • How can the risk of sparks be reduced when refuelling an aircraft?

    When refuelling an aircraft, the risk of sparking can be reduced by earthing the aircraft and fuel tank to carry excess charge away.

  • What is Coulomb's law?

    Coulomb's law states that the electric force between two point charges is directly proportional to the product of the charges and inversely proportional to the square of their separation.

  • What is the electric force between two identical charges of magnitude, q, separated by a distance, r?

    The electric force between the two identical charges is: F space equals space fraction numerator k q squared over denominator r squared end fraction

    Where:

    • k = Coulomb constant (8.99 × 109 N m2 C–2)

    • q = magnitude of the charges (C)

    • r = separation of the charges (m)

  • How is Coulomb's law analogous to Newton's law of gravitation?

    Coulomb's law: F space equals space k fraction numerator q subscript 1 q subscript 2 over denominator r squared end fraction

    Newton's law of gravitation: F space equals space G fraction numerator m subscript 1 m subscript 2 over denominator r squared end fraction

    Both electric force and gravitational force follow an inverse square law with distance.

  • Is the electric force between two opposite charges positive or negative?

    The electric force between two opposite charges is negative.

    A negative force means the force is attractive.

  • Is the electric force between two similar charges positive or negative?

    The electric force between two similar charges is positive.

    A positive force means the force is repulsive.

  • True or False?

    Coulomb's law can be applied to any charged object regardless of shape or size.

    False.

    Coulomb's law can only be applied to charged spheres.

  • True or False?

    The value of, k, (Coulomb constant) is the same in all materials.

    False.

    The value of, k, (Coulomb constant) is not the same in all materials.

    • In a vacuum (or air): k space equals space fraction numerator 1 over denominator 4 straight pi epsilon subscript 0 end fraction

    • In other materials: k space equals space fraction numerator 1 over denominator 4 straight pi epsilon end fraction

    Where epsilon subscript 0 = permittivity of free space and epsilon = permittivity of a material

  • What is the permittivity of a medium?

    The permittivity of a medium represents the medium's ability to transfer an electric field and force between charges in it.

  • How is the permittivity of a medium related to the permittivity of free space?

    The permittivity of a medium is related to the permittivity of free space by: epsilon subscript r space equals space epsilon over epsilon subscript 0

    Where:

    • epsilon subscript r = relative permittivity

    • epsilon = permittivity of a medium

    • epsilon subscript 0 = permittivity of free space

  • True or False?

    All materials have a higher relative permittivity than air.

    True.

    All materials have a higher relative permittivity than air.

    • Relative permittivity of air: epsilon subscript r space equals space 1

    • Relative permittivity of other materials: epsilon subscript r space greater than space 1

  • Define electric field strength at a point.

    The electric field strength at a point is the force per unit charge experienced by a small positive test charge placed at that point.

  • What are the two equivalent units of electric field strength?

    The two equivalent units of electric field strength are N C-1 and V m-1.

  • What is the significance of a test charge?

    Test charges are used to define the strength of a field at a point and the direction a charge will move in the field.

    This is because electric field strength is a vector quantity.

  • How is the direction of an electric field defined?

    The direction of an electric field is defined by the direction of the force that acts on a positive test charge, such that

    • the force on a positive charge is in the direction of the field

    • the force on a negative charge is in the opposite direction

  • What is the electric field strength due to a point charge of magnitude, q, at a distance, r?

    The electric field strength due to a point charge is: E space equals space fraction numerator k q over denominator r squared end fraction

    Where:

    • k = Coulomb constant (8.99 × 109 N m2 C–2)

    • q = magnitude of the charge (C)

    • r = distance from the charge to the point (m)

  • True or False?

    The variation of electric field strength around a charged sphere and a point charge are identical.

    False.

    The variation of electric field strength around the outside of a charged sphere and a point charge are identical.

    Inside the charged sphere, the electric field strength is zero.

  • How is the resultant electric field due to multiple charges determined?

    The resultant electric field due to multiple charges is determined by vector addition. This could be

    • using simple addition (if the point lies on a line joining the charges)

    • using Pythagoras (if the point makes a right-angled triangle with the charges)

  • How is a uniform electric field set up?

    A uniform electric field can be set up between two parallel metal plates by connecting them to the terminals of a power supply.

  • Which two quantities does the strength of an electric field between two parallel plates depend on?

    The strength of an electric field between two parallel plates is: E space equals space V over d

    Where:

    • V = potential difference between the plates (V)

    • d = separation of the plates (m)

  • An electron is placed in the uniform electric field shown in the diagram. In which direction will it move?

    Parallel horizontal lines with arrows directed from left to right, representing an electric field. A circle labelled "e-" indicates an electron in the field.

    The electron will move to the left towards the positively charged plate.

    A uniform electric field with parallel horizontal lines directed from left to right. The plate on the left is positively charged, and the plate on the right is negatively charged. An electron is shown moving to the left.
  • What do electric field lines represent?

    Electric field lines represent

    • the strength of the electric field

    • the direction of the electric field

  • Draw the electric field lines around a positive point charge.

    The electric field lines around a positive point charge are

    Diagram of electric field lines radiating outwards from a positive charge with arrows pointing away from the charge.
  • Draw the electric field lines around a negative point charge.

    The electric field lines around a negative point charge are

    Electric field lines around a negative charge with arrows pointing towards the charge.
  • Draw the electric field lines around two opposite charges.

    The electric field lines around two opposite charges are

    Electric field lines between a negative charge on the left and a positive charge on the right, indicating field direction from positive to negative.
  • Draw the electric field lines around two similar charges.

    The electric field lines around two similar charges are

    Two positive charges are shown with outward radial electric field lines indicating repulsion. Field lines are denser near the charges, depicting stronger fields.
  • Draw the electric field lines between a positive charge and an earthed plate.

    Diagram of a grounded parallel plate near a positive charge.

    The electric field lines between a positive charge and an earthed plate are

    Diagram of electric field lines between a positive charge and a grounded plate. Arrows indicate the direction of the field lines away from the charge.

    The grounded plate has a potential of 0 V, so the field lines are directed from the positive charge to the 'less positive' plate.

  • True or False?

    Field lines are always perpendicular to the surface of a conducting sphere.

    True.

    Field lines are always perpendicular to the surface of a conducting sphere.

  • True or False?

    The field lines around the edges of two parallel plates are uniform.

    False.

    The field lines around the edges of two parallel plates are not uniform.

  • What two factors does the strength of a radial electric field depend on?

    The strength of a radial electric field depends on

    • the magnitude of the charge producing the field

    • the distance between the charge and a point

  • What is the relationship between electric field strength and line density?

    The density of field lines represents the strength of an electric field

    • the closer together the field lines, the stronger the field

    • the further apart the field lines, the weaker the field

  • True or False?

    Magnetic fields are produced around all charges.

    False.

    Magnetic fields are produced around all moving charges.

  • Define electric potential at a point.

    The electric potential at a point is the work done per unit charge in taking a small positive test charge from infinity to a defined point.

  • Define magnetic flux density.

    The magnetic flux density of a field is the number of magnetic field lines passing through a region of space per unit area.

  • True or False?

    Electric potential is a vector quantity.

    False.

    Electric potential is a scalar quantity.

  • Define 1 tesla (T).

    One tesla (T) is the flux density that causes a force of 1 N on a 1 m wire carrying a current of 1 A at right angles to the field.

  • What is the unit of electric potential?

    The unit of electric potential is J C-1 or V.

  • What is the relationship between flux density and the strength of a magnetic field?

    The flux density is a measure of the strength of a magnetic field

    • the higher the flux density, the stronger the magnetic field

    • the lower the flux density, the weaker the magnetic field

  • What is the electric potential due to a point charge of magnitude, q, at a distance, r?

    The electric potential due to a point charge is: V space equals space fraction numerator k q over denominator r end fraction

    Where:

    • k = Coulomb constant (8.99 × 109 N m2 C–2)

    • q = magnitude of the charge (C)

    • r = distance from the charge to the point (m)

  • How is a uniform magnetic field set up?

    A uniform magnetic field can be set up between two flat permanent magnets when the north pole of one magnet is parallel to the south pole of the other.

  • True or False?

    Electric potential increases when a test charge moves closer to an isolated positive charge.

    True.

    Electric potential increases when a test charge moves closer to an isolated positive charge.

  • What is the right-hand grip rule?

    The right-hand grip rule is used to determine the direction of a magnetic field around a current:

    • the thumb points in the direction of the current

    • the fingers curl in the direction of the magnetic field

    The right-hand grip rule is where magnetic field lines are clockwise when the current is directed upwards and anticlockwise when the current is directed downwards.
  • True or False?

    Electric potential decreases when a test charge moves away from an isolated negative charge.

    False.

    Electric potential increases when a test charge moves away from an isolated negative charge.

  • Draw the magnetic field lines around a current-carrying wire.

    The magnetic field lines around a current-carrying wire:

    A vertical wire with current flowing upwards. Surrounding the wire are concentric circles representing magnetic field lines with clockwise direction.
  • Sketch the variation of electric potential with distance for a positive charge.

    Graph with a vertical axis labelled "Electric Potential" and a horizontal axis labelled "Distance from surface of positive charge"

    For a positive charge, electric potential decreases as the distance increases.

    Graph showing electric potential decreasing with increasing distance from the surface of a positive charge. The horizontal axis is distance, and the vertical axis is electric potential.
  • Draw the magnetic field lines around a solenoid.

    The magnetic field lines around a solenoid:

    A solenoid with magnetic field lines looping through it, and arrows indicating the current direction through the solenoid.
  • True or False?

    Electric potential increases in the direction of electric field lines.

    False.

    Electric potential decreases in the direction of electric field lines.

  • Draw the magnetic field lines around a flat circular coil.

    The magnetic field lines around a flat circular coil:

    Magnetic field lines of a circular coil with labelled arrows indicating current direction and field lines, forming concentric circles around the coil.
  • True or False?

    Inside a charged sphere, the electric potential is zero.

    False.

    Inside a charged sphere, the electric potential has a constant non-zero value.

  • True or False?

    When viewed from the end of a solenoid, the pole is a north pole if the current travels clockwise around the coil.

    False.

    When viewed from the end of a solenoid, the pole is a south pole if the current travels clockwise around the coil.

    Hand demonstrates the right-hand rule over a coiled wire, indicating current direction with red arrows and magnetic poles (N and S) with blue arrows.
  • True or False?

    The combined electric potential at a point due to multiple charges is determined by vector addition.

    False.

    The combined electric potential at a point due to multiple charges is determined by adding together the potentials due to each of the charges.

  • Define electric potential energy.

    Electric potential energy is the work done when bringing all the charges in a system to their positions from infinity.

  • True or False?

    Electric potential energy is always positive.

    False.

    Electric potential energy can be positive or negative depending on the signs of the charges involved.

  • What happens to the electric potential energy of two similar charges as their separation increases?

    The electric potential energy of two similar charges decreases as the separation between them increases.

  • What happens to the electric potential energy of two opposite charges as their separation increases?

    The electric potential energy of two opposite charges increases as the separation between them increases.

  • What is the electric potential energy of two point charges with magnitudes +q and -q separated by a distance r?

    The electric potential energy of two opposite charges is: E subscript p space equals space minus fraction numerator k q squared over denominator r end fraction

    Where:

    • k = Coulomb constant (8.99 × 109 N m2 C–2)

    • q = magnitude of the charges (C)

    • r = separation between charges (m)

  • True or False?

    Electric potential and electric potential energy are both equal to zero at infinity.

    True.

    Electric potential and electric potential energy are both equal to zero at infinity.

  • When a charge q subscript 2 moves away from a chargespace q subscript 1, what is the change in electric potential energy?

    The change in electric potential energy (or work done) is increment E subscript p space equals space k q subscript 1 q subscript 2 open parentheses 1 over r subscript 1 space minus space 1 over r subscript 2 close parentheses

    Where:

    • k = Coulomb constant (8.99 × 109 N m2 C–2)

    • q subscript 1, q subscript 2 = magnitudes of the charges (C)

    • r subscript 1 = initial separation between charges (m)

    • r subscript 2 = final separation between charges (m)

  • What does the area under a force-distance graph represent?

    The area under a force-distance graph represents the change in electric potential energy or the work done in moving the charge from one point to another.

  • Name two scenarios in which the change in electric potential energy is similar to the change in gravitational potential when a small mass moves away from a large mass.

    When a small mass moves away from a large mass, the gravitational potential energy increases.

    The change in electric potential energy is similar when:

    • a small positive charge moves away from a large negative charge

    • a small positive charge moves towards a large positive charge

  • Name two scenarios in which the change in electric potential energy is similar to the change in gravitational potential when a small mass moves towards a large mass.

    When a small mass moves towards a large mass, the gravitational potential energy decreases.

    The change in electric potential energy is similar when:

    • a small positive charge moves towards a large negative charge

    • a small positive charge moves away from a large positive charge

  • What is the work done in moving a charge, q, in an electric field?

    The work done in moving a charge, q, in an electric field is: W space equals space q increment V

    Where:

    • q = magnitude of charge moving in the field (C)

    • increment V = potential difference between two points (V or J C−1)

  • Define electric potential difference.

    Electric potential difference is the difference in electric potential between two points.

    It is equal to the work done when a charge of 1 C is moved between the points.

  • What is the potential difference due to a point charge Q when a charge is moved from a distance r subscript 2 to r subscript 1?

    The potential difference due to a point charge is: increment V space equals space k Q open parentheses 1 over r subscript 1 space minus space 1 over r subscript 2 close parentheses

    Where:

    • k = Coulomb constant (8.99 × 109 N m2 C–2)

    • Q = magnitude of charge producing the potential (C)

    • r subscript 2 = initial distance from charge Q (m)

    • r subscript 1 = final distance from charge Q (m)

  • Define the potential gradient of an electric field.

    Potential gradient is the rate of change of electric potential with respect to displacement in the direction of the field.

  • What does the negative sign indicate in the potential gradient equation?

    In the potential gradient equation E space equals space minus fraction numerator increment V over denominator increment r end fraction

    The negative sign indicates that the direction of the field strength E opposes the direction of increasing potential.

  • What does the gradient of a V minus r graph represent?

    The gradient of a potential-distance open parentheses V minus r close parentheses graph represents the electric field strength at that point.

  • What does the area under an E minus r graph represent?

    The area under a field-distance open parentheses E minus r close parentheses graph represents the potential difference between the two points.

  • True or False?

    The V minus r graph for a positive charge follows a negative 1 over r relation

    False.

    The potential-distance open parentheses V minus r close parentheses graph for a positive charge follows a 1 over r relation.

    All values of potential are positive for a positive charge.

  • True or False?

    The E minus r graph for a negative charge follows a negative 1 over r relation

    False.

    The field-distance open parentheses E minus r close parentheses graph for a negative charge follows a negative 1 over r squared (inverse square law) relation.

    All values of field strength are negative for a negative charge

  • True or False?

    The curve of an E minus r graph is steeper than its corresponding V minus r graph

    True.

    The curve of an E minus r graph is steeper than its corresponding V minus r graph.

    This is because E minus r graphs follow a 1 over r squared relation whereas V minus r graphs follow a 1 over r relation.

  • What is an electric equipotential surface?

    Equipotential surfaces (or lines) connect points of equal electric potential.

  • True or False?

    Equipotential lines are always parallel to electric field lines.

    False.

    Equipotential lines are always perpendicular to electric field lines.

  • True or False?

    No work is done as a charge moves along an equipotential line.

    True.

    No work is done as a charge moves along an equipotential line.

  • What are the key features of the equipotential lines in a radial electric field?

    The key features of the equipotential lines in a radial electric field are:

    • concentric circles

    • become further apart with distance

  • What are the key features of the equipotential lines in a uniform electric field?

    The key features of the equipotential lines in a uniform electric field are:

    • horizontal straight lines

    • parallel

    • equally spaced

  • Draw the electric field lines and equipotential lines around the point charges.

    Diagram showing a positive charge on the left and a negative charge on the right

    The field lines (black arrows) and equipotential lines (dotted green lines) for a positive and negative point charge are:

    A positive charge is on the left and a negative charge is on the right. Their radial electric field lines are shown in black. Their equipotential lines are shown in green.
  • Draw the electric field lines and equipotential lines between the parallel plates.

    Two parallel metal plates. The plate on the left has a positive charge. The plate on the right has a negative charge.

    The field lines (black arrows) and equipotential lines (dotted green lines) for a uniform electric field are:

    Two parallel metal plates. The plate on the left has a positive charge and the plate on the right has a negative charge. The uniform electric field lines are shown in black. The equipotential lines are shown in green.
  • Does the following equipotential surface show two similar or opposite charges?

    Equipotential lines between two charges where curved lines emanate outward. The signs of the charges are not included. At the midpoint between the charges is a vertical line.

    This is the equipotential surface for two opposite charges. The central line has a potential of 0 V.

    Equipotential lines between two opposite charges where curved lines emanate outward. The positive charge is on the left and the negative charge is on the right. At the midpoint between the charges is a vertical line labelled 0 V.
  • Does the following equipotential surface show two similar or opposite charges?

    Equipotential lines between two charges where lines curve around each charge. The signs of the charges are not included. At the midpoint between the charges is an empty space.

    This is the equipotential surface for two similar charges. The region of empty space in the centre indicates where the resultant field is zero.

    Equipotential lines between two positive charges where lines curve around each charge. At the midpoint between the charges is an empty space.
  • How can an equipotential surface be used to determine the sign of a charge?

    Equipotential lines represent the potential gradient, so the sign of a charge can be identified by looking for

    • positive potentials which decrease with distance represent a positive charge

    • negative potentials which increase with distance represent a negative charge