The work function energy of sodium is 2.28 eV.
State what is meant by work function energy.
The electronvolt is a unit of energy.
Show that 2.28 eV is equivalent to 3.65 × 10–19 J.
State what is meant by the threshold frequency of a metal.
Determine the threshold frequency of sodium.
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A physics teacher gives her class an excerpt which summarises the theory of the photoelectric effect, as shown below.
Some of the information is missing.
The photoelectric effect is the release of .................. from a metal surface by ................... radiation (light) above a threshold ..................
Varying the .................. of the incident light varies the .................. kinetic energy of the photoelectrons.
Varying the .................. of the incident light varies the number of photoelectrons released per second.
She also provides a list of keywords for students to consider, as shown below:
Intensity |
Photoelectrons |
Frequency |
Maximum |
Electromagnetic |
Minimum |
Complete the missing information using keywords from the list provided.
You may use any keyword once, more than once, or not at all.
The physics teacher then asks her class to consider the equation for photoelectricity, which she writes as:
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Explain the meaning of each term in the photoelectric equation:
(i) hf
(ii) ϕ
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One of the students in the physics class recognises the form of the photoelectricity equation.
They say that it looks very similar to the equation of a straight line.
Sketch a graph of against f on the axes provided in Figure 2:
State the value of the gradient of the graph sketched in part (c).
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The graph in Figure 1 shows how the maximum kinetic energy of photoelectrons released from the surface of a metal varies with the frequency f of incident light.
Using Figure 1, explain, with reference to both frequency and energy, why no photoelectrons are emitted when the incident light is below a frequency of 4.4 × 1014 Hz.
State the property of the graph in Figure 1 which would be used to determine a value for Planck’s constant.
Use the graph in Figure 1 to determine a value for the maximum kinetic energy, in joules, of a photoelectron when the incident light is of frequency f = 8 × 1014 Hz.
State the experimental adjustment which could be made in order to reduce the maximum kinetic energy of released photoelectrons.
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Apparatus to investigate the photoelectric effect is set up as shown in Figure 1 below:
The incident electromagnetic radiation is above the threshold frequency of the metal photocathode.
State what happens at the metal photocathode when the electromagnetic radiation is incident on its surface.
As a result of the incident electromagnetic radiation, a photocurrent is detected in the ammeter in Figure 1.
State what happens to the reading on the ammeter when:
(i) The intensity of the incident electromagnetic radiation is increased but the frequency remains constant
(ii) The frequency of the incident electromagnetic radiation is increased but the intensity remains constant
The frequency of the incident radiation is 1.4 × 1018 Hz and the work function of the metal photocathode is 2.5 eV.
Calculate the maximum kinetic energy of the emitted photoelectrons.
Draw a circle around the sentence below which best describes where in the metal photocathode the photoelectron with the maximum kinetic energy originated from:
Near the metal surface |
Deep within the metal |
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The graph in Figure 1 shows how the maximum kinetic energy K of emitted photoelectrons from a metal surface varies with the frequency f of incident light.
Draw another line on the graph in Figure 1 that shows how K will vary with f for a different metal with a greater threshold frequency.
State which feature of the graph in Figure 1 is used to determine the work function of the metal.
The kinetic energy of emitted photoelectrons is often measured in electronvolts.
Define the electronvolt.
Calculate the energy transferred to a photoelectron by a photon of wavelength 400 nm.
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The photoelectric effect is represented by the equation
= Φ + 
Name the following terms and explain their significance in this equation:
Φ
A copper plate is illuminated with ultraviolet radiation of wavelength of 150 nm. The work function of copper is 5.0 eV.
Calculate the maximum kinetic energy of the liberated electrons in eV.
The radiation is maintained at the same frequency but the intensity is halved.
State and explain what changes, if any, occur to the number of electrons released per second and to the maximum kinetic energy of these electrons.
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Calculate the longest wavelength of electromagnetic radiation that will cause photoelectric emission at a clean sodium surface. Express your answer to an appropriate number of significant figures.
Work function of sodium Φ = 3.94 × 10–19 J.
Calculate the maximum kinetic energy of the electrons emitted when electromagnetic radiation of frequency 1.05 × 1015 Hz is incident on the surface in eV.
Explain why the kinetic energy of the emitted electrons from part (b) is a maximum value.
Explain, with reference to the work function, why electrons are not emitted if the frequency of the electromagnetic radiation is below a certain value.
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Figure 1 shows a photocell which uses the photoelectric effect to provide a current in an external circuit.
Ultraviolet radiation is incident on the photo-emissive surface. It has a wavelength of 150 nm and the current is 1.8 µA.
Give the value of the current when the intensity of the incident radiation is doubled. State and explain this effect on the current.
There is current only if the frequency of the electromagnetic radiation is above a certain value called the threshold frequency.
Explain, in terms of energy, why this threshold frequency exists.
The wavelength of the incident radiation is increased and at 280 nm the current falls to zero.
Calculate the threshold frequency and the work function Φ.
The student changes the material of the photoemissive surface to one with a work function of 1.7 eV.
The frequency of the electromagnetic radiation the student now uses is 6.4 × 1014 Hz.
Calculate the maximum kinetic energy, in J, of the electrons emitted from the photoemissive surface.
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State and explain which aspect of wave-particle duality is demonstrated by the photoelectric effect.
A particular photocell is designed to emit electrons when visible light is incident on its cathode. When orange light with wavelength 620 nm is incident on the cathode the electrons are emitted with almost zero kinetic energy.
Calculate the work function of the cathode material in eV.
Ultra-violet radiation of photon energy 4.2 × 10–19 J and of the same intensity as the visible light in part (b) is now incident on the cathode.
Calculate the maximum velocity of the emitted electrons.
State and explain the effect on the number of electrons emitted per second resulting from this change of UV radiation instead of visible light on the cathode.
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Photoelectrons are emitted from a metal surface when photons of a certain frequency hit the surface.
State two factors that increase the maximum kinetic energy of the emitted photoelectrons.
When monochromatic light is shone on a zinc surface, electrons with a range of energies up to a maximum of 5.72 × 10–20 J are released. The work function of zinc is 6.88 × 10–19 J.
Explain why the emitted electrons have a range of kinetic energies up to a maximum value.
Calculate the threshold frequency of the zinc surface. Give your answer to an appropriate number of significant figures.
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When electromagnetic radiation of frequency f is incident on a particular metal surface, photoelectrons are emitted.
Figure 1 shows how the maximum kinetic energy 
of these electrons varies with frequency f.
Figure 1
Sketch on Figure 1 the shape of the graph that would be obtained if the experiment is repeated using metal with a greater work function.
A certain metal with a work function of 2.2 eV is selected to create two parallel plates. These are connected in a circuit to a sensitive ammeter and a power source, such that a uniform electric field of 140 N C–1 exists between them. Figure 2 shows the two plates, labelled A and B, separated by 25 mm in a vacuum.
Electromagnetic radiation of wavelength 255 nm is incident on plate B, such that photoelectrons are emitted from B and move towards A. The ammeter detects a photocurrent in the circuit.
Figure 2
Deduce the direction of the electric field between the plates, given the photocurrent is at a maximum.
Show that the maximum possible speed of the photoelectrons as they reach plate A is approximately 1.5 × 106 m s–1.
Suggest and explain an experimental change to the setup as shown in Figure 2 that would reduce the photocurrent measured.
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The maximum kinetic energy, of photoelectrons varies with the wavelength of incident light on a metal surface. This is shown in Figure 1 below:
Figure 1
Use Figure 1 to show that the work function of the metal is 2.1 eV.
A student uses the shape of the curve in Figure 1 to state that maximum kinetic energy is inversely proportional to the incident wavelength.
By referring to the photoelectricity equation, discuss the validity of this statement.
Calculate the de Broglie wavelength of photoelectrons emitted from the metal surface for incident light of wavelength 500 nm.
Discuss the experimental changes that would reduce the minimum de Broglie wavelength of the emitted photoelectrons.
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Figure 1a shows the apparatus used in an experiment designed to investigate the photoelectric effect.
Light falls on to a photo-sensitive metal, and the kinetic energy of the fastest moving emitted electrons can be measured by increasing the voltage provided by the battery until the ammeter reading is zero.
Figure 1b shows the results obtained for monochromatic light of various frequencies.
Figure 1a
Figure 1b
Use Figure 1b to determine the work function of the photo-sensitive metal in electronvolts.
Calculate the speed of the fastest moving electron emitted by light of wavelength 500 nm
The photo-sensitive metal is removed from the apparatus and irradiated with photons of energy 4 eV. Loss of electrons causes the metal to acquire a positive potential.
Determine the potential at which no further loss of electrons from the surface occurs.
Explain how you arrive at your answer.
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