Particles and Waves Part 1

Question 1

Give an example of a piece of evidence that light behaves as a particle, not as a wave.

Answer 1

Photoelectric effect (radiation / photons incident on a metal surface removing excess electrons).

Question 2

What is meant by waves which are coherent?

Answer 2

Coherent means that waves have the same frequency, wavelength and velocity, and have a constant phase relationship.

The examples shown are both of coherent waves.

Question 3

What is the definition of the photoelectric effect?

Answer 3

The photoelectric effect occurs when electromagnetic radiation (in the form of photons) is incident on a metal surface and ejects electrons from the metal.

Question 4

In an experiment to demonstrate the photoelectric effect, a gold leaf electroscope is negatively charged, and an ultraviolet lamp is directed at a steel cap.

The electroscope does not discharge.

Suggest a change that could be made to the experiment which would cause the electroscope to discharge.

Answer 4

The metal cap of the electroscope could be changed to one with a lower work function than steel (for example, zinc).

Question 5

When light passes from a material into one with a lower refractive index (e.g. glass to air), what happens to its speed?

Answer 5

When light passes from a material into one with a lower refractive index (e.g. glass to air), its speed increases.

Question 6

When light passes from a material into one with a lower refractive index (e.g. glass to air), what happens to its frequency?

Answer 6

When light passes from a material into one with a lower refractive index (e.g. glass to air), its frequency remains constant.

Question 7

What does the symbol f₀ represent?

Answer 7

f₀ represents the threshold frequency - the minimum frequency of radiation required to eject an electron from the surface of a metal.

Question 8

Waves from two coherent sources meet at point P, perfectly in phase.

What name is given to point P?

Answer 8

Point P is the central maximum.

Question 9

What is the unit for energy?

Answer 9

The unit for energy is joules (J).

Question 10

What is the definition of threshold frequency?

Answer 10

Threshold frequency is the minimum frequency of radiation required to eject an electron from the surface of a metal.

Question 11

In an experiment to demonstrate the photoelectric effect, a gold leaf electroscope is negatively charged, and an ultraviolet lamp is directed at the metal. The electroscope discharges (the gold leaf slowly falls).

A UV lamp with the same frequency, but greater intensity, is now used.

What difference would be observed in the experiment?

Explain your answer.

Answer 11

The gold leaf (in the electroscope) would fall faster.

A UV lamp of greater intensity will emit more photons per second, meaning more electrons per second are ejected from the metal.

Question 12

Explain what is shown in this picture.

Answer 12

This is constructive interference.

Two waves meet at a point exactly in phase (peak meets peak, and trough meets trough) to form a wave of increased amplitude.

Question 13

Name the three quantities shown in this formula, and give the unit for each one.

Answer 13

I is irradiance (in W m^-2)

P is power (in W)

A is area (in m²)

Question 14

What characteristic of waves is shown in this diagram?

Answer 14

Diffraction

Question 15

Define all symbols in the formulae shown.

Answer 15

n = refractive index

ϴ = angle (in air or in a material)

λ = wavelength (in air or in a material)

v = speed of light (in air or in a material)

Question 16

In the diagram, a ray of light undergoes refraction as it enters a glass block.

How would the refractive index of the block be calculated?

Answer 16

The refractive index can be calculated by using the formula

Question 17

Waves from two coherent sources arrive at point P.

Point P is exactly the same distance from sources S₁ and S₂.

Explain what is happening at P.

Answer 17

Point P is a maximum.

Constructive interference is occurring at P because path difference = zero.

The waves are meeting at P in phase.

Question 18

In an experiment to demonstrate the photoelectric effect, a gold leaf electroscope is negatively charged, and a red laser is directed at the metal. The electroscope does not discharge.

When the experiment is repeated with a violet laser, the electroscope does discharge.

Explain why this happens.

Answer 18

Violet light has a shorter wavelength / higher frequency than red light.

The photons from the violet laser will have a greater energy than red.

The energy of the photons is given by E = hf.

Question 19

The diagram shows refraction of different colours (frequencies).

What conclusion can be drawn about the relationship between frequency and refractive index?

Answer 19

Violet light has a higher frequency than red.

Violet light is refracted by a greater angle than red.

The higher the frequency, the greater the refractive index.

Question 20

When light passes from air (or a vacuum) into a material of a greater refractive index, what happens to its speed?

Answer 20

When light passes from air (or a vacuum) into a material of a greater refractive index, its speed decreases.

Question 21

Give an example of a piece of evidence that light behaves as a particle.

Answer 21

The photoelectric effect is evidence that light behaves as a particle.

Question 22

What is the unit of irradiance?

Answer 22

The unit of irradiance is

watts per metres squared (W m^-2).

Question 23

What is the unit of frequency?

Answer 23

The unit of frequency is hertz (Hz).

For example:

5 Hz = 5 waves per second.

Question 24

A ray of white light is refracted by a prism.

Describe the pattern produced.

Answer 24

A spectrum would be produced.

Red is refracted the least, violet refracted the most.

Question 25

List the different characteristics (or behaviours) that all waves display (four possible answers)

Answer 25

* diffraction * reflection * refraction * interference

Question 26

When does **total internal reflection** to occur?

Answer 26

**Total internal reflection** occurs when the angle of incidence is **greater than the critical angle**.

Question 27

When light passes from a material into one with a **lower refractive index** (e.g. glass to air), what happens to its **wavelength**?

Answer 27

When light passes from a material into one with a **lower refractive index** (e.g. glass to air), its **wavelength increases**.

Question 28

What is the unit for **refractive index** (**n**)?

Answer 28

There are **no units** for refractive index. It will just be a number >1.

Question 29

What is the definition of **work function**?

Answer 29

Work function is the **minimum energy** of a **photon** required to **eject** an **electron** from the surface of a **metal**.

Question 30

What is the definition of **critical angle**?

Answer 30

**Critical angle** is the angle of incidence that results in an angle of refraction of 90° to the normal.

Question 31

A ray of light, inside a block of glass, hits the surface of the glass. The angle is **greater** than the **critical angle**. What will happen to the ray of light?

Answer 31

The ray of light will be **totally internally reflected**.

Question 32

Waves from two coherent sources arrive at point P₁. The distance from S₁ to P₁ is one whole wavelength less than the distance from S₂ to P₁. Explain what is happening at P₁.

Answer 32

Point P₁ is a **maximum**. **Constructive interference** is occurring at P₁ because **path difference = λ**. The waves from S₁ and S₂ **meet in phase**.

Question 33

What characteristic of waves is shown in this diagram?

Answer 33

**Interference**

Question 34

A ray of white light is incident on a diffraction grating. Describe the pattern that would be produced.

Answer 34

There are several maxima observed. There is a **white central maximum**. There are **spectra** either side of the central maximum. In each spectrum, **violet** is **diffracted** the **least**, **red** is **diffracted** the **most**.

Question 35

Give an example of a piece of **evidence** that **light behaves as a wave.**

Answer 35

**Interference patterns** are evidence that **light behaves as a wave**. ## Footnote (Also: diffraction, refraction, reflection of light)

Question 36

The relationship between **irradiance** and **distance** is an example of an **inverse square law**. What is meant by an 'inverse square law' - in this context?

Answer 36

An **inverse square law**, in this context, means that if the distance is multiplied by 2, the irradiance is divided by 4 (2 squared). If the distance is multiplied by 10, the irradiance is divided by 100 (10 squared) - and so on.

Question 37

What is the definition of *absolute refractive index* of a medium (or material)?

Answer 37

*Absolute refractive index* is the **ratio** of **speed of light in a vacuum** to **speed of light in the medium**.

Question 38

Explain, **in terms of waves**, what is shown in this picture.

Answer 38

This is **destructive interference**. Two waves meet at a point exactly out-of-phase (crest meets trough, and trough meets crest) to form a wave of reduced amplitude. (if both waves are the same amplitude then the new amplitude will be zero)

Question 39

What is the unit for **wavelength**?

Answer 39

The unit for wavelength is **metres** (**m**).

Question 40

When light passes from air (or a vacuum) into a material of a **greater refractive index**, what happens to its **wavelength**?

Answer 40

When light passes from air (or a vacuum) into a material of a greater refractive index, its **wavelength decreases**.

Question 41

What is the unit for **frequency**?

Answer 41

The unit for frequency is **hertz** (**Hz**).

Question 42

What is the definition of **irradiance**?

Answer 42

**Irradiance** of light (or any e.m. radiation) is the power per unit area incident on a surface. | (power per square metre)

Question 43

When light passes from air (or a vacuum) into a material of a **greater refractive index**, what happens to its **frequency**?

Answer 43

When light passes from air (or a vacuum) into a material of a greater refractive index, its **frequency remains constant**.

Question 44

What characteristic of waves is shown in this diagram?

Answer 44

**Reflection**

Question 45

What characteristic of waves is shown in this diagram?

Answer 45

**Refraction**