Light

Question 1

What types of waves can be reflected or refracted?

Answer 1

All waves, whether longitudinal or transverse

Question 2

When does reflection occur?

Answer 2

Reflection occurs when:
A wave hits a boundary between two media and does not pass through, but instead stays in the original medium.

Question 3

When does refraction occur?

Answer 3

Refraction occurs when:
A wave passes a boundary between two different transparent media and undergoes a change in direction of waves at a boundary.

Question 4

Where are angles measures on a ray diagram for reflection or refraction?

Answer 4

Angles are measured between the wave direction (ray) and a line at 90 degrees to the boundary.

Question 5

What is the angle of the wave approaching the boundary called?

Answer 5

The angle of the wave approaching the boundary is called the angle of incidence (i)

Question 6

What is the angle of the wave leaving the boundary called? (in reflection)

Answer 6

The angle of the wave leaving the boundary is called the angle of reflection (r).

Question 7

What is the law of reflection?

Answer 7

Angle of incidence (i) = Angle of reflection (r)

Question 8

What is used to show the direction the wave is travelling?

Answer 8

When drawing a ray diagram an arrow is used to show the direction the wave is travelling.

Question 9

What is the arrow on a ray used for on a ray diagram?

Answer 9

When drawing a ray diagram an arrow is used to show the direction the wave is travelling.

Question 10

Describe the incident ray

Answer 10

An incident ray is the ray approaching the boundary and has an arrow pointing towards the boundary

Question 11

Describe a reflected ray

Answer 11

An reflected ray is the ray leaving the boundary and has an arrow pointing away from the boundary

Question 12

What is the angle of incidence labelled as?

Answer 12

The angles of incidence is usually labelled i

Question 13

What is the angle of reflection usually labelled as?

Answer 13

The angles of reflection is usually labelled r

Question 14

Where are the angles of incidence and reflection measured from?

Answer 14

The angles are measured from the normal

Question 15

What happens when the ray of light hits the boundary between two different medias on refraction ray diagrams?

Answer 15

At the boundary, the rays of light undergo a change in direction.

Question 16

When the rays of light on refraction ray diagram change directions due to light passing through different, what does the direction depend on?

Answer 16

The direction is taken as the angle from a hypothetical line called the normal.

Question 17

Describe the normal

Answer 17

It is a perpendicular line to the surface of the boundaries and is usually represented by a straight dashed or dotted line

Question 18

What does the change in direction of the ray in refraction depend on?

Answer 18

The change in direction depends on the difference in density between the two media; From less dense to more dense (e.g air to glass), light bends towards the normal
From more dense to less dense (e.g. glass to air), light bends away from the normal
However, When passing along the normal (perpendicular) the light does not bend at all

Question 19

What happens when the light travels from a less dense medium to more dense medium?

Answer 19

From less dense to more dense (e.g air to glass), the rays will slow down and light bends towards the normal and so r < I.

Question 20

What happens when the light travels from a more dense medium to less dense medium?

Answer 20

From more dense to less dense (e.g. glass to air), the rays will speed up and light bends away from the normal and so r > i .

Question 21

When happens to the light
passing along the normal in refraction (perpendicular)?

Answer 21

When passing along the normal (perpendicular) the light does not bend at all.

Question 22

What are the only properties that change during refraction, and what does not change?

Answer 22

The only properties that change during refraction are speed and wavelength – the frequency of waves does not change.

Question 23

What do different frequencies account for and give an example?

Answer 23

Different frequencies account for different colours of light (red has a low frequency, whilst blue has a high frequency)

Question 24

What happens to colours when light refracted?

Answer 24

When light refracts, it does not change colour (think of a pencil in a glass of water), therefore, the frequency does not change.

Question 25

What is a virtual image and how can it be represented on a diagram?

Answer 25

A virtual image is an image that cannot be formed on a screen and can be represented as the rays do not meet at the image.

Question 26

Explain what happens to the wavelength of light when it passes from air into water. (Not light ray)

Answer 26

The wavelength decreases;
because wave speed decreases and frequency remains constant.

Question 27

What is refraction?

Answer 27

A change in direction of waves at a boundary.

Question 28

If light light speeds up on entering a new medium, what does this inform us about the new medium it enters.

Answer 28

If light speeds up on entering a new medium, then the medium is “less optically dense”

Question 29

If light slows up on entering a new medium, what does this inform us about the new medium it enters?

Answer 29

If light slows down as it enters a new medium, the new medium is “more optically dense”.

Question 30

What happens to light entering a material with higher optical density?

Answer 30

It slows down and turns towards the normal.

Question 31

What happens to the wavelength of waves when they are reflected?

Answer 31

It does not change

Question 32

What is white light?

Answer 32

White light is combination of all colours

Question 33

What is black light?

Answer 33

Black light is the absence of light

Question 34

What is the aim of the practical for investigating refraction?

Answer 34

To investigate the refraction of light using rectangular blocks, semi-circular blocks and triangular prisms.

Question 35

What is the independent variable for the practical investigating refraction?

Answer 35

Shape of the block

Question 36

What is the dependent variable for the practical investigating refraction?

Answer 36

Direction of refraction

Question 37

What are the control variables for the practical investigating refraction?

Answer 37

Control variables:
Width of the light beam
Same frequency / wavelength of the light

Question 38

What are the equipment in the experiment for the practical investigating refraction?

Answer 38

Ray box, protractor, sheet of paper, pencil, ruler, Perspex blocks (rectangular block, semi-circular block & prism)

Question 39

What is the purpose of the ray box for the practical investigating refraction?

Answer 39

To provide a narrow beam of light to reflect in the mirror.

Question 40

What is the purpose of the protractor for the practical investigating refraction?

Answer 40

To measure the light beam angles.

Question 41

What is the purpose of the sheet of paper in the practical investigating refraction?

Answer 41

To mark with lines for angle measurement.

Question 42

What is the purpose of a pencil in the practical investigating refraction?

Answer 42

To mark perpendicular line and angle line on paper.

Question 43

What is the purpose of the ruler in the practical investigating refraction?

Answer 43

To draw lines on paper.

Question 44

What is the purpose of the Perspex blocks in the practical investigating refraction?

Answer 44

To refract the light beam.

Question 45

Describe the method to carry out an experiment to investigate refraction.

Answer 45

1. Place the glass block on a sheet of paper, and carefully draw around the rectangular perspex block using a pencil
2. Switch on the ray box and direct a beam of light at the side face of the block
3. Mark on the paper:
   - A point on the ray close to the ray box
   - The point where the ray enters the block
   The point where the ray exits the block
   - A point on the exit light ray which is a distance of about 5 cm away from the block
4. Draw a dashed line normal (at right angles) to the outline of the block where the points are
5. Remove the block and join the points marked with three straight lines
6. Replace the block within its outline and repeat the above process for a ray striking the block at a different angle
7. Repeat the procedure for each shape of perspex block (prism and semi-circular)

Question 46

Describe what happens when the light rays enter the Perspex block.

Answer 46

For light rays entering the perspex block, the light ray refracts towards the central line and so i > r (angle of incidence is greater than angle of reflection).

Question 47

Describe what happens when the light rays exit the Perspex block.

Answer 47

For light rays exiting the perspex block, the light ray refracts away from the central line and so i < r (angle of refractions is greater than angle of incidence).

Question 48

Systematic Error in the practical investigating refraction & Snell’s Law and what is the solution.

Answer 48

An error could occur if the 90° lines are drawn incorrectly

Solution: use a set square to draw perpendicular lines

Question 49

Random Errors in the practical investigating refraction & Snell’s Law and what are the solutions.

Answer 49

The points for the incoming and reflected beam may be inaccurately marked
Solution: use a sharpened pencil and mark in the middle of the beam
The protractor resolution may make it difficult to read the angles accurately
Solution: Use a protractor with a higher resolution

Question 50

Safety considerations in the practical investigating refraction & Snell’s Law and how to protect ourselves?

Answer 50

The ray box light could cause burns if touched
Solution: Run burns under cold running water for at least five minute
Looking directly into the light may damage the eyes
Solution: Avoid looking directly at the light
Solution: Stand behind the ray box during the experiment
Keep all liquids away from the electrical equipment and paper

Question 51

What is Snell’s Law?

Answer 51

n = sin i/sin r

Question 52

What is n in the Snell’s Law equation?

Answer 52

n = the refractive index of the material

Question 53

What is i in the Snell’s Law equation?

Answer 53

i = angle of incidence of the light (°)

Question 54

What is r in the Snell’s Law equation?

Answer 54

r = angle of refraction of the light (°)

Question 55

What is sin in the Snell’s Law equation?

Answer 55

‘Sin’ is the trigonometric function ‘sine’ which is on a scientific calculator.

Question 56

What is the number range for the refractive index of a material?

Answer 56

Greater than one, but less than 4

Question 57

If an object is more optically dense, what does that inform us regarding its refractive index?

Answer 57

Objects which are more optically dense have a higher refractive index.

Question 58

If an object is less optically dense, what does that inform us regarding its refractive index?

Answer 58

Objects which are less optically dense have a lower refractive index.

Question 59

What is the aim of the practical: investigating Snell’s Law?

Answer 59

To investigate the refractive index of glass, using a glass block.

Question 60

What is the independent variable in the practical: Investigating Snell’s Law?

Answer 60

Angle of incidence, i

Question 61

What is the dependent variable in the practical: Investigating Snell’s Law?

Answer 61

Angle of refraction, r

Question 62

What is the control variables in the practical: Investigating Snell’s Law?

Answer 62

Use of the same perspex block
Width of the light beam
Same frequency / wavelength of the light

Question 63

What are equipment utilised in the practical: investigating Snell’s Law?

Answer 63

Ray box, protractor, sheet of paper, pencil, ruler and Perspex rectangular block.

Question 64

What is the purpose of the ray box in the practical: Investigating Snell’s Law?

Answer 64

To provide a narrow beam of light to reflect in the mirror.

Question 65

What is the purpose of the protractor in the practical: Investigating Snell’s Law?

Answer 65

To measure the Light beam angles.

Question 66

What is the purpose of the sheet of paper in the practical: Investigating Snell’s Law?

Answer 66

To mark with lines for angle measurement.

Question 67

What is the purpose of a pencil in the practical: Investigating Snell’s Law?

Answer 67

To mark perpendicular Line and angle Lines on paper.

Question 68

What is the purpose of the ruler in the practical: Investigating Snell’s Law?

Answer 68

To draw lines on paper

Question 69

What is the purpose of the Perspex rectangular block in the practical: Investigating Snell’s Law?

Answer 69

To refract the light beam.

Question 70

Describe a method to investigate Snell’s Law

Answer 70

I. Place the glass block on a sheet of paper, and carefully draw around the block using a pencil
2. Draw a dashed line normal (at right angles) to the outline of the block
3. Use a protractor to measure the angles of incidence to be studied and mark these lines on the paper
4. Switch on the ray box and direct a beam of light at the side face of the block at the first angle to be investigated
5. Mark on the paper:
• A point on the ray close to the ray box
• The point where the ray enters the block
• The point where the ray exits the block
• Apoint on the exit light ray which is a distance of about 5 cm
away from the block
6. Remove the block and join the points marked with three straight lines
7. Replace the block within its outline and repeat the above process for a rays striking the block at the next angle
8. Record your results on a table of results

Question 71

What can happen sometimes when light is moving from a denser medium towards a less dense one and does not get refracted?

Answer 71

When this happen, the all light is reflected. This is known as total internal reflection.

Question 72

When does total internal reflection occur?

Answer 72

It occurs when the angle of incidence is greater than the critical angle and the incident material is denser than the second material.

Question 73

What the two conditions for total internal reflection?

Answer 73

The angle of incidence is greater than the critical angle and the incident material is denser than the second material.

Question 74

What can total internal reflection be utilised in?

Answer 74

Total internal reflection is utilised in:
Optical fibres eg. endoscopes or communication
Prisms eg. periscopes

Question 75

What happens when the angle of refraction is exactly 90°?

Answer 75

When the angle of refraction is exactly 90°, the light is refracted along the boundary.

Question 76

Give examples of when total internal reflection is used to reflect light along optical fibres.

Answer 76

Communications
Endoscopes
Decorative lamps
Safety reflectors on bicycles, cars and roads
In medicine; to see within the human body

Question 77

How is light travelling down an optical fibre totally internally reflected?

Answer 77

Light travelling down an optical fibre is totally internally reflected each time it hits the edge of the fibre.

Question 78

How are optical fibers used in medicine?

Answer 78

Endoscopes use optical fibres to produce an image of inside the body. A doctor can insert a bundle of optical fibres into the body. This allows the doctor to see an image of the inside of the body clearly, and help them diagnose diseases.

Question 79

Give examples of how can prisms be used in optical instruments.

Answer 79

Prisms are used in a variety of optical instruments, including:
Periscopes
Binoculars
Telescopes
Cameras

Question 80

What is a periscope?

Answer 80

A periscope is a device that can be used to see over tall objects and consists of two right-angled prisms

Question 81

How can a periscope be used to see over tall objects?

Answer 81

Periscopes consist of two right-angled prisms and light is totally internally reflected in both these prisms.

Question 82

What happens the angle of incidence is increased?

Answer 82

As the angle of incidence is increased, the angle of refraction also increases until it gets closer to 90° and when the angle of refraction is exactly 90° the light is refracted along the boundary

Question 83

What is the equation to calculate critical angle?

Answer 83

sin c = 1/n

Question 84

What is the equation for calculating the refractive index using the critical angle?

Answer 84

n = 1/sin c

Question 85

How are the refractive index and critical angle related?

Answer 85

The larger the refractive index of a material, the smaller the critical angle.

Question 86

Light rays inside a material with a high refractive index are more likely to be…

Answer 86

Light rays inside a material with a high refractive index are more likely to be totally internally reflected