P3- Medical applications of physics

Question 1

How are X-rays used?

Answer 1

• Broken/fractured bones.
• Security.
• Telescopes.
• Destroy tumours at or near the body surface.

Question 2

What are X-rays?

Answer 2

• Part of electromagnetic spectrum.
• High frequency and very short wavelength.

Question 3

How are X-rays produced?

Answer 3

By fast moving electrons, which smash into a metal plate causing x-rays to be emitted.

Question 4

How are low intensity X-rays dangerous?

Answer 4

They can damage cells and cause cancer (ionsiation).

Question 5

How are high-intensity X-rays dangerous?

Answer 5

They kill cells straight away.

Question 6

Name 3 properties of X-rays.

Answer 6

• They affect a photographic film in the same way as light.
• They are absorbed by metal and bone.
• They are transmitted by healthy tissue.

Question 7

Why do bones look like this in X-rays?

Answer 7

Denser objects such as bones absorb more x-rays than soft tissue so show up more on x-ray images.

Question 8

What precautions do workers using X-rays take?

Answer 8

• Wearing film badges which monitor exposure.
• Use lead screens or stand in lead rooms to shield themselves from X-rays.
• Wearing lead aprons.

Question 9

What is a CT scan?

Answer 9

A ‘computed tomography’ scan is an advanced technique that uses X-rays and CCDs.

X-rays are fired through the patient and a series of images, like slices, are produced which are processed by a computer to give a 3D image.

Question 10

What are CCDs?

Answer 10

Charge-coupled devices can be used to form electronic images of X-rays.

Question 11

How can body organs made of soft tissues be seen on an X-ray image?

Answer 11

Some body organs such as the intestines can be filled with a contrast medium that absorbs X-rays so they can be seen on an X-ray image.

Question 12

What are ultrasound waves?

Answer 12

Ultrasound waves are sound waves above the frequency of 20,000 Hz (higher than the human ear can detect).

Question 13

How can ultrasound waves be used to produce an image?

Answer 13

The waves travel back through the material to a detector. The time it takes to reach the detector can be used to calculate how far away the boundary is. The results can be processed by a computer to give an image.

Question 14

When ultrasound passes through the body, some of it is reflected back. Why?

Answer 14

Because of the change in density as it passes from one medium to another.

Question 15

What is sound?

Answer 15

Sound is vibrations, compressions and decompressions of air that the human ear can detect.

Question 16

What is the speed of sound in air?

Answer 16

340m/s.

Question 17

Name 5 uses of ultrasound.

Answer 17

• Scanning unborn babies.
• Navigation underwater (SONAR).
• Finding and breaking kidney stones.
• Used by animals for navigation & communication.
• Purification of water.

Question 18

How can the distance travelled by an ultrasound pulse be calculated?

Answer 18

s = v x t

s= Distance travelled (m).

v= Speed of ultrasound (m/s).

t= Time (s).

*Remember: In the time between the transmitter sending out a pulse of ultrasound and it returning to the detector it has travelled twice the distance to the boundary.*

Question 19

How can the depth of boundary below the surface be calculated?

Answer 19

1/2 x distance travelled.

Question 20

Identify the disadvantages and advantages of using X-rays.

Answer 20

✅Fast- images available the same day or within the hour.

✅Painless & non-invasive.

✅Doesn’t require any special preparation.

✅Requires no recovery time.

❌Slower than ultrasound.

❌Not recommended for pregnant women.

❌Exposure to radiation= increased risk of developing cancer.

Question 21

Identify the disadvantages and advantages of using ultrasound.

Answer 21

✅Non-invasive.

✅Accurate.

✅Considered risk-free as it doesn’t damage cells.

✅’Real-time’ video therefore image available immediately.

❌Images from deeper into body have progressively poorer resolution.

❌Relies on expertise of sonographer.

❌After 18 weeks pregnancy, scans are unlikely to show anything but major problems.

Question 22

How does light refract from a less denser to a denser material?

Answer 22

Light slows down and bend towards the normal.

Question 23

How does light refract from a denser material to a less dense material?

Answer 23

Lights speeds up and bends away from the normal.

Question 24

What is refractive index?

Answer 24

Refractive index (n) is a measure of how much a substance can refract a light ray.

A measure of the speed of light through a material compared to the speed of light in a vacuum.

Question 25

How can refractive index be calculated?

Answer 25

n= sini/sinr

n= refractive index.

sini= sine of the angle of incidence.

sinr= sine of the angle of refraction.

Question 26

Why doesn’t refractive index have a unit?

Answer 26

Because it is a ratio.

Question 27

Total internal reflection only occurs when…

Answer 27

1. The angle of the light is above the critical angle.
2. The light is travelling from a more dense to a less dense material.

Question 28

When does total internal reflection occur?

Answer 28

When the angle of incidence is increased beyond the critical angle.

Question 29

What is the critical angle?

Answer 29

The critical angle is when the angle of incidence emerges along the boundary between the two materials.

Question 30

How is light refracted when the angle of incidence is below the critical angle?

Answer 30

Light refracts, a little is reflected.

Question 31

How is light refracted when the angle is above the critical angle?

Answer 31

Total internal reflection.

Question 32

What is the relationship between refractive index and critical angle?

Answer 32

The higher the refractive index, the lower the critical angle.

Question 33

How can refractive index also be calculated?

Answer 33

n= 1/sinc

n= refractive index.

sinc= sine of the critical angle.

Question 34

What is an optical fibre?

Answer 34

An optical fibre is a thin, flexible rod of high-quality glass. Light getting in at one end undergoes repeated total internal reflection and emerges at the other end.

Question 35

How can optical fibres be used?

Answer 35

• In endoscopes, which contain bundles of optical fibres➡️Endoscopes allow surgeons to look inside a patient’s body without cutting it open or whilst performing keyhole surgery.
• Optical fibres can carry enourmous amounts of information as pulses of light.

Question 36

What is a laser?

Answer 36

A laser produces an intense narrow beam of light because it has low divergence meaning it spreads out very little.

Question 37

How can lasers be used?

Answer 37

• Cutting through materials.
• Burning (e.g: laser engraving).
• Cauterising (to destroy damaged tissue or stop bleeding).
• Eye surgery on retina.

Question 38

What shape is a converging lens and how does this refract rays?

Answer 38

A converging lens is always convex. Converging lenses make the rays that are coming in parallel converge to a point.

Question 39

What shape is a diverging lens and how does this refract rays?

Answer 39

A diverging lens is always concave. Diverging lenses make parallel rays coming in diverge away from a point.

Question 40

What symbol may be used in a ray diagram to represent a converging lens?

Answer 40

Question 41

What symbol may be used in a ray diagram to represent a diverging lens?

Answer 41

Question 42

What type of image is formed by a converging lens when the object is beyond 2F?

Answer 42

• Real.
• Inverted.
• Diminished.
• Between F and 2F.

Question 43

What type of image is formed by a converging lens when the object is on 2F?

Answer 43

• Real.
• Inverted.
• Same size as object.
• On 2F.

Question 44

What type of image is formed by a converging lens when the object is between 2F and F?

Answer 44

• Real.
• Inverted.
• Magnified.
• Further than 2F.

Question 45

What type of image is formed by a converging lens when the object is on F?

Answer 45

No image formed.

Question 46

What type of image is formed by a converging lens when the object is infront of F?

Answer 46

• Upright.
• Virtual.
• Magnified.
• Same side as object.

Question 47

What type of image is always formed by a diverging lens?

Answer 47

• Virtual.
• Upright.
• Diminished.
• Closer to lens than object.

Question 48

How can magnification be calculated?

Answer 48

Magnification= Image height/Object height.

Question 49

What is the principal axis in a ray diagram?

Answer 49

The line through the centre of the lens and at right angles to it.

Question 50

How do you draw a ray diagram for a converging lens?

Answer 50

A) A ray parallel to principal axis is refracted through the principal focus.

B) A ray through the centre of the lens travels straight on without refraction.

C) A ray through the principal focus is refracted parallel to the principal axis.

Question 51

What is the principal focus/focal point?

Answer 51

The point at which parallel lines are converged to by a converging lens.

Question 52

What is a magnifying glass?

Answer 52

A converging lens that is used to form a virtual image of an object.

Question 53

Is the image formed in a camera real or virtual?

Answer 53

Real.

Question 54

What is the function of:

The cornea?

The iris?

The pupil?

The lens?

Answer 54

• Cornea➡️Protects eye and helps to focus light onto retina.
• Iris➡️Controls how much light enters the pupil by relaxing or contracting.
• Pupil➡️Allows light to pass through as it enters the eye.
• Lens➡️Refracts light to focus it onto the retina.

Question 55

What is the function of:

The ciliary muscles?

The suspensory ligaments?

The retina?

Answer 55

• Ciliary muscles➡️Changes thickness of lens.
• Suspensory ligaments➡️Slacken or stretch as the ciliary muscles contract or relax to adjust the thickness and curvature of the lens.
• Retina➡️Contains light receptors which trigger electrical impulses to be sent to the brain when light is detected.

Question 56

What is label 1-6?

Answer 56

1- Cornea.

2- Pupil.

3- Iris.

4- Lens.

5- Retina.

6- Ciliary muscle.

Question 57

What is the near point and far point of the human eye?

Answer 57

Near point= 25cm.

Far point= Infinity.

Question 58

What does long-sightedness mean?

Answer 58

Someone with long sight can see distant objects clearly but their near point is further away than 25cm, so they cannot focus properly on objects.

Question 59

What does short-sightedness mean?

Answer 59

Someone with short sight can see near objects clearly but their far point is closer than infinity, so they cannot focus properly on distant objects.

Question 60

How is the power of a lens calculated?

Answer 60

P= 1/f

P= power of lens in dioptres (D).

f= focal length in metres (m).

Question 61

How is long sight caused?

Answer 61

1) The eyeball (distance between lens and retina) is too short.
2) Loss of elasticity in the lens so it cannot become fat enough to focus.

Question 62

How is short sight caused?

Answer 62

1) The eyeball (distance between lens and retina) is elongated.
2) The lens is too thick and curved, so light is focused in front of the retina.

Question 63

What lense is needed to fix long-sightedness?

Answer 63

Converging lens.

Question 64

What lense is needed to fix short-sightedness?

Answer 64

Diverging lens.

Question 65

What does it means if the power of the lens is:

Positive?

Negative?

Answer 65

Positive➡️Converging lens.

Negative➡️Diverging lens.

Question 66

What does a higher refractive index mean for manufacturing?

Answer 66

A flatter, thinner lens can be manufactured.

Question 67

For the eye, give the:

1. Type of lens.
2. Focusing adjustment.
3. Image.
4. Image Detection.
5. Brightness Control.

Answer 67

1. Variable focus, converging lens.
2. Ciliary muscles alter lens thickness.
3. Real, inverted, magnification less than 1.
4. Light sensitive cells on retina.
5. Iris controls the width of the pupil.

Question 68

For a camera, give the:

1. Type of lens.
2. Focusing adjustment.
3. Image.
4. Image Detection.
5. Brightness control.

Answer 68

1. Fixed focus, converging lens.
2. Adjustment of lens position.
3. Real, inverted, magnification less than 1.
4. Photographic film (or CCD) sensors.
5. Adjustment of aperture ‘stop’.

Question 69

How do you draw a ray diagram for a diverging lens?

Answer 69

1) Draw a ray passing parallel to the principal axis and being refracted away from the principal axis.
2) Draw a ray directed at the principal focus behind the lens, but being refracted by the lens so that it runs parallel to the principal focus after leaving the lens.
3) Draw a ray passing in a straight line through the centre of lens without being refracted.