Radioactivity

Question 1

Explain what is meant by background radiation?

Answer 1

Background radiation is radiation produced by radioactive material in the Earth and in the Earth’s atmosphere. It should be measured and taken into account when measuring the activity of radiation from a particular source.

Question 2

Explain the difference between natural background radiation and artificial radiation?

Answer 2

Natural background radiation is due to the decay of naturally occurring radioactive isotopes in the Earth that were formed when the Solar System was created. Natural radiation also results from high-energy particles that bombard the Earth. Artificial background radiation comes from
man-made sources, rather than from the rocks that make up the Earth.

Question 3

Give three examples of sources of BR?

Answer 3

Uranium in rocks in the Earth’s crust (natural). Radioactive materials that have escaped into the environment from nuclear power stations (artificial). Fallout from atmospheric nuclear weapon
testing in the 1950s and 1960s (artificial).

Question 4

Explain simply, the principle of the GM tube?

Answer 4

Ionising radiation causes ionisation of a low-pressure gas inside the tube. The ionised gas allows a current to flow between two electrodes, and the current is detected by an electronic circuit.

Question 5

What does a rate meter measure in a GM tube?

Answer 5

A rate meter gives an indication of the number of decays occurring per second.

Question 6

Rate meter is calibrated at kBq. How is this unit defined?

Answer 6

A bequerel is a rate of decay of one disintegration per second. 1 kBq is 1000 disintegrations per
second.

Question 7

Define what is meant by the half life of a radioactive material?

Answer 7

The half-life of a radioactive sample is the average time taken for half the unstable atoms in the sample to undergo radioactive decay.

Question 8

Radioactive decay is a random process. Explain this?

Answer 8

Random means that the decay of an individual atom is unpredictable; we cannot say when any particular atom will undergo decay.

Question 9

A student wants to measure the half life of a radioactive isotope. He is told that is has a half life of between 10 and 20 minutes.

What measurements should he take?

How should he use the measurements to find the half life?

Answer 9

Students should measure the background radiation. They should then measure the radioactivity of the sample using a GM tube and rate meter at regular intervals of, say, 5 minutes for a period
of 30–40 minutes.

The readings of the activity of the sample should be corrected by subtracting the average background radiation count. The corrected readings should then be plotted on a graph of count rate against time. The time taken for the
initial activity to fall to half can then be measured from the graph.

Question 10

Explain why a particles half life of 6 hours and decay by emission of low energy gamma and beta particles is good in medicine?

Answer 10

It has a short half-life, so its activity drops to a negligible level in a day or two. Beta particles and low energy gamma rays penetrate soft tissue easily, so the progress of the isotope through the body can be monitored easily. The emitted radiation is not strongly ionising, so the risk of
tissue damage is acceptably small. (It is also relatively easy to produce.)

Question 11

How can an isotopes’ progress in the body be monitored?

Answer 11

By using a detector such as a GM tube.

Question 12

What can cause an isotope to decay to another isotope of a different element with the same mass no?

Answer 12

Beta decay. The process involves a change in element but with a negligible change in mass.

Question 13

How can iodine isotope be used to identify an over-active thyroid gland?

Answer 13

Iodine-131 is taken up by the thyroid gland in the same way as ordinary iodine. An overactive thyroid concentrates more iodine – if the concentration of I-131 is greater than normal, this can be detected by measuring the activity and comparing it with the expected take-up from a normal thyroid gland.

Question 14

How can iodine isotope help to treat an over-active thyroid?

Answer 14

I-31 is a high-energy beta-emitter. The radiation is sufficiently ionising to destroy cells in the thyroid, reducing its activity.

Question 15

Explain the advantages of ionising radiation for sterilizing surgical equipment

Answer 15

Surgical instruments may be sealed into wrappers and then sterilised using radiation. The radiation passes through the wrapper, destroying any organisms on the instrument, which then remains sterile within its wrapper.

Question 16

How can you use ionizing radiation to check the thickness of paper during production?

type of radiation

how it will be used to measure paper thickness

what checks should be made to make sure measurements are accurate

safety procedures

Answer 16

Beta radiation is used. It can pass through paper (unlike alpha particles) but the thicker the paper, the greater the amount of beta radiation absorbed.

A beta-emitting source is placed above the paper as it emerges from the rollers used to press it to
the required thickness and a detector is placed beneath the paper in line with the source. The count rate will decrease as the thickness of the paper passing between the emitter and the
detector increases.

To ensure accuracy, the background radiation count should be taken regularly so that the reading from the detector can be corrected. The half-life of the beta-emitting source needs to be quite long (so that the count rate does not fall significantly over short intervals), but the apparatus will need to be recalibrated regularly using paper of known thickness.

Care should be taken to ensure workers cannot come within range of the radiation from the source. The source must be stored in a secure container that is lined with lead to ensure no ionising radiation can escape. The storage area and the part of the paper-making works in which
the radiation source is being used should be clearly identified with standard signs. The source must be selected and screened to ensure that it emits only beta radiation.

Question 17

How is C-14 made?

Answer 17

Cosmic radiation causes C-14 to form from nitrogen in the atmosphere.

Question 18

Why does all living matter contain C-14?

Answer 18

Carbon-14 has the same chemical behaviour as the abundant stable isotope C-12. Carbon reacts
with oxygen to form carbon dioxide. Through photosynthesis, carbon-14 enters the food chain
and therefore all living material.

Question 19

What happens to the proportion of C-14 in an organism when it dies?

Answer 19

Once an organism is dead, no new C-14 is taken in via photosynthesis (plants) or food
(animals). The proportion of C-14 in organic material decreases as the C-14 decays.

Question 20

What assumptions are made in radiocarbon dating?

Answer 20

The principal assumption is that the rate of production of C-14 through cosmic rays has remained constant over time. In practice this is not so, but it is possible to make adjustments for the variation in C-14 by taking samples from objects of known age.

Question 21

Why is carbon dating not suitable when measuring material older than 50,000 years?

Answer 21

The half-life of C-14 is roughly 5600 years. After 10 half-lives have elapsed, the activity remaining C-14 is too small for accurate measurement.

Question 22

An isotope that decays by alpha emission is relatively safe when outside the body by dangerous if absorbed.

Why?

Answer 22

Alpha radiation has a very limited range. After alpha particles have travelled only a few centimetres in air, they have lost most of their kinetic energy and thus lose their ionising power. Alpha particles are stopped completely by quite thin layers of material that are not very dense.
Thus alpha radiation is not particularly dangerous to living cells, as in the human body, unless the source is very close to living tissue. If a source is very close to the skin it may, if the exposure is prolonged, cause burns and other tissue damage.

The greatest danger is when alpha emitting material is absorbed into the body. Inside the body, cells do not even have the protection of a layer of skin and fat, so are readily affected by the highly ionising alpha particles. This will result in cell destruction or mutation.

Question 23

Why is radon-220 a v.dangerous isotope?

Answer 23

Radon-220 is an alpha-emitter. It is a dense gas and therefore accumulates in the lower parts of buildings, etc. As it is a gas, it is readily inhaled and thus comes into close contact with internal cells.

As described above, this is the most hazardous condition for alpha sources.

Question 24

Give one difference between Thomson’s and R’s model?

Answer 24

In Thomson’s model, the mass of the atom is uniformly distributed through the whole of the atom.The atom was thought to be a positively charged sphere with negative charges distributed evenly throughout the sphere.

In Rutherford’s model, nearly all the mass of the atom and all its positive charge is concentrated in the small central core or nucleus.

Question 25

What did the results of G and M’s experiment reveal about the atom?

Answer 25

That most of the volume of a gold atom is empty space, and most of the mass and positive charge is concentrated in a very small volume at the centre of the atom.

Question 26

How would deflection change if particles had only half the electric charge?

Answer 26

The particles would have travelled closer to the nucleus before suffering a rebound and be deflected through smaller angles at any specific distance from the nucleus than the more highly charged particles.

Question 27

What is a fissile material?

Answer 27

The nuclei of its atoms can be split apart by a nucleus.

Question 28

What is a chain reaction?

Answer 28

A reaction that produces further reactions – in this case, neutrons produced when a uranium nucleus splits can cause further nuclei to split.

Question 29

Why does a chain reaction depend on the amount of fissile material in one piece?

Answer 29

If there is only a small amount, neutrons can escape the material without hitting any more nuclei.

Question 30

Advantages and Disadvantages of nuclear fission as an energy resource?

Answer 30

Advantages:
virtually inexhaustible supply of energy

does not produce ‘greenhouse’ gases.

Disadvantages:

produces waste that remains extremely dangerous for thousands of years

very highset-up and decommissioning costs.

Question 31

What are alpha particles?

Answer 31

Alpha particles are helium nuclei (1) ejected at high speed from the decaying nucleus (1).

Question 32

Describe the results of G and M’s expand what R drew from the results?

Answer 32

Most alpha particles passed straight through, undeflected (1). Some were deflected (1) and a
very small proportion actually rebounded (1).

Rutherford deduced that the mass and charge of
an atom was concentrated in a very small central core or nucleus (1)

Question 33

Describe the plum model?

Answer 33

In the plum pudding model, the mass is uniformly distributed throughout the volume of the atom
(1). The atom was considered to be a positively charged sphere with electrons studded in it like
plums in a pudding or raisins in a cake (1).

Question 34

Will an experiment with more or less particle representers be better?

Answer 34

The 200-dice experiment is more likely to produce the best model (1). In radioactive decay, millions of atoms are involved. The larger the number of dice, the more statistically valid the
experiment will be (1).

Question 35

What is an isotope?

Answer 35

Isotopes of an element have the same atomic number (1) and the same chemical properties (1).

Isotopes differ in their atomic mass (having different numbers of neutrons) (1) and have different physical properties (1).

Question 36

How does radiocarbon dating work?

Answer 36

Living organisms take in carbon-14, and so have a relatively fixed proportion of carbon-14 to carbon-12 in their body (1). When they die, the carbon-14 decays and is not replenished (1) so the proportion of carbon-14 decreases (1).

By measuring the relative amounts of the two isotopes of carbon, we can work out how long ago the organism died (1).

Question 37

How to measure the half-life of a radioactive isotope?

Answer 37

Using a GM tube and counter (1), measure the background radiation over a period of time to find the average count rate (1). Place the radioactive sample a fixed distance from the detector, taking care to handle the source with handling tongs at arm’s length (1). Measure the activity of the sample at regular intervals (of a minute or two) (1).

Plot a graph of activity against time (activity corrected for background count) (1). Measure how long it takes for the activity to halve from the graph (1).

Question 38

What isotope is best for cancer treatment?

Answer 38

An alpha-emitter (1) that can be attached to a material that is readily absorbed by the target tissue (1). Alpha radiation is heavily ionising (so short range) and will destroy the tissue in the
immediate vicinity of the emitter (1).

Question 39

What isotope is best for diagnosis?

Answer 39

A beta-emitter (1) with a relatively short half-life (1). The radiation can be detected outside the body (1) and will fall to a safe level of activity in a short period (1)

Question 40

Why is iodine isotope used in preference for thyroid cancer treatment?

Answer 40

Iodine is taken up by the thyroid (1). An overactive thyroid concentrates more iodine than a healthy one (1). Using a radioisotope of iodine means that cancerous cells within the thyroid can be destroyed without damage to other surrounding tissue (1).

Question 41

What is the effect of an emission of a beta particle on a nucleus?

Answer 41

Less neutron and one more proton. Mass number overall still the same.

Question 42

Sources of background radiation?

Answer 42

Radiation from rocks/buildings

Cosmic radiation from stars/Sun

Radiation from medical sources

Nuclear waste/accidents

Question 43

How would you measure for cosmic background radiation and adjust count rate accordingly?

Answer 43

Remove radioactive source going to be tested
Measure background count rate
Repeat the measurement/repeat for a long time
Subtract this value from each reading

Question 44

Explain why radioactive sources can be dangerous?

Answer 44

ionizing radiation

cells mutate

cancer

Question 45

What can be used to detect beta particles?

Answer 45

GM counter

zinc sulfide

photographic film

gold leaf electroscope

Question 46

Granite is a rock. It contains a radioactive isotope of uranium that decays very slowly. Explain how scientists can use this radioactivity to find the age of a piece of granite.

Answer 46

There is a known proportion of activity when rocks form. Measure activity now and COMPARE.

Hence determine the number of half lives elapsed and then calculate the age from that.

Question 47

Suggest why the age of a piece of granite could not be found using a uranium isotope with a half-life of 15 hours.

Answer 47

The half life is too short; it decays too rapidly.

The isotope would have decayed long ago and its current activity would be too small to measure or distinguish from background radiation.

Question 48

Explain what is meant by the term unstable.

Answer 48

Will decay/emit radioactive particles

Question 49

Explain what is meant by the term half-life.

Answer 49

Time taken for half of the radioactive nuclei /atoms to decay

Question 50

Describe how a teacher should measure the activity of a radioactive source using
a Geiger-Muller detector.

Answer 50

Use a rate meter
Measure background radiation
Safety precaution with use of tongs, shielding

Control time/distance by keeping the source near/by the detector for a minute

Repeat; average; reset scaler

Mention becquerel

Question 51

Iodine-131 is used to treat thyroid cancer. This radioactive isotope is allowed to enter the tumour. Explain why iodine-131 is suitable for this treatment.

Answer 51

Beta is moderately ionizing and has a short range and short half life

Easily absorbed by thyroid

Reduces damage to healthy cells and doesn’t penetrate out of body

Kills mainly tumour cells

Question 52

What form of energy is produced by nuclear fission?

Answer 52

Kinetic energy

Question 53

What is the job of a moderator?

Answer 53

slow down neutrons

increase rate of fission
increase absorption of neutrons by uranium/fuel

Question 54

Suggest why Uranium 238 is the most common isotope of Uranium?

Answer 54

Other isotopes have decayed more quickly and it has the longest half-life

Question 55

What is produced from nuclear fission?

Answer 55

gamma radiation (thermal energy)
more neutrons
krypton/barium/xenon

Question 56

What happens in the reactor when the control rod is removed?

Answer 56

The rate of reaction increases
Fewer electrons are absorbed by control rod
MORE COLLIDE WITH URANIUM
Temperature increases

Question 57

Explain why it is difficult to make the surrounding area safe again after a nuclear accident?

Answer 57

harmful nature of radiation/danger to life
high levels
long half/life

difficulties for workers to access the area
need special handling equipment
radioactive material can mix with local environment and spread material further (air, water, fire, soil, plants)

Question 58

Describe nuclear fission and how it is controlled?

Answer 58

nucleus absorbs neutron
splits into daughter nuclei
extra electrons are released
kinetic energy released

released neutrons collide with other uranium nuclei

CONTROLLED BY MODERATOR than slows down neutrons
control rods absorb extra electrons
Control rods prevent a runaway chain reaction

Question 59

What form of energy is released during fission?

Answer 59

KINETIC

Question 60

How does shielding improve safety?

Answer 60

Absorbs radiation and some particles’ energy

Question 61

Explain how nuclear fission can lead to a chain reaction

Answer 61

neutrons released
slowed by moderator
absorbed by other nuclei
causes further fissions

Question 62

Why is shielding needed on reactor?

Answer 62

Reactor material is radioactive and so is waste
Radiation ionizes cells/tissues/organs
Causes cancer
Radiation is very PENETRATING

Question 63

How should scientists deal with anomalous results?

Answer 63

check and repeat measurement/experiment

work out why this result ocurred

Question 64

Why is it important to carry out experiments in physics?

Answer 64

to make new discoveries
validate existing theories
disprove hypotheses
gather evidence
confirm other scientists' findings

Question 65

What is the Geiger counter?

Answer 65

Device to measure, detect and quantify the amount of radiation passing through

COUNTS NUMBER OF DECAYS/SECOND

Question 66

What does a ratemeter do?

Answer 66

indicates the number of pulses/counts per second.

Question 67

Number of protons and neutrons in uranium 238?

Answer 67

p = 92

n = 146

Question 68

Why are gamma and alpha radiation not used in paper industry?

Answer 68

Gamma would penetrate the paper either way

Alpha would be absorbed by the paper

Question 69

Why is a long half like needed in paper industry?

Answer 69

If you have a long half life then fluctuations in radiation detected must be due to paper thickness and not just a half life! If you get a drop you know that its because of a change in thickness of the paper and not because its decaying…

Question 70

What half life is needed in checking for pipe cracks?

Answer 70

medium half life - otherwise radiation will stay in and contaminate water!

Question 71

What radiation is used in finding leaks?

Answer 71

Gamma b/c alpha and beta wouldn’t penetrate earth and pipe material

Question 72

What radiation is used in tracers?

Answer 72

Gamma so it can be detected outside of the body - Alpha would just be absorbed by cells and this is VERY DANGEROUS AS IT IS IONIZING

Question 73

Risk of alpha inside and outside body?

Answer 73

OUTSIDE: minimal risk cannot penetrate past skin cells to reach living ones

INSIDE: high risk; every particles will interact with a body cell and cause damage

Question 74

Risks of beta inside and outside body?

Answer 74

OUTSIDE: medium risk; can penetrate and interact with cells

INSIDE: medium risk - many will pass out of body and many will interact with cells

Question 75

Risks of gamma inside and outside body?

Answer 75

OUTSIDE: high risk; many penetrate body but some interact other pass straight through

INSIDE: low risk - every gamma ray will pass through the body

Question 76

What decay does C-14 undertake?

Answer 76

beta

Question 77

What two isotopes undergo nuclear fission?

Answer 77

uranium 235

plutonium 239

Question 78

What is alpha stopped by?

Answer 78

Few mm of paper

Question 79

What is beta stopped by?

Answer 79

Few mm of aluminium

Question 80

What is gamma ‘stopped’ by?

Answer 80

reduce with metres of concrete / lead

Question 81

When is high intensity and long term exposure to radiation good and why?

Answer 81

It causes so much cell damage - good when sterilisation is to occur to kill microbes on surgical equipment for example.

Question 82

What does low intensity radiation do to a cell?

Answer 82

Causes mutations - some beneficial, some harmful

Question 83

How can a harmful mutation pose a threat?

Answer 83

If it increase by the cells affected dividing uncontrollably CANCER

Question 84

Safety precautions when handling radioactive material?

Answer 84

handle with tongs/forceps

at arms length, pointing way from body

far away from eyes

Question 85

Why don’t rocks contain carbon-14 atoms?

Answer 85

In rocks that are generally quite old. the amount of 14C is too small to measure accurately. Rocks make poor C14 samples because they do not include much-if any- free atmospheric gases which is the source of C14, the gases they include come from underground sources. All organic samples, plants and animals, do include C14,, as a part of their normal respiration.