P7 - Radioactivity Flashcards

Question 1

Q

What is activity?

Answer

A

The number of unstable atoms that decay per second in a radioactive source

Question 2

Q

What is alpha radiation (α)

Answer

A

Alpha particles, each composed of 2 protons and 2 neutrons (helium nuclei), emitted by unstable nuclei at an extremely high speed

Question 3

Q

What is an atomic number?

Answer

A

The number of protons (which equals the number of electrons) in an atom. It is sometimes called the proton number

Question 4

Q

What is beta radiation (β)?

Answer

A

Beta particles that are high energy electrons created in, and emitted from, unstable nuclei

Question 5

Q

What is a chain reaction?

Answer

A

Reactions in which one reaction causes further reactions, which in turn cause further reactions, etc.

Question 6

Q

What is the count rate?

Answer

A

the number of decays recorded each second by a Geiger counter

Question 7

Q

What is gamma radiation (γ)?

Answer

A

Electromagnetic radiation emitted from unstable nuclei in radioactive substances

Question 8

Q

What is a half-life?

Answer

A

Average time taken for half the number of nuclei of the isotope (or mass of the isotope) in a sample to decay.

Average time for the count rate to fall by half

Question 9

Q

What is ionisation?

Answer

A

Any process in which atoms become charged (become ions)

Question 10

Q

What does irradiated mean?

Answer

A

Objects near a radioactive source are said to be irradiated by it. This simply means that they’re exposed to a radioactive source. This does not make the source radioactive.

Question 11

Q

What are isotopes?

Answer

A

Atoms with the same number of protons and different numbers of neutrons

Question 12

Q

What is the mass number?

Answer

A

The number of protons and neutrons in a nucleus

Question 13

Q

What is a moderator?

Answer

A

Substance in a nuclear reactor that slows down fission neutrons

Question 14

Q

What is nuclear fission?

Answer

A

The process in which certain unstable nuclei (such as uranium-235 and plutonium-239) split into 2 daughter nuclei, releasing energy (in the form of gamma radiation) and 2 or 3 neutrons as a result

Question 15

Q

What is a nuclear fission reactor?

Answer

A

reactors that release energy steadily due to the fission of a suitable isotope, such as uranium-235 or plutonium-239

Question 16

Q

What is nuclear fusion?

Answer

A

the process where light nuclei are forced together to fuse and form a larger nucleus

Question 17

Q

What is radioactive contamination?

Answer

A

The unwanted presence of materials containing radioactive atoms on other materials. The contaminating atoms may then decay, releasing radiation which may cause harm. Contamination is especially dangerous as radioactive particles may get inside your body

Question 18

Q

What is a reactor core?

Answer

A

The thick steel vessel used to contain fuel rods, control rods, and the moderator in a nuclear fission reactor

Question 19

Q

How were radioactive materials discovered?

Answer

A

Henri Becquerel used covered photographic plates that were placed under uranium salts to discover radioactivity. Henri Becquerel’s work was expanded on by Marie and Pierre Curie, who investigated and discovered a range of new radioactive elements

Question 20

Q

What is radiation?

Answer

A

The emission of energy as electromagnetic waves or as moving subatomic particles

Question 21

Q

What is the unit for radioactivity (and count rate)?

Answer

A

Becquerels (Bq), where 1 Bq = 1 nuclear decay event per second

Question 22

Q

What type of substances emit radiation?

Answer

A

Substances containing atoms with unstable nuclei

Question 23

Q

What causes a nucleus to become unstable?

Answer

A

If it contains too many protons
If it contains too many neutrons
If it is too large

These factors cause the nucleus to have excess energy, making it unstable

Question 24

Q

Why does an unstable nuclei undergo nuclear decay/

Answer

A

An unstable nuclei can undergo nuclear decay, emitting radiation and becoming more stable as they do so.

Question 25

Q

What is a geiger counter?

Answer

A

A Geiger counter is a device that counts the number of radioactive particles per second. A Geiger counter clicks even when it is not near a radioactive source, this effect is due to background radiation

Question 26

Q

Why does a Geiger counter click even when it is not near a radioactive source?

Answer

A

Due to background radiation

Question 27

Q

Explain the gold foil experiment and the results it produced:

Answer

A

Rutherford set up a radioactive source which sent a beam of alpha particles towards a gold foil (which was surrounded by a detector which could detect alpha particles). Most of the alpha particles passed straight through the foil un deflected, this suggests that atoms are mostly empty space. Some of the alpha particles were deflected by small angles, this suggests the centre of the atom is positively charged as it repels the positively charged alpha particles. Occasionally, an alpha particle would travel back from the foil, this suggests the atom contains a dense centre containing a lot of mass

Question 28

Q

Why were so many atomic models abandoned in favour of new models?

Answer

A

New models explained data from tests and experiments better than old models, new results contradicted old results

Question 29

Q

What is a radioisotope?

Answer

A

An isotope which has an unstable nucleus. It will decay by emitting radiation

Question 30

Q

What is the difference between a daughter nucleus and the parent nucleus, when the parent nucleus has emitted alpha radiation?

Answer

A

The daughter nucleus would have an atomic mass of 4 less than the parent nucleus and an atomic number of 2 less than the parent nucleus

Question 31

Q

Write the equation for Thorium-232 decaying by emitting alpha-radiation (atomic number = 90)

Question 32

Q

Explain how Beta Decay occurs:

Answer

A

An atom decays into a new atom by changing a neutron into a proton and an electron. The fast moving, high energy electron is known as a beta particle

Question 33

Q

What is the difference between a daughter nucleus and the parent nucleus, when the parent nucleus has emitted beta radiation?

Answer

A

The daughter nucleus would have the same atomic mass, but the atomic number would increase by 1.

Question 34

Q

Write the equation for Radium-228 decaying by emitting beta-radiation (atomic number = 88)

Question 35

Q

What is the difference between a daughter nucleus and the parent nucleus, when the parent nucleus has emitted gamma radiation?

Answer

A

There is no atomic change within the nucleus

Question 36

Q

Explain the process of gamma decay:

Answer

A

Gamma radiation is surplus energy sometimes emitted after alpha or beta decay. The atom itself is not changed. Gamma radiation is part of the EM spectrum; a wave with a very high frequency, very short wavelength

Question 37

Q

What type of wave is gamma radiation?

Answer

A

An electromagnetic wave with a very high frequency, very short wavelength

Question 38

Q

Write the equation for when Radon 224 decays by alpha emission:

Question 39

Q

Write the equation for when Strontium 90 decays by beta emission

Question 40

Q

What is 1 bequerel?

Answer

A

1 decay event per second

Question 41

Q

What is the symbol for alpha radiation?

Question 42

Q

What is the symbol for beta radiation?

Question 43

Q

What is the symbol for gamma radiation?

Question 44

Q

What is the range in air of alpha radiation?

Question 45

Q

What is the range in air of beta radiation?

Question 46

Q

What is the range in air of gamma radiation?

Answer

A

unlimited - spreads out in air without being absorbed

Question 47

Q

What is the penetrative power of alpha radiation?

Answer

A

It can be stopped by a sheet of paper / skin

Question 48

Q

What is the penetrative power of beta radiation?

Answer

A

it can be stopped by 3mm of aluminium or a thin lead sheet

Question 49

Q

What is the penetrative power of gamma radiation?

Answer

A

It can be stopped by a thick lead sheet (several cm thick) or concrete (more than 1m thick)

Question 50

Q

What is the ionising power of alpha radiation?

Answer

A

Very strong ionising

Question 51

Q

What is the ionising power of beta radiation?

Answer

A

relatively ionising, less ionising than alpha but more ionising than gamma

Question 52

Q

What is the ionising power of gamma radiation?

Answer

A

Weakly ionising

Question 53

Q

What is ionising power?

Answer

A

The ability for nuclear radiation to remove electrons from atoms to form ions

Question 54

Q

Why is alpha radiation the most ionising?

Answer

A

Alpha particles are the most ionising because they have the largest mass and charge. Gamma rays do not interact with electrons strongly at all

Question 55

Q

Explain how ionising radiation is used in smoke alarms:

Answer

A

Smoke alarms contain a radioactive isotope that sends out alpha particles into a gap in a circuit in the alarm, The alpha particles ionise the air in the gap so there is a current across the gap. In a fire, smoke absorbs the alpha particles, preventing them from ionising the air, so the current across the gap drops and the alarm sounds. Beta or gamma radiation could not be used because they do not create enough ions to make the air in the gap conduct electricity, they would also not be absorbed by the smoke

Question 56

Q

Explain how ionising radiation is used in automatic thickness monitoring in metal foil:

Answer

A

Automatic thickness monitoring in metal foil production uses a radioactive source that sends out beta radiation. The amount of beta radiation passing through the foil depends on the thickness of the foil. The detector measures the amount of radiation passing through the foil. If the foil is too thick, the detector reading drops and the detector sends a signal to increase the pressure of the rollers on the metal sheet. This makes the foil thinner again. Gamma radiation isn’t used because it would all pass through the foil unaffected. Alpha radiation isn’t used as it would all be stopped by the foil.

Question 57

Q

What is the nuclear equation for alpha-decay?

Question 58

Q

What is the nuclear equation for beta-decay?

Question 59

Q

What happens to the activity of a source as more and more unstable atoms decay?

Answer

A

As there are fewer unstable atoms there is a lower activity as fewer unstable atoms decay per second

Question 60

Q

Radioactive decay is ……………………..

Answer

A

Random / Spontaneous
Not effected by temperature
Unpredictable

Question 61

Q

What is the half life of iodine-131?

Question 62

Q

What is the equation for count rate after “n” half lives?

Answer

A

Count rate after “n” half lives = Count rate before / 2ⁿ

Question 63

Q

What is the half life of carbon-14?

Answer

A

5760 years

Question 64

Q

What is the isotope used in carbon dating and why?

Answer

A

Carbon-14 as it is a radioisotope and decays over time

Answer 53

A

Radioactive tracers
Gamma cameras
External Radiotherapy
Internal Radiotherapy

Answer 54

A

Radioactive tracers are used to trace the flow of a substance through an organ and therefore image and diagnose a range of illnesses. The tracer contains a radioactive isotope that emits gamma radiation as it can be detected outside the system. For example, doctors use radioactive iodine to find out if a patients kidney is blocked.
Before the test, the patient drinks water containing a tiny amount of the radioactive substance. A detector is then placed against each kidney. Each detector is connected to a chart recorder.
*The radioactive substance flows in and out of a normal kidney. So the detector reading goes up then down.
*For a blocked kidney, the reading goes up and stays up. This is because the radioactive substance goes into the kidney but does not flow out again

Answer 55

A

Iodine-131 is used because:

Its half life is eight days, so it lasts long enough for the test to be done, but decays almost completely after a few weeks
It emits gamma radiation, so it can be detected outside the body
It decays into a stable product

Answer 56

A

Gamma cameras are used to take images of internal body organs. Before an image is taken, the patient is injected with a solution that contains a gamma-emitting radioactive isotope. The solution is then absorbed by the organ, and a nearby gamma camera detects the gamma radiation emitted by the solution. The gamma rays pass through the holes in the thick lead grid in front of the detector (this way only gamma rays from nuclei directly in front of the detector are detected as rays at an angle are blocked by the lead grid). The detector signals are used to build up an image of where the radioactive isotope is located in the organ.

Answer 57

A

Gamma radiation in a narrow beam is sued to destroy cancerous tumours. The radiation is emitted from a radioactive isotope of cobalt. It has a half-life of 5 years. Gamma radiation is used because it can penetrate deeper into the body than beta radiation and alpha radiation

Answer 58

A

radioactive implants are used to destroy cancer cells in some tumours. Beta or gamma emitting isotopes are used in the form of small seeds or tiny rods. Permanent implants use isotopes with half-lives long enough to irradiate the tumour over a given time, but short enough so that most of the unstable nuclei will have decayed soon afterwards

Answer 59

A

background radiation

Answer 60

A

Because nuclear decay is random and uncontrollable

Answer 61

A

Spontaneous

* Induced

Answer 62

A

fission is unforced and happens by itself, this is rare

Answer 63

A

If an already unstable nuclei absorbs a neutron, it’s atomic mass will increase and it will become even more unstable and fission will occur, this is usually how fission occurs

Answer 64

A

Not all atoms can undergo nuclear fission, those that can are called fissionable

Answer 65

A

During fission, neutrons (fission products) fired form a nucleus can collide with other unstable nuclei, causing further fission events to occur, resulting in a chain reaction

Answer 66

A

Control rods absorb excess neutrons, this prevents the chain reaction becoming out of control

Answer 67

A

High pressure and temperature is required

* The nuclei repel each other as they are both positively charged

Answer 68

A

Both release lots of energy, but nuclear fusion releases much more energy than nuclear fission

Answer 69

A

Background radiation is a measure of the level of ionising radiation present in the environment at a particular location which is not due to deliberate introduction of radiation sources. Background radiation orignates form a variety of sources, both natural and artificial

Answer 70

A

To prevent radioactive contamination of the environment and it needs to be stored for many years as the waste contains radioisotopes with long half lives

Answer 71

A

Nuclei approaching each other will repel each other as they are both positively charged. To overcome this, the nuclei must be heated to extremely high temperatures to give them enough kinetic energy to overcome this repulsion, and fuse together. Because of the enormously high temperatures involved, the reaction cannot take place inside a normal container, since the nuclei would touch the edges and grow cold, causing fusion to stop. Instead, the fusion reaction must be contained by a magnetic field. This is extremely difficult and expensive to perform.

Answer 72

A

Cosmic rays
Ground and buildings
Food and drink
Natural radioactivity in the air
Medical applications
Air travel

Answer 73

A

Used fuel rods are removed from a reactor and stored in big tanks of water for up to a year to cool down. Remote-control machines are then used to open up the fuel rods. The unused uranium and plutonium is removed chemically so that it can be reused. The material that is left contains lots of radioactive isotopes with long half lives. This radioactive waste has to be stored in secure conditions for many years to prevent radioactive contamination of the environment

Answer 74

A

if the substance contains atoms that decay, releasing radiation in the form of particles or energy

Answer 75

A

Keeping sources in a lead-lined box
Standing behind barriers or being in a different room
Using remote-controlled arms

Answer 76

A

Gloves and tongs should be used when handling sources, to avoid particles getting stuck to your skin or under your nails
Using protective suits to stop particles being breathed in

Answer 77

A

Contamination, this is because alpha particles can only travel a few centimetres in the air and cannot penetrate your skin and cause damage to your internal organs but can cause great damage if already inside your body

Answer 78

A

Outside the body, beta and gamma sources are the most dangerous. This is because beta and gamma particles can penetrate the body and get to the delicate organs. Alpha is less dangerous because it cannot penetrate the skin and is easily blocked by a small air gap as it can only travel a few centimetres in the air. High levels of irradiation from all sources are dangerous, especially from beta and gamma emitting sources

Answer 79

A

Inside the body, alpha sources are the most dangerous, this is because they do all their damage in a very localised area. So contamination, rather than irradiation, is the main concern when working with alpha sources. Beta sources are less damaging inside the body, as radiation is absorbed over a wider area, and some passes out of the body all together. Gamma sources are the least dangerous inside the body, as they mostly pass straight out - they have the lowest ionising power

Answer 80

A

Radiation can enter living cells and ionise atoms and molecules within them. This can lead to tissue damage
Lower doses tend to cause minor damage without killing the cells. This can cause mutations which cause the cells to divide uncontrollably. This is known as cancer
Higher doses tend to kill cells completely, causing radiation sickness (leading to vomiting, tiredness and hair loss) if a lot of cells all get irradiated at once

Answer 81

A

Nuclear decay

Answer 82

A

mass = 4
number = 2
charge = +2

Answer 83

A

mass = almost 0
charge = -1

Answer 84

A

number of unstable nuclei after “n” half lives = initial number of unstable nuclei / 2ⁿ

Answer 85

A

2 or 3 high speed neutrons

* energy - in the form of gamma radiation, and kinetic energy of the nuclei and neutrons

Answer 86

A

slower moving neutrons are more effective in causing a fission event, faster moving neutrons don’t cause further fission

Answer 87

A

During fusion, some of the mass of the small nuclei is converted to energy (this is given by the equation “E = mc²)

Answer 88

A

When 2 light nuclei collide at very high speeds

Answer 89

A

Wear a personal radiation monitor, such as a film badge. This badge shows if it is over-exposed to ionising radiation, its wearer should not continue to work with radioactive equipment for a period of time

Answer 90

A

Enriched uranium, 97% Uranium-238 (non-fissionable), 3% Uranium-235 (Fissionable)

Answer 91

A

The reactor core contains the fuel rods, control rods, and water at high pressure. The fission neutrons are slowed by collisions with the atoms in the water molecules. This is because fast neutrons don’t cause further fission of U-235. The water is said to act as a moderator as it slows the fission neutrons. Control rods absorb surplus neutrons. This keeps the chain reaction under control. The depth of the rods in the core is adjusted to maintain a steady chain reaction. The fuel rods become very hot (due to energy released during fission) and the water acts as a coolant. Its molecules’ kinetic energy stores increase as energy is transferred from the neutrons and fuel rods. The water is pumped through the core. Then it goes through sealed pipes to and from a heat exchanger outside the core. The water transfers energy from the core to the heat exchanger. In the heat exchanger the moderating water heats and evaporates water in pipes which drives a turbine, which in turn drives a generator, generating electricity

Answer 92

A

Heated by passing a large electrical current through it

* Contained by a magnetic field so that it does not touch the reactor walls

Answer 93

A

The fuel for fusion reactors is easily available as heavy hydrogen is naturally present in sea water (unlike fission which requires uranium-235)
The reaction product, helium, is a non-radioactive gas, so it is harmless (whereas fission produces radioactive waste)
Fusion releases much larger amounts of energy than fission does

Answer 94

A

Background radiation
Nuclear waste
Nuclear accidents
Half-lives and instability
Radioactive risks

Answer 95

A

Another term for the hydrogen isotope deuterium, it has a mass number of 3 (contains 1 proton and 2 neutrons)

Answer 96

A

A Geiger counter clicks even without a radioactive source near it. This is because of background radiation. Background radiation is a measure of the level of ionizing radiation present in the environment at a particular location which is not due to deliberate introduction of radiation sources

Answer 97

A

Background radiation in the air is mostly caused by radon gas that seeps through the ground from radioactive substances in rocks deep underground. Radon gas emits alpha particles, so radon is a health hazard if it is breathed in. It can seep into homes and other buildings in some locations. In affected homes, pipes under the building can be installed and fitted to a suction pump to draw the gas out of the ground before it seeps into the building

Answer 98

A

Used fuel rods are extremely hot and very radioactive. After they are removed from a reactor, they are stored in big tanks of water for up to a year. The water cools the rods down. Remote-control machines are then sued to open up the fuel rods. The unused uranium and plutonium are removed chemically from the used fuel. These are stored in sealed containers so they can be used again. The material that’s left contains lots of radioactive isotopes with long half-lives. This radioactive waste has to be stored in secure conditions for many years to prevent contamination of the environment

Answer 99

A

In 1986, a nuclear reactor in Ukraine exploded. A cloud of radioactive material from the fire drifted over many parts of Europe, including Britain. More than 100 000 people were evacuated and over 30 people died in the accident. More have developed leukaemia or other cancer types since then. The Chernobyl reactor did not have high-speed shutdown systems like most reactors have, safety instructions were ignored. Lessons learnt were put into place during the Fukushima meltdown, the population within 20km were evacuated and many things were monitored for years to come.

Answer 100

A

A standard design to reduce costs and construction time
A longer operating life
More safety features, such as convection of outside air through cooling panels along the reactor walls
Much less effect on the environment

Answer 101

A

Radioactive isotopes have a wide range of half-loves. Some radioactive isotopes have half-lives of a fraction of a second, whilst others have half-lives of over 1 billion years. Isotopes with the shortest half-lives have the most unstable nuclei - so they emit a lot of radiation in a short amount of time

Answer 102

A

The half-life of a radioactive source tells you how quickly its activity decreases. As its activity decreases, the rate it gives out radiation decreases. So the hazards caused by the ionising effect of the radiation from radioactive materials decrease with time according to the half-lives of their isotopes.

Answer 103

A

They do not interact with the atoms much, they tend to pass straight through

Answer 104

A

Yes, irradiating food does not make it radioactive, it simply kills the hsrmful bacteria and other pathogens that may be on the food

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P7 - Radioactivity Flashcards

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