P4: Atomic structure

Question 1

What was Dalton’s model of the atom?

Answer 1

Atoms were solid, indivisible spheres. Each element was made of a different type of sphere.

Question 2

What was Thomson’s model of the atom?

Answer 2

Discovered electrons which could be removed from atoms- disproving Dalton’s theory of indivisibility. Thomson suggested atoms were spheres of positive charge, with negative electrons scattered throughout (plum pudding model).

Question 3

What was Rutherford’s model of the atom?

Answer 3

Positively charged nucleus, surrounded by a cloud of negative electrons. This was the first nuclear model of the atom.

Question 4

What discovery did Bohr make? How was he proven right?

Answer 4

Electrons orbit the nucleus in fixed positions, called energy levels. His theoretical calculations agreed with experimental data.

Question 5

What discovery was made after electron orbits?

Answer 5

Experiments showed that the nucleus’ positive charge was subdivided between a group of particles, called protons.

Question 6

What discovery did Chadwick make? Why did this make sense?

Answer 6

He proved the existence of neutrons in the nucleus. This explained the imbalance between the atomic and mass numbers.

Question 7

Who theorised that atoms were solid, indivisible spheres?

Answer 7

Dalton.

Question 8

Who theorised the plum pudding model?

Answer 8

Thomson.

Question 9

Whose discoveries led to the nuclear model of the atom?

Answer 9

Rutherford.

Question 10

Who calculated that electrons had fixed orbits?

Answer 10

Bohr.

Question 11

Who discovered neutrons?

Answer 11

Chadwick.

Question 12

How was Rutherford’s alpha scattering experiment conducted?

Answer 12

Scientists in Rutherford’s lab fired a beam of alpha particles at a thin sheet of gold foil.

Question 13

In Rutherford’s alpha scattering experiment, what did the scientists expect to happen and why?

Answer 13

From the plum pudding model, they expected most particles to be slightly deflected, and a minority to pass straight through the foil.

Question 14

What were the results of Rutherford’s alpha scattering experiment? Why wasn’t this as expected?

Answer 14

The majority of the alpha particles went straight through the gold sheet, and some were deflected more than expected and a few were deflected right back the way they came. The plum pudding model couldn’t explain these results.

Question 15

In Rutherford’s alpha scattering experiment, a few alpha particles were deflected right back and some more than expected. What did the scientists deduce from this?

Answer 15

They realised that most of the atom’s mass was concentrated in a central nucleus, which must also have a positive charge, since it repelled the positive alpha particles.

Question 16

In Rutherford’s alpha scattering experiment, most of the alpha particles passed straight through. What did the scientists deduce from this?

Answer 16

They realised that most of the atom is just empty space, rather than a solid sphere, and that the nucleus is very small relative to this space.

Question 17

What was deduced from the results of Rutherford’s alpha scattering experiment?

Answer 17

1. Because a few alpha particles were deflected back, they realised that most of the atom’s mass was concentrated in a central nucleus, which must also have a positive charge, since it repelled the positive alpha particles.
2. Because most of the alpha particles passed straight through, they realised that most of the atom is just empty space, and that the nucleus is very small relative to this space.

Question 18

The nucleus’ radius is about ___x smaller than the radius of an atom.

Answer 18

10,000x

Question 19

The radius of an atom is about ___m.

Answer 19

1x10(^-10)m

Question 20

Electron shells =

Answer 20

energy levels.

Question 21

What happens when electrons gain energy by absorbing EM radiation?

Answer 21

They move to a higher energy level (further from the nucleus).

Question 22

What happens when electrons lose energy by releasing EM radiation?

Answer 22

They move to a lower energy level (closer to the nucleus).

Question 23

What are isotopes?

Answer 23

Isotopes of an element are atoms with the same number of protons, but different numbers of neutrons (so have different mass numbers).

Question 24

All elements have isotopes, but…

Answer 24

…but there are usually only one or two stable ones.

Question 25

What do unstable isotopes tend to do?

Answer 25

They decay into other elements, giving out radiation to become more stable. This process is called radioactive decay.

Question 26

What is radioactive decay?

Answer 26

The process by which unstable nuclei emit radiation until they reach a stable state.

Question 27

What types of radiation do unstable nuclei release?

Answer 27

Alpha, beta, gamma, neutron.

Question 28

What makes a nucleus unstable?

Answer 28

A bigger nucleus would be less stable because it’s harder to hold all the protons and neutrons together. The less energy holding them together, the less stable.

Question 29

What is alpha radiation?

Answer 29

A particle: helium nucleus (2 protons, 2 neutrons).

Question 30

What is the symbol for alpha?

Answer 30

α

Question 31

What is the mass and charge of alpha particles?

Answer 31

Relative mass: large. Charge: +2e

Question 32

What is the ionising power of alpha radiation?

Answer 32

High

Question 33

What is the range of alpha particles and why?

Answer 33

Because alpha radiation is so ionising, it quickly loses kinetic energy and is absorbed. It therefore has a small range of a few cm in air, and doesn’t penetrate very far into materials.

Question 34

Alpha particles can be blocked by…

Answer 34

…paper or skin.

Question 35

What is beta radiation?

Answer 35

A particle: high speed electrons released by the nucleus.

Question 36

What is the symbol for beta?

Answer 36

β

Question 37

What is the mass and charge of beta particles?

Answer 37

Small relative mass. Charge: -1e

Question 38

What is the ionising power of beta radiation?

Answer 38

Moderate to low.

Question 39

What is the range and penetration of beta radiation and why?

Answer 39

It travels several metres in the air, and penetrates moderately far into materials, because it is only moderately ionising.

Question 40

Beta radiation can be blocked by…

Answer 40

…thin sheet of aluminium and lead.

Question 41

What is gamma radiation?

Answer 41

It is a high energy, high frequency electromagnetic wave (of photons). Released by the nucleus to get rid of excess energy.

Question 42

What is the symbol for gamma?

Answer 42

γ

Question 43

What is the mass and charge of gamma rays?

Answer 43

No mass and no charge.

Question 44

What is the ionising power of gamma radiation and why?

Answer 44

Very low, because it has no mass or charge.

Question 45

What is the range and penetration of gamma radiation and why?

Answer 45

Both very high, because it has very low ionising power. Eventually, gamma rays will hit something and do damage.

Question 46

Gamma radiation can be “absorbed” by…

Answer 46

several cm of lead / several m of concrete

Question 47

How is alpha radiation used in smoke detectors?

Answer 47

Smoke alarms release alpha radiation, which ionises air particles, causing a current to flow. If there is smoke in the air, alpha particles bind to the ions. This stops the current, causing the alarm to go off.

Question 48

Why and can beta radiation be useful in testing the thickness of sheets of metal?

Answer 48

Because it’s moderately penetrating.

Question 49

What are beta emitters used for?

Answer 49

Testing the thickness of sheets of metal.

Question 50

Beta radiation is used in testing the thickness of sheets of metal. Why is this used, and not alpha or gamma?

Answer 50

Because beta radiation is moderately penetrating, particles aren’t immediately absorbed, where alpha radiation would be, and don’t penetrate as far as gamma rays. Therefore, slight variations in thickness of the metal affect the amount of radiation passing through the sheet.

Question 51

What is ionisation?

Answer 51

The process by which radiation from radioactive substances ionise (knock electrons out of) atoms.

Question 52

What does ionisation of body cells lead to?

Answer 52

Cell death and cancers.

Question 53

Which type of radiation is the most ionising?

Answer 53

Alpha.

Question 54

Alpha decay decreases the ___ and ___ of the nucleus.

Answer 54

Charge and mass.

Question 55

When an atom emits an alpha particle, its atomic number reduces by __ and and its mass number reduces by __.

Answer 55

2, 4

Question 56

What is the rule to remember when forming nuclear equations?

Answer 56

Total mass and atomic numbers must be equal on both sides of the equation.

Question 57

How can alpha particles be shown in nuclear equations?

Answer 57

(4,2)α or (4,2)He

Question 58

Give the equation for the alpha decay of uranium to thorium:

(238,92)U -> (x,y)Th + alpha

Answer 58

(238,92)U -> (234,90)Th + (4,2)He

Question 59

What sometimes also happens when a nucleus decays by alpha or beta?

Answer 59

Gamma rays can be released.

Question 60

What happens during beta decay?

Answer 60

A neutron in the nucleus turns into a proton and releases a fast-moving electron.

Question 61

What happens to an atom’s charge during beta decay?

Answer 61

Neutron -> proton + electron. The nucleus’ charge increases by one, and one electron is lost. Overall, the charge increases by 2.

Question 62

Why doesn’t the mass of the nucleus change during beta decay?

Answer 62

Because the nucleus has lost a neutron and gained a proton- which have the same mass.

Question 63

How are beta particles represented in nuclear equations?

Answer 63

(0, -1)e or (0, -1)β

Question 64

Give the equation for the beta decay of carbon to nitrogen:

(14, 6)C -> (x,y)N + beta

Answer 64

(14, 6)C -> (14, 7)N + (0, -1)e

Question 65

Why are new elements formed in alpha and beta decay, but not gamma?

Answer 65

The number of protons (atomic number) changes in alpha and beta decay, but doesn’t in gamma decay.

Question 66

How are gamma rays represented in nuclear equations?

Answer 66

(0,0)γ

Question 67

Give the equation for the gamma decay of uranium:

(238, 92)U ->

Answer 67

(238, 92)U -> (238, 92)U + (0,0)γ

Question 68

Why is there no change to the mass or atomic number of an atom after gamma decay?

Answer 68

Gamma radiation is not a particle- it is a wave, of energy, and has no mass or charge.

Question 69

How can radiation be measured?

Answer 69

With a Geiger-Muller tube and counter, which records the count-rate.

Question 70

Radioactive decay of a nucleus cannot be ___ ___; it is ___. Half-life can be used to make___ ___ about radioactive sources.

Answer 70

1) accurately predicted
2) random
3) estimated predictions

Question 71

What is activity and what is it measured in?

Answer 71

The number of decays per second- measured in Becquerels, Bq, where 1Bq is one decay per second.

Question 72

What is the half-life of a radioactive isotope?

Answer 72

The time it takes for half the nuclei in the sample to decay, or for the activity to halve.

Question 73

How can substances with a short half-life be dangerous? What is a more positive side to this?

Answer 73

The nuclei are very unstable and rapidly decay, emitting large amounts of radiation. However, they quickly become safer because the activity falls quickly.

Question 74

How can substances with a long half-life be dangerous?

Answer 74

Activity falls slowly, so the source releases small amounts of radiation over a long time. Dangerous because nearby areas can be exposed to radiation for millions of years.

Question 75

What is the formula to calculate the mass/no. nuclei of a sample left where the half-life and time passed is given?

Answer 75

= i x2^-n

where i = initial mass/no. nuclei and n = no. half-lives passed

Question 76

A 1kg sample of an isotope has a half-life of 3 hours. How much of the sample would you expect to be remaining after 9 hours?

Answer 76

1kg x 2^-3 = 0.125kg

Question 77

What is the formula to calculate the amount of a sample left where the half-life and time passed is given?

Answer 77

= i x2^-n

where i = initial activity and n = no. half-lives passed

Question 78

The initial activity of a sample is 640Bq. Calculate the final activity, after two half-lives, as a percentage of the initial activity.

Answer 78

1) 640 x 2^-2 = 160Bq

2) (160/640) x 100 = 25%

Question 79

When measuring radiation, you should always…in order to avoid..

Answer 79

1) measure and subtract the background radiation from your results.
2) systematic errors

Question 80

What three things contribute to background radiation?

Answer 80

1) Radioactivity of naturally occuring unstable isotopes.
2) Radiation from space: cosmic rays.
3) Radiation due to human activity.

Question 81

Naturally occuring unstable isotopes are found all around us, e.g. in…

Answer 81

Rocks, the air, food.

Question 82

Cosmic rays usually come from __ ___. The ___ protects us from much of this radiation.

Answer 82

1) The sun

2) Atmosphere

Question 83

Radiation due to human activity represents a ___ proportion of the total background radiation on Earth.

Answer 83

Tiny.

Question 84

What is radiation dose measured in?

Answer 84

Sieverts (Sv) or millisieverts (mSv)

Question 85

What is irradiation?

Answer 85

Exposure to radiation.

Question 86

When working with radioactive sources, what are two ways to prevent irradiation?

Answer 86

1) Keeping sources in lead-lined boxes.

2) Staying behind barriers/in a different room and controlling the source remotely.

Question 87

What is contamination?

Answer 87

The presence of radioactive materials in/on an object.

Question 88

Why is contamination more dangerous than irradiation?

Answer 88

A contaminated object will be exposed to radiation for as long as it is contaminated, whereas, if irradiated, it stops being exposed to radiation as soon as it is no longer near the source.

Question 89

What three things are used to prevent contamination?

Answer 89

1) Gloves
2) Tongs
3) Protective suits

Question 90

What sources of radiation are most dangerous outside the body?

Answer 90

Beta and gamma, because they can penetrate the body and get to sensitive organs. Alpha is less dangerous because it is blocked by a few cm of air, and can’t penetrate through the skin, so is unlikely to get inside your body.

Question 91

Which type of radiation poses the greatest threat to cells when inside the body? Why?

Answer 91

Alpha, because it is the most ionising (due to charge of 2+ and a large mass) and does damage in a very localised area.

Question 92

When working with alpha sources, is the main concern irradiation or contamination?

Answer 92

Contamination.

Question 93

Which type of radiation poses the smallest threat to cells when inside the body? Why?

Answer 93

Gamma, as they usually pass straight through the body since they have a very small ionising power.

Question 94

Why are beta sources less damaging than alpha when inside the body?

Answer 94

Radiation is absorbed over a wider area, and some passes out of the body.

Question 95

How are gamma sources used in medical tracers?

Answer 95

Certain radioactive isotopes are injected or swallowed, and their progress around the body is followed by an external detector. A computer displays where the strongest reading of radioactivity is coming from. This indicates whether substances are being taken in as they should be.

Question 96

Why are gamma emitters used in medical tracers?

Answer 96

Gamma is used so that radiation passes through the body without causing too much ionisation.

Question 97

Why should gamma emitters used in medical tracers have a short half-life?

Answer 97

So that radioactivity inside a patient quickly minimises, preventing too much ionisation.

Question 98

How does radiotherapy work? Give 2 methods.

Answer 98

1) Gamma rays are directed carefully, and at the right dosage, to kill cancer cells without damaging too many normal cells.
2) Radiation (usually beta) emitting implants are put next to/inside tumours.

Question 99

Why does radiotherapy make patients feel ill?

Answer 99

Damage is done to non-cancerous cells in the process of killing cancerous ones.

Question 100

Explain how contamination leads to cell death and cancer.

Answer 100

When radiation enters the body, it causes ionisation of atoms and molecules in tissue.
Lower doses of radiation lead to mutated cells which divide uncontrollably, i.e. cancer.
Higher doses cause cell death, which can lead to radiation sickness.

Question 101

Why are many scientists trying to push the production of nuclear power over fossil fuels?

Answer 101

1) Nuclear power produces more energy per unit mass than fossil fuels.
2) Fossil fuels produce carbon dioxide when burnt, contributing to global warming.

Question 102

Explain what happens during induced nuclear fission.

Answer 102

1) High-energy neutron fired at unstable nucleus.
2) Nucleus absorbs neutron and becomes more unstable.
3) Nucleus splits into 2, releasing 2+ neutrons and… 4) Energy not transferred to the KE stores of the products is carried away by gamma rays.
5) If any of the released neutrons are moving enough, they can be absorbed by another nucleus and cause it to split, i.e. a chain reaction.

Question 103

During nuclear fission, energy is carried away by gamma rays and transferred to the kinetic energy stores of the products (neutrons and two nuclei). How is this energy used?

Answer 103

Used to heat water, producing steam to turn turbines and generators.

Question 104

How is nuclear fission controlled?

Answer 104

Lowering down control rods into a nuclear reactor. These absorb neutrons, slowing the chain reaction and controlling the amount of energy released.

Question 105

What happens during uncontrolled fission reactions?

Answer 105

Lots of energy is released as an explosion (this is how nuclear weapons work).

Question 106

What happens during nuclear fusion?

Answer 106

1) Two small, high-speed nuclei collide and fuse into a larger nucleus.
2) This nucleus is less massive than the total mass of the two initial nuclei. Some of their mass is converted to energy and released as radiation.

Question 107

For a given mass of fuel, which of nuclear fission and fusion produces more energy?

Answer 107

Fusion.

Question 108

Although nuclear fusion produces more energy than fission per unit mass of fuel, it can’t be used to generate energy. Why is this?

Answer 108

The temperatures and pressures needed for fusion are so high that fusion reactors are difficult and expensive to build.

Question 109

Why are sources of alpha radiation more dangerous inside the body than outside the body?

Answer 109

Inside:
1) Alpha radiation is strongly ionising
2) When it enters living cells, it can kill them, damage
them and cause cancer.
3) It is almost certain to be absorbed by living cells and
cause damage.

Outside:
1) It is easily absorbed by thin barriers (e.g. skin) so is
unlikely to reach the body’s delicate organs if outside
the body.