basics to radioactivity

Question 1

Radioactivity

Answer 1

• Spontaneous emission of small particles and or radiation (energy) by unstable atomic nuclei to attain more stable nuclear state

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Question 2

1896- Henry Becquerel-

Answer 2

studied phosphorescence with uranylsulfate, discovered the uranium radioactivity.
Nobel prize in physics- 1903 for discovery of radioactivity

Question 3

Becquerel

Answer 3

• Investigated connection between x-rays and naturally occurring phosphorescence
• When uranium salts were placed by a photographic plate covered with opaque paper the plate was discovered to be fogged
• This was a property of the uranium atom
• He showed that the rays emitted uranium caused gases to ionize and that they differed from x-rays in that they could be deflected by electric or magnetic fields

Question 4

1896

Answer 4

• Marie curie pursued the study of becquerel rays
• Studied radioactive material
• The pitchblende contained traces of some unknown radioactive component which was far more radioactive than uranium
• In 1898 she announced the existence of this new substance
• After several years they isolated 2 new chemical elements, radium and polonium
• Radioactivity was found to be unaffected by chemical and physical testing showing that the radiation came from the atom itself- specifically from the disintegration or decay of an unstable nucleus

Question 5

Discovery of radioactivity

Answer 5

• 1898- ernest Rutherford began studying the nature of the rays that were emitted
• Classified into three distinct types according to their penetrating power
• Alpha decay- positively charged can barely penetrate a piece of paper
• Beta decay- negatively charged pass through as much as 3mm of aluminium
• Gamma decay- neutral; extremely penetrating

Question 6

Types of radiation

Answer 6

• Alpha rays- nuclei of helium atoms )2 protons and 2 neutrons)
• Beta rays- electrons (created within the nucleus)
• Gamma rays- high energy photons (packets of energy)

Question 7

Alpha decay

Answer 7

• The loss of 2 neutrons and 2 pr0tons changes the atom

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Question 8

Alpha decay smoke detector

Answer 8

• Americium 241 has a half life of 432.6 years.
• Emitted α particle ionises the air molecules which conduct current between two terminals
• Smoke clings to ionised air molecules and slows them down
• Current decreases and a transistor switch activates the alarm
• Contains 0.3µg of the isotope or 37Bq or 1 Ci of radioactivity.
• Radiation risk much smaller than background radiation.
• Sensitive to flaming stage of fire
• Optical smoke detectors sensitive to smouldering stage of fire

Question 9

Beta decay (negatron decay)

Answer 9

• The electron emitted in beta decay is NOT an orbital electron; the electron is created in the nucleus itself
• One of the neutrons changes to a proton and in the process (to conserve charge) throws off an electron
• These particles are referred to as beta particles so as not to confuse them with orbital electrons

Question 10

Beta decay and the neutrino

Answer 10

• Scientists found that some of the fundamental principles in physics did not hold true (law conservation of energy and law of conservation of momentum- both linear and angular)
• 1930- wolfgang pauli proposed there was a new particle that was very difficult to detect was emitted in beta decay, as well as the electron
• Neutrino- symbol is ‘nu’ (v)
• So the equation becomes: (bar denotes anti neutrino)

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Question 11

Positron decay

Answer 11

• Occurs when there are too few neutrons compared to protons
• These isotope lies between the stable isotope line
• This beta decay, the particle that is emittied is called positron but has a charge of +1 but same mass as an electron
• The positron is called the antiparticle to the electron
• Many different radioisotopes are positron emitters, such as Fluorine18, Oxygen15, and Carbon11.

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Question 12

Positron emission tomography (PET)

Answer 12

• nuclear medicine functional imaging technique that is used to observe metabolic processes in the body.
• The system detects pairs of gamma rays emitted indirectly by a positron-emitting radionuclide (tracer), which is introduced into the body on a biologically active molecule. 3-D images of tracer concentration within the body are then constructed by computer analysis.
• Biological molecule e.g. fludeoxyglucose (FDG), an analogue of glucose, shows tissue metabolic activity corresponding to glucose uptake. Indicates cancer metastastis (90% of use)

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• 20min scan. Red areas show more accumulated tracer substance (18F-FDG) and blue areas are regions where low to no tracer have been accumulated. Used to detect cancers.

Question 13

Electron capture

Answer 13

• Occurs when a nucleus absorbs one of the orbiting electrons
• Usually the innermost electrons
• The electron disappears and a proton becomes a neutron in the process
• A neutrino is emitted in electron capture decay
• This has been detected by the emission of x-rays due to other orbital electrons jumping down to fill in the lower energy levels and releasing energy of that energy
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Question 14

Source of instabilities

Answer 14

• Too big
• Too many neutrons for the protons
• Not enough neutrons for the protons
• Too many excess energy

Question 15

Nuclear stability- Determined by the number of neutrons to protons

Answer 15

Atomic number (Z) less than 20 (Calcium):
- Ratio close to 1 fall in zone of stability
Atomic number (Z) going from 21( Scandium)- 83( Bismuth):
- Number of neutrons always greater than the number of protons
- Neutrons help to stabilise the nucleus and overcome repulsive electric forces of the protons
- Ratio increases from 1 to 1.5 as Z increases from 21 to 83
Atomic number (Z) greater than 83 (Bismuth):
- Ratio greater than 1.5 ( proportionately more neutrons needed to stabilise larger number of protons)
- All unstable and decay and are radioactive
- Outside zone of stability

Question 16

Neutron to proton ratio

Answer 16

• Shaded region corresponds to ‘ban’ or ‘belt’ od stability

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Left of zone:
Neutron rich
Changes neutrons to protons by β emission
n -> p + e
Right of zone:
Proton rich
Tries to lose protons and gain neutrons
P + e -> n
Positron emission or electron capture
Just in zone but Z>83:
Decay by emitting α particle to try to achieve a more stable nucleus

Question 17

Odd even rule-

Answer 17

• When N/P both even numbers, isotopes tends to be far more stable than when they are both odd
• Of all 264 isotopes number of protons/ neutrons
• 168- even/even
• 57- even/odd
• 50- odd/even
• 4- odd/odd

Question 18

Radioactive decay

Answer 18

• Some nuclei can not obtain stability in just one transformation

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Question 19

Uranium decay series

Answer 19

• Uranium goes through 8 alpha decays and 6 beta decays before it reaches stability at lead
• All have very different half lives

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Question 20

Gamma decay

Answer 20

• Gamma rays are photons having very high energies
• The decay of a nucleus by the emission of a gamma rays s much like the emission of photons by excited electrons
• The gamma rays come from an excited nucleus that is trying to get back to its ground state
• The nucleus could be in an excited state either from a collision with another particle or because it is a nucleus left over from a previous radioactive decay

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Question 21

characteristics of alpha, beta and gamma radiations

Answer 21

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Question 22

Gamma decay

Answer 22

• A nucleus may remain in an excited state for some time before it emits a gamma ray. The nucleus is then said to be in a metastable state called an isomer
• The nucleus can also return to its ground state by a process called internal conversion where no gamma ray is emitted
• The nucleus interacts with an electron and loses its energy in that way
• The electron then loses the energy as an x-ray
• X-rays come from atom electron interactions while gamma rays come from nuclear processes

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Question 23

Conservation of nucleon number

Answer 23

• The following laws all hold true
• Laws of conservation of energy
• Law of conservation of linear momentum
• Law of conservation of angular momentum
• Conservation of electric charge
• Law of conservation of nucleon number
• The total number of nucleons stays the same in any decay, but the different types can change (protons into neutrons and vice versa)