Radioactivity

Question 1

Atomic number Z

Answer 1

number of protons

Question 2

Atomic mass # (A)

Answer 2

number of nucleons

Question 3

neutron to proton ratio

Answer 3

• At close distances, a nuclear force between the nucleons holds the nucleus together
• Greater need for neutrons to interact with more protons
• most of the first 20 elements have a 1:1 ratio

Question 4

how to calculate # of neutrons?

Answer 4

number of nucleons - number of protons

Question 5

neutron to proton ratio past the first 20 elements

Answer 5

the number of neutrons exceeds the number of protons

Question 6

why are neutrons present?

Answer 6

Positively charged protons would repel each other without the right number of neutrons present

Question 7

Radioactivity

Answer 7

• unstable nuclei disintegrate to achieve the ideal balance of neutrons to protons
• emits radiation and/or fast-moving particles
• nuclear process
• not possible to control the rate of radioactive breakdown of a nuclide
• parent radionuclide disintegrates -> daughter product (stable or unstable)

Question 8

isotope

Answer 8

atom with the same number of protons but a different number of neutrons
- naturally occurring or man made

Question 9

radioisotope

Answer 9

an unstable isotope
- aka radionuclide, radioactive nuclides, radioactive isotopes

Question 10

nuclear belt of stability

Answer 10

• non-radioactive isotopes
• belt of stability ends at element 83 (bismuth)
• all elements with 84 or more protons are radioactive

Question 11

understand slide 11 digram

Answer 11

blue dots and red line

Question 12

what is the law of conservation of matter?

Answer 12

matter is never created or destroyed
- in a nuclear reaction all the protons and neutrons in a nucleus must be accounted for

Question 13

Format of a reaction

Answer 13

X -> R+Y
X - reactants
R and Y - products
-> chemical change occurred

Question 13

radioactive decay

Answer 13

• unstable nucleus loses energy through radiation to achieve stability
• type depends largely on how its n:p compares with those of nearby nuclei that lie within the belt of stability
• Alpha decay, Beta decay and/or Gamma decay

Question 14

alpha particle decay/emission

Answer 14

• heavy nuclei
• unstable nuclide
• nucleus is too large (high atomic mass) to balance forces

Question 15

what is an alpha particle (mass and make up)?

Answer 15

2 protons and 2 neutrons, atomic mass 4

Question 16

alpha particle emission solves instability by…..

Answer 16

• release alpha particles to lose atomic mass
• moves nucleus diagonally towards the belt of stability

Question 17

properties of an alpha particle

Answer 17

• heaviest of particle emissions
• positive electric charge
• highly ionizing
• very short range

Question 18

how far can an alpha particle travel in air?

Answer 18

1-10cm

Question 19

how far can an alpha particle travel in soft tissue?

Answer 19

0.1mm

Question 20

what is the decay scheme?

Answer 20

• energy diagram depicting decay
• graphical representation of all the transitions occurring in the decay of a radioactive substance
• height of the horizontal lines represents the different nuclear energy states
• changes in proton numbers are represented by a horizontal displacement

Question 21

beta particle emission

Answer 21

• neutron rich nuclei
• atomic number 0
• decrease neutrons by 1 increase protons by 1
  solves high n:p ratios by decreases the ratio

Question 22

Beta particle properties

Answer 22

• identical to an electron (same mass and charge)
• negative electric charge
• ionizing
• short range (3mm in soft tissue, stopped by a layer of Al a few mm thick)

Question 23

positive beta particle/positron emission

Answer 23

• proton rich nuclei
  solves the problem of: too many protons and a n:p that is too low

Question 24

what solutions does positron emission provide?

Answer 24

need to give off radiation that reduces number of protons or repulsion force or increases the number of neutrons

Question 25

positron particle properties

Answer 25

- positive electric charge - ionizing - combines with negative electrons and disappears in an annihalation radiation

Question 26

if n:z ratio is too high

Answer 26

neutrons are converted to protons via beta decay

Question 27

if n:z ratio is too low

Answer 27

protons are converted to neutrons via positron emission

Question 28

if amu is too high

Answer 28

alpha decay - change to both neutrons and protons

Question 29

isomeric reaction

Answer 29

- nucleus may be excited following the emission of a beta or alpha particle - excited nuclei release energy without changing number of protons or neutrons (typically gamma rays) - ranges from instantaneous to years

Question 30

gamma radiation emission

Answer 30

0,0 y - does not effect the n:z ratio - releases excess energy from nucleus

Question 31

properties of gamma radiation

Answer 31

- no charge and no mass - ionizing - highly penetrating - radioactive cobalt used in radiotherapy - requires several mm of Pb to produce significant attenuation

Question 32

what is a metastable state?

Answer 32

too much energy

Question 33

isomeric transition

Answer 33

metastable state element -> gamma photon + stable state element

Question 34

Deposition of radiant energy

Answer 34

- the amount of radiation deposited in matter is expressed in terms of the absorbed dose, measured in gray (gy) - absorbed dose = energy absorbed per unit mass of tissue - consider spatial distribution of the ionizing event

Question 35

equivalent dose

Answer 35

absorbed dose * radiation weighting factor

Question 36

effective dose

Answer 36

equivalent dose * tissue weighting factor

Question 37

penetrating ability or linear energy transfer

Answer 37

- average energy deposited per unit path length along the track of an ionizing particle - keV/um

Question 38

what does LET depend on?

Answer 38

- nature of radiation - material traversed

Question 39

high LET radiation

Answer 39

3-200keV/um - alpha particles - protons - neutrons greater density of interactions at cellular level more likely to produce biological damage in tissue

Question 40

Lower LET radiation

Answer 40

0.2-3 keV/um - electrons - positrons - gamma rays - x-rays less likely than high LET to produce tissue damage in the same volume of tissue

Question 41

what is radioactive half life?

Answer 41

- time required for one half if the sample to decay - decay is exponential

Question 42

if you start off with 50g of Cs which has a HL of 14 years, how much Cs will be present 42 years later?

Answer 42

6.25 g

Question 43

what is the number of radioactive decays per second?

Answer 43

Activity (A)

Question 44

SI unit for radioactive activity

Answer 44

Becquerel (Bq) - one transformation/decay per second

Question 45

activity depends on?

Answer 45

- amount of substance - half life

Question 46

how does the amount of substance affect activity?

Answer 46

- higher mass = greater number of nuclei = more activity - mass and activity are directly proportional

Question 47

how does half life affect activity?

Answer 47

- longer the half life, lower the activity - half life and activity are inversely proporitonal

Question 48

decay equation

Answer 48

decay constant (⋋) = # of atoms breaking down per second/total number of atoms - the rate at which a radionuclide decays

Question 49

what is the relationship between decay constant and each nucleotide

Answer 49

- fixed characteristic value for each radionuclide

Question 50

half lives in medical imaging

Answer 50

Isotopes with short half lives are useful for several reasons: - Cheaper to manufacture - The patients and staff receive less radiation dose because the activity reduces more quickly - Post-treatment/investigation activity is low

Question 51

therapeutic uses of radioactivity in medicine

Answer 51

- Sources of ionizing radiation applied to malignant tissue to prevent or reduce cell division - Administered internally (injection or ingestion) or externally (external beam therapy)

Question 52

diagnostic uses of radioactivity in physiological studies

Answer 52

a chemical labelled with a radionuclide is injected/ingested and its uptake by an organ or system is monitored to determine function

Question 53

diagnostic uses of radioactivity in blood volume studies

Answer 53

total volume of blood can be estimated by measuring its diluting effect on a known amount of radionuclide

Question 54

diagnostic uses of radioactivity in imaging studies

Answer 54

a radionuclide is introduced in the body and a measurement of the spatial distribution in an organ or system creates an image