Post on 21-Jul-2020
DR. MOHAMMED MOSTAFA EMAM
INAYA MEDICAL COLLEGE
(IMC)RAD 243- LECTURE 28OCT2015
Units and Measurement of Radiation
Radioactive Decay Law
• This law is given by:
Nt = No . exp (-λt)
whereNo = initial number of radioactive nuclei
Nt = number of radioactive nuclei at time tλ = decay constant (s-1)
• It tells us that the number of radioactive nucleiwill decrease in an exponential fashion withtime with the rate of decrease being controlledby the Decay Constant.
• The decay constant depends on nothing but the nuclear properties.
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Half-Life
• Half Life is an indicator that expresses
the length of time it takes for the radioactivity
of a radioisotope to decrease by a factor of two.
• Some of the radioisotopes have a relatively
short half life.
• These tend to be the ones used for medical
diagnostic purposes because they do not
remain radioactive for very long following
administration to a patient and hence result
in a relatively low radiation dose.
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Logistic Problems with Radioisotope
Handling
• Short half lives (e.g. 99mTc):
Transportation over long distances
• Long half lives (e.g. 226Ra):
Safe storage for a long period of time
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Relationship between Decay Constant
and Half Life
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1
6930
t
.
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Units of Radioactivity
• SI (metric) unit (Becquerel, Bq):
The Becquerel is defined as the quantity of
radioactive substance that gives rise to a
decay rate of 1 decay per second.
• Traditional unit (curie, Ci):
1 Ci = 37 GBq
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Weight of a Given
Radioactivity• Let
• A = activity (in Bq)
• λ = decay constant (s-1)
• L = Avogadro’s number (6.23×1023)
• M = molecular (atomic) weight
• The weight corresponding to the given
radioactivity is calculated from:
L
AMW
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Typical Radiation System
• The quantities which can be measured in a
radiation system are usually associated with
• the source
• the radiation beam
• the absorber
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The Radiation Source
• When the radiation source:
• is radioactive the quantity that is
typically measured.
• is the radioactivity of the source
measured in Becquerel's or in curies.
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The Radiation Beam
• The characteristic of a radiation beam
that is typically measured is called the
Radiation Exposure.
• This quantity expresses how much
ionization the beam causes in the air
through which it travels.
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The Radiation Beam
• The SI unit of radiation exposure is the
coulomb per kilogram (C∙kg-1).
• It is defined as the quantity of X- or γ-
rays such that the associated
electrons emitted per kilogram of air at
standard temperature and pressure
(STP) produce ions carrying 1 C of
electric charge.
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The Radiation Beam
• The traditional unit of radiation exposure is
the roentgen, and is given the symbol R. It is
defined as the quantity of X- or γ-rays such
that the associated electrons emitted per
kilogram of air at STP produce ions carrying
2.58 x 10-4 C of electric charge.
• Often it is not simply the exposure that is of
interest but the exposure rate, i.e., exposure
per unit time. The units which tend to be
used in this case are the C∙kg-1s-1and the
R∙h-112
The Absorber
• Energy is deposited in the absorber
when radiation interacts with it.
• It is usually quite a small amount of
energy but energy nonetheless.
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The Absorber
• The quantity that is measured is called
the Absorbed Dose and it is of
relevance to all types of radiation be
they X- or γ-rays, α- or β-particles.
• The SI unit of absorbed dose is called
the gray (Gy). The gray is defined as the
absorption of 1 J of radiation energy per
kilogram of material (J∙kg-1).
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The Absorber
• The traditional unit of absorbed dose is
called the rad, which supposedly stands
for Radiation Absorbed Dose.
• It is defined as the absorption of 10-2 J
of radiation energy per kilogram of
material.
• 1 Gy = 100 rad
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Equivalent Dose
• Often the effectiveness with which different
types of radiation produce a particular chemical
or biological effect varies with a Quality factor
that is characteristic of the type of radiation.
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Equivalent Dose
• The dose-equivalent (DE) in sievert (Sv) is the
product of the dose in Gy and that quality factor.
• The dose-equivalent (DE) in rem is the product of
the dose in rad and that quality factor.
• Recently, the newly defined radiation weightingfactors, WR have been adopted to represent the
Quality factor.
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Radiation Weighting Factors
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Inverse Square Law• The radiation produced in a radioactive source is emitted in all
directions.
• We can consider that spheres of equal radiation intensity exist around the source with the same number of photons/particles spreading out as we move away from the source.
• Consider an area on the surface of one of these spheres and assume that there are a certain number of photons/particles passing though it.
• If we now consider a sphere at a greater distance from the source the same number of photons/particles will now be spread out over a bigger area.
• Following this line of thought it is easy to appreciate that the radiation intensity will decrease with the square of the distance from the source.
• This effect is known as the Inverse Square Law.
• As a result if we double the distance from a source, we reduce the intensity by a factor of two squared, that is 4. If we treble the distance the intensity is reduced by a factor of 9, that is three squared, and so on.
• This is a very useful piece of information if you are working with a source of radiation and are interested in minimizing the dose of radiation you will receive.
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Interaction of Radiation with
Matter
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Physical Characteristics of the
Major Types of Radiation
One of the main effects to be noticed irrespective of the typeof radiation is that ions are produced when radiationinteracts with matter.It is for this reason that it is called ionizing radiation.
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Alpha Particles• α-particles have a double positive charge and therefore they
will exert considerable electrostatic attraction on the outerorbital electrons of atoms near which they pass.
• The result is that some electrons will be attracted away fromtheir parent atoms and that ions will be produced.
• α-particles are quite massive relative to the other types ofradiation and also to the electrons of atoms of the materialthrough which they are passing. As a result they travel instraight lines through matter except for rare direct collisionswith nuclei of atoms along their path.
• The energy with which α-particles are emitted is alwaysdistinct. For example 221Ra emits an α-particle with an energyof 6.71 MeV. Every α-particle emitted from this radionuclidehas this energy.
• α-particles are very damaging biologically, and this is onereason why they are not used for in-vivo diagnostic studies.
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Beta Particles• β-particles have a negative electric charge (positrons
are not considered here since these particles do notlast for very long in matter before they are annihilated).
• Because of their negative charge they are attracted bynuclei and repelled by electron clouds as they passthrough matter. The result is ionization.
• The path of β-particles in matter is often described asbeing not straight-forward, since they tend to reboundfrom atom to atom.
• The energy of β-particles is never found to be distinctin contrast to the alpha-particles above. The energies ofthe β-particles from a radioactive source forms aspectrum up to a maximum energy.
• β-particles are quite damaging biologically and this isone reason why they are not used for in-vivo diagnosticstudies.
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Spectrum of Beta Radiation
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Gamma Rays• The energies of γ-rays emitted from a radioactive
source are always distinct. For example:• 99mTc (Technetium 99m) emits γ-rays which have an
energy of 140 keV.
• 51Cr (Chromium-51) emits γ-rays which have an energy of 320 keV.
• γ-rays have many modes of interaction with matter.
• Those which are very important to nuclear medicine imaging are • the Photoelectric Effect
• the Compton Effect
• The effects described here are also of relevance to the interaction of X-rays with matter since as we have noted before X-rays and γ-rays are essentially the same entities.
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Photoelectric Effect• When a γ-ray collides with an orbital electron of an
atom of the material through which it is passing it can transfer all its energy to the electron and thus cease to exist.
• On the basis of the Principle of Conservation of Energy we can deduce that the electron will leave the atom with a kinetic energy given by:
kinetic energy = energy of the γ-ray - orbital binding energy
• The resulting electron is called a photoelectron.
• The following phenomena are of importance:• An ion results when the photoelectron leaves the atom.
• The γ-ray energy is totally absorbed in the process.
• X-ray emission can occur when the vacancy left by thephotoelectron is filled by an electron from an outer shellof the atom (electron capture).
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Photoelectric Effect
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Compton Effect (Scattering)
• Here a γ-ray transfers only part of its energy
to a valance electron which is almost free.
• The electron leaves the atom and may act
like a β-particle
• The γ-ray deflects off in a different direction
to that with which it approached the atom.
• This deflected or scattered γ-ray can
undergo further Compton scatterings within
the material.
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Compton Scattering
Fig. 929
Attenuation of Gamma-Rays
• The photoelectric and the Compton effects
give rise to both absorption and scattering
of the radiation beam.
• The overall effect is referred to as
attenuation of γ-rays.
• Remember: γ-rays and X-rays are
essentially the same physical entities.
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Specific Gamma Ray
Constant (G)• It is defined as the exposure rate per unit
activity at a certain distance from a source.
• SI units:
C∙kg-1∙s-1∙Bq-1 (at 1 m)
• Traditional units:
R∙h-1∙mCi-1 (at 1 cm)
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Specific Gamma Ray Constant G(mSv∙h-1∙GBq-1 at 1 m)
γ-Ray ConstantNuclide
0.004241Am
0.012201Tl
0.01657Co
0.01799mTc
0.04199Mo
0.057131I
0.084111In
0.087137Cs
0.36060Co 32
Specific Gamma Ray Constant and Dose
• Given that an object at distance (d) m
away from the source, and that the source
activity is (A) Bq, one can compute the
dose (D) in Sv/h as follows:
2d
AGD
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Attenuation Model
Io = incident intensityIx = transmitted intensityΔI = absorbed intensity = Io - Ix
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Effect of Atomic Number• The magnitude of ∆I is highly dependent on
the atomic number of the absorbing material.
• For example ∆I is quite low in the case of anabsorber made from carbon (Z=6) and verylarge in the case of lead (Z=82).
• Reason:• The atoms of the high atomic number absorber
present larger targets for the radiation to strikeand hence the chances for interactions via thePhotoelectric and Compton Effects is relativelyhigh. The attenuation should therefore berelatively large.
• In the case of the low atomic number absorber, however, the individual atoms are smaller and hence the chances of interactions are reduced.
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Effect of Atomic Number
It is found that:ΔI = k∙Z3 (where k is a constant)
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Effect of Density• A low density absorber will give rise to
less attenuation than a high density
absorber since the chances of an
interaction between the radiation and the
atoms of the absorber are relatively lower.
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Effect of Thickness
• A thick absorber a greater attenuation than
a thin one.
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Effect of Gamma-Ray Energy
• The greater the energy of the γ-rays the less
the attenuation.
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Mathematical Model of
Attenuation• Ix and Io are related by:
• This final expression tells us that the radiationintensity will decrease in an exponential fashionwith the thickness of the absorber with the rate ofdecrease being controlled by the Linear AttenuationCoefficient (μ).
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Linear Attenuation Coefficient• μ is characteristic of individual absorbing materials.
• Some materials like carbon have a small value and are
easily penetrated by γ-rays.
• Other materials such as lead have a relatively large μ and
are relatively good absorbers of radiation.
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Influence of the Linear
Attenuation Coefficient
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Half Value Layer
• An indicator is usually derived from theexponential attenuation equation which helpsus think more clearly about what is going on.
• This indicator is called the Half Value Layer,and it expresses the thickness of absorbingmaterial which is needed to reduce the incidentradiation intensity by a factor of two.
• We can say that when:
• the thickness of absorber is the Half ValueLayer. 43
Relationship between the Linear
Attenuation Coefficient and the
Half Value Layer
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Mass Attenuation Coefficient• the Linear Attenuation Coefficient is useful
when we are considering an absorbingmaterial of the same density but of differentthicknesses.
• A related coefficient can be of value when wewish to include the density, ρ, of the absorberin our analysis.
• This is the Mass Attenuation Coefficientwhich is defined as
• It is usually measured in cm2g-1.
density
tcoefficien nattenuatio linearmass
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