2.2
radiation protection 1
1. Radiation Protection
2. MAXIMUM PERMISSIBLE DOSES
3. Radiation Exposure
INTRODUCTION
The history of
radiation exposure control is very
briefly outlined in this
lesson, and the main maximum permissible doses are
discussed.
2.2.1 THE HISTORY OF RADIATION EXPOSURE CONTROL
Man has always been
subjected to radiation,
both from outside and inside
his body. This RADIATION BACKGROUND, as we call it, arises
both from cosmic
rays from space and
from naturally occurring radioactive materials. For example, we know that radioactive carbon
and potassium atoms are found in the body itself (carbon-14
and potassium-40). These and
other radioactive substances occurring
in the earth's
surface (uranium, radium, thorium)
all contribute to
the radiation background.
The radiation dose
we receive from
this background depends on where
v/e live, what we
eat, the structural materials of our homes and
so on, but
a figure of
100 to 200 mrem per year is a reasonable
average in Canada. These radiations provide a
lower limit of exposure
which is unavoidable, and which
is not normally
considered significant.
However, following
the introduction of man-made
sources of radiation, the
harmful effects of an overdose were soon discovered as, for example, in
the experience of the early X-ray experimenters. It is
generally believed that the harmful effects of nuclear radiations are due
to their ionizing effects on the
tissues in the body. Although the biological consequences of
this will be considered in
a later section, it is sufficient here to
realize that ionizing radiation
does result in
damage to the body.
For
large doses of radiation, the damage may
range from a surface burn to some sort of effect deep in the
body. This kind of radiation damage is called SOMATIC damage. Radiation may also affect the reproductive
organs in such a way as to produce malformations in future generations; this is
called GENETIC damage.
Now it should be
pointed out that there are no biological effects that are uniquely caused by
radiation - all we can say is that radiation increases the probability or rate
at which these effects occur. Present
evidence seems to indicate that although the body may recover from the somatic
effects of small doses of radiation, it is probable that damage to the genetic
organs may not be repaired.
During the 1920's it
was well known that the amount of radiation received by an individual had to be
limited to prevent injury and various national organizations began to
study the problem and issue recommendations for the control of radiation
exposure. In 1928 an international
commission (then called The International X-ray and Radium Protection
Commission) was formed to consider this problem and to make recommendations
with regard to radiation protection.
In 1950 the Commission
was reorganized. The name was changed to
"The International Commission on Radiological Protection" -
universally known as the ICRP, The
Commission is composed of a chairman and not more than 12 members who are
chosen on the basis of their recognized expertise in radiation protection and
related fields, without regard to nationality.
The ICRP is widely recognized today as the chief authority on radiation
protection. Its policy with regard to
its recommendations is stated by the Commission as follows:
"The policy
adopted by the ICRP in preparing its recommendations is to deal with the basic
principles of radiation protection, and to leave to the various national
protection committees the right and the responsibility of introducing the
detailed technical regulations, recommendations, or codes of practice best suited
to the needs of the individual countries."
2.2.2 PERMISSIBLE DOSE
In
order to be able to enjoy the tremendous advantages of the proper use of
nuclear energy and other sources of radiation, we obviously cannot restrict
ourselves to no radiation exposure whatsoever - particularly since we cannot
avoid background radiation. While there
is no conclusive evidence that exposures above background are completely
harmless, evidence in the past 60 years does indicate that an individual
limited to PERMISSIBLE DOSES of radiation should not suffer any ill effects
from radiation, The ICRP's definition of
the Permissible Dose for an individual is:
"The PERMISSIBLE
DOSE for an individual is that dose, accumulated over a long period of
time or resulting from a single exposure, which, in the light of present
knowledge, carries a negligible probability of severe somatic or genetic
injuries; furthermore, it is such a dose that any effects that
ensue more frequently are limited to those of a minor nature that would not be
considered unacceptable by the exposed individual and by competent medical
authorities."
2.2.3 CRITICAL ORGANS AND TISSUES
All body tissues are
sensitive to ionizing radiation, but some are more RADIOSENSITIVE than
others. Furthermore, certain organs have
functions which are essential to the well-being of the entire body. When one considers the radiosensitivity of
organs with respect to their specific function, some tissues and organs assume
a greater importance, and they are said to be CRITICAL ORGANS.
In the case of more or
less uniform irradiation of the whole body, the blood-forming organs (red bone
marrow) and the gonads are the critical organs.
In the case of
irradiation more or less limited to parts of the body, the critical tissue or
organ is that part of the body most likely to be permanently damaged either
because of its inherent radiosensitivity, or because of a combination of
radiosensitivity and localized high dose.
2.2.4 DOSE RATE
Dose rate is the time
rate at which a dose is received, i.e. dose per unit time.
Dose
rates are expressed as rads or rems (or mrad, mrem) per unit of time (year,
week, hour, minute).
2.2.5 DOSE
LIMITS
THE ICRP
Even before the 1920's
it became well known that the radiation dose received by an individual had to
be limited to prevent injury. Various organizations began to study the problem
and issue recommendations for the control of radiation exposure. In 1928, an
international commission ( then called the International X-Ray and Radium
Protection Committee) was formed to make recommendations with regard to
radiation protection.
This Committee was
reorganized in 1950. The name was changed to the International Commission on
Radiological Protection - universally abbreviated to the ICRP. The ICRP is
widely recognized today as the chief authority in protection from the harmful
effects of ionizing radiation and has responsibility for presenting
recommendations on all aspects of this subject. These recommendations usually
are adopted without significant change by most countries and are incorporated
into their laws.
ICRP 26
The ICRP published an
important document in 1977. It is ICRP Publication 26, known as ICRP 26, and it
describes the ICRP system of dose limitation Given below are some of the
concepts that are described in detail in ICRP 26.
2.2.6 THE
OBJECTIVES OF RADIATION PROTECTION
The primary objective
of radiation protection is to protect individuals, their off-spring and mankind
as a whole, while still allowing necessary and beneficial activities involving
radiation exposure.
The biological effects
of radiation are classified as somatic and hereditary. ICRP 26 treats somatic
effect as STOCHASTIC or NON-STOCHASTIC. Stochastic means " arising
from chance; involving probability ". It is worth quoting from ICRP 26:
Stochastic ' effects
are those for which the probability of an effect occurring, rather than
its severity, is regarded as a function of dose, without threshold.
'Non - stochastic '
effects are those for which the severity of the effect varies with the dose, and for which a threshold may therefore occur.
For example, cancer is
a somatic effect that is stochastic. In other words, the probability of
contracting cancer increases with the dose, but once you get it, the severity
of the disease is the same no matter how big the dose was that caused it. We
assume that the relationship is linear, in other words, twice the dose means
twice the chance of getting cancer. Hereditary effects are also stochastic
effects. No threshold is assumed for stochastic effects.
In contrast to this,
cataract of the lens of the eye is a non-stochastic effect with a threshold
value of 7.5 Sv (750 Rein). As long as the dose is below 7.5 Sv (750 Rein),
radiation induced cataracts cannot form.,
To
illustrate, given below are a couple of practical examples of non-stochastic
and stochastic effects. Sunburn has a threshold; above this threshold exposure,
the degree of sunburn becomes more and more severe with increasing exposure to
the sun, and below the threshold no harm is done. Compare this with winning a
million rupees in a lottery; this is pure chance - the probability depends on
the exposure ( the number of tickets you buy), but the magnitude of the effect
doesn't change. You either win a million or you don't.
According to ICRP-26,
(he aim of radiation protection should be to prevent detrimental non-stochastic
effects and to limit the probability of stochastic effects to levels believed
to be acceptable.
This is a most
important objective. The non-stochastic effects can be prevented by setting
annual dose limited low enough so that no threshold dose would ever be reached
during a person's lifetime. The stochastic effects are limited by applying
annual dose limits which, if not exceeded, would ensure that the level of risk
from radiation work is no greater than the risk for other occupations which are
recognized as having high standards of safety.
The main features of the
ICRP recommendations > known
as SYSTEM OF ^t)OSE LIMITATION, are the following :
a) No practice shall be adopted unless its introduction produces a
positive net benefit.
This eliminates the "
frivolous " use of radiation. For example, in the 1950's, many shoe stores
would X-ray feet to see whether the new shoes fitted. This is no longer
permitted.
b) All exposure shall be kept as low as reasonably achievable,
economic and social factors being taken into account. This statement ( known as
the ALARA, (As Low As Reasonably Achievable ) principle ) implies that a value
judgement must be made on the economic and social cost of say, one man-mSv. The
important point is that all unnecessary radiation exposure should be avoided.
c) The dose equivalent to individuals shall not exceed the limits
recommended for appropriate circumstances by the Commission.
Like other national
practices, Pakistan Atomic Energy Commission has also been adopting the
recommendations of the ICRP.
the dose equivalent
limits
hi any organ or
tissue, the total dose due to occupational exposure consists of the dose
contributed by external sources (i.e., those outside the body) during working
hours and those contributed by internal sources (i.e., those inside the body)
taken into the body during working hours. The limits apply to this dose
received on the job - they do not apply to medical exposure or exposure to radiation
background.
Furthermore, the
limits presented here apply to Radiation Workers.
RADIATION WORKERS are
people who may be routinely exposed to radiation as a result of their
occupation.
At mentioned before,
the dose equivalent limits are intended to prevent non-stochastic effects and
to limit the occurrence of stochastic effects to an acceptable level.
2.2.7
SUMMARY OF CURRENT ANNUAL DOSE EQUIVALENT UMITS FOR RADIATION WORKERS
|
Organ or tissue
|
Dose quantity
|
Dose limits in mSv
|
|
Whole body
|
Effective dose equivalent
|
50 (5 rem)
|
|
Partial body
|
Committed effective dose
equivalent or effective dose equivalent from partial body exposure
|
50 (5 rem)
|
|
Individual organs and
tissues except the lens of the eye or the skin
|
Dose equivalent or
committed dose equivalent.
|
500 (50 rem)
|
|
The lens of the eye
|
Dose equivalent or
committed dose equivalent
|
150 (15 rem)
|
|
Skin averaged over any
area of 100cm2
|
Dose equivalent or
committed dose equivalent
|
500 (50 remO
|
|
Hands, face, amis, feet
and ankles.
|
Dose equivalent
|
500 (50 rem)
|
* Averaging over
an contamination; a smaller radiation beams area of
100 cm2 applies
to doses from
radioactive area should be used for averaging in case exposure is to
radiation beams.
3.1 RADIATION
PROTECTION 2
1. Radiation Protection
2. Radiation Exposure
3. PROTECTION AGAINST EXTERNAL EXPOSURE TIME, DECAY AND DISTANCE
INTRODUCTION
The fundamental aim of
Radiation Protection is to reduce exposures to the lowest practical level.
Protection against
radiation is concerned with two separate situations:
EXTERNAL RADIATION, which
arises from a source outside the body;
INTERNAL RADIATION, which
arises from a source inside the body.
FIG 3.1
The general biological
effects of ionizing radiation from external and internal sources are not very
different from one another. However, as
we progress it will become evident that the precautions taken against the one
hazard are of little use in protecting against the other, and that the
corresponding methods of estimating dose are different. Therefore external and
internal radiation are treated separately, and in this lesson we shall
consider three methods of controlling external exposure.
3.2 TIME; DECAY; DISTANCE; SHIELDING
Radiation exposure can
be decreased in any one of four ways:
1) By decreasing the length of TIME spent near a source.
2) By allowing the source to DECAY for some time before approaching
it.
3) By increasing the DISTANCE between yourself and the source.
4) By absorbing the radiation in SHIELDING material placed between
yourself and the source.
In this lesson we
shall discuss the first three methods; shielding will be left for the next
lesson.
3.2.1 TIME
Radiation exposure can
be controlled very simply by limiting the length of time a person spends in the
radiation area. For example, if the
radiation level in an area is 5 mR/h, then in 1 hour a worker receives an
exposure of 5 mR, in 2 hours 10 mR, and in 6 hours 30 mR. The dose he receives is therefore 5 mrem, 10
mrem and 30 mrem.
If you wish to limit
the dose received by a person to a certain value, and you know the radiation
dose rate, you may calculate the maximum length of time to be spent in the area
by using the formula:
Time
Limit =
Dose Rate
THE UNITS OF TIME MUST BE
THE SAME FOR THE DOSE RATE AND THE TIME LIMIT.
3.2.2 DECAY
A second way of
reducing exposure when working near a radioactive source is to allow the source
to decay to some extent before starting work.
The radiation dose rate will be decreased by a factor of 2 for every
half-life delay. This is a good approach when work has to be done in a radiation
area where the dose rate decreases very rapidly with time, say a half-life of
the order of minutes or even hours. If there is no need for the work to be done
immediately, then waiting a day or so would reduce the dose rate quite appreciably.
3.2.3DISTANCE
Increasing the
distance between a person and the source results in a marked reduction in the
radiation exposure. The diagram on the opposite page shows how this comes
about.
S is a point gamma
source which emits photons isotropically.
(This is an elegant way of saying "uniformly or equally in all
directions11.) If we stand at
A, we can count 7 gamma photons striking us every second, whereas if we move
out to B, only 3 photons strike us per second.
Thus, as we move away from the source, the gamma ray intensity
decreases. This is entirely due to the spreading out of the emitted photons.
FIG 3.2.3 (a)
The INVERSE SQUARE LAW
describes the decrease in the radiation intensity with distance:
The intensity of the
radiation varies inversely as the square of the distance from the source; that
is, doubling the distance drops the exposure rate to 1/4, tripling the distance
drops it to 1/9, and so on.
The decrease in
intensity predicted by the inverse square law is shown in the diagram below.
INTENSITY
DECREASES AS DISTANCE INCREASES
FIG 3.2.3 (b)
4.1 RADIATION PROTECTION 3
1. Radiation
Protection
3. Radiation Exposure
4. PROTECTION AGAINST EXTERNAL EXPOSURE
SHIELDING
INTRODUCTION
In some cases the only
practical way of reducing radiation exposures to an acceptable level is to
install shielding between the source and yourself. Radiation shielding is a very complex
subject, and therefore only a few elementary ideas are discussed. Some aspects of reactor shielding are
described.
4.2 ALPHA PARTICLE SHIELDING
You may recall from
lesson R.P.T. 1.2.2 that alpha particles have a relatively small penetrating
power - even in air the most energetic alpha particles don't have a range of
more than 10 cm; the dead layer of the skin will stop them completely. Because of this, alpha sources outside the
body do not present an external hazard and shielding against alpha particles is
therefore quite unnecessary.
However, alpha
particles with their QF of 10 are a very serious internal hazard and great care
must be exercised to ensure that alpha sources are not taken into the body.
4.3 BETA PARTICLE SHIELDING
Normally, at a nuclear
power station, radioactive materials are enclosed in systems which completely
shield the operators from the beta particles.
You will recall from lesson R.P.T. 1.2.2, page 7, that not very much
shielding is required to do this.
However, when radioactive
materials are released into the plant (e.g., Ar4l) , or when systems
are opened for maintenance (e.g., removal and maintenance of a primary pump),
the shielding is removed from around the beta sources. Then an external hazard can exist, because
beta particles have a considerable range in air depending on their
energies.
The most restrictive
critical organs for beta radiation are the skin (30 rem/year) and the lens of
the eye (15 rem per year). Serious
damage may be caused to both if the source is strong enough. The hazard to the eye lens which is already
shielded by the cornea may be further reduced by the routine wearing of safety
glasses.
Since beta particles
are easily absorbed, no one should receive an appreciable external dose
from beta ratiation if proper techniques are applied. Maximum beta energies,
E^x' vary widely but average about 1 MeV for mixtures of old fission products.
The percentage of incident 1 MeV beta radiation absorbed in some common
materials is given in the table below.
ABSORPTION OF BETA
RADIATION: E-max
= 1 MeV. Table 4.3
|
Type of Material
|
Thickness (inches)
|
Percent Absorption
|
|
Surgeons gloves
|
|
30
|
|
Cotton gloves
|
|
30
|
|
Neoprene gloves
|
|
50
|
|
Double neoprene gloves
|
|
70
|
|
Light coveralls
|
|
20
|
|
Plastic hood (PVC)
|
0.008
|
30
|
|
Safety glasses (lens)
|
0.14
|
90
|
|
Army respirator (lens)
|
0.14
|
90
|
|
Air
|
36
|
80
|
|
Plywood
|
0.25
|
100
|
|
Asbestos
|
0.125
|
90
|
|
Paper
|
0.125
|
90
|
Asbestos or heavy
paper is useful for draping over
contaminated equipment to reduce beta dose rate. About 1/8 inch of either material reduces the
dose rate by a factor of 10 for 1 MeV beta particles.
4.4 GAMMA RAY SHIELDING
We already know that
gamma rays will penetrate to great depths in materials and that no amount of
shielding will stop all of the radiation.
The effectiveness of gamma ray shielding is frequently described in
terms of the half-value layer (HVL), which is the thickness of absorber
required to rediice the gamma radiation to half its former intensity. But this you know already from lesson R.P.T.
1.2.2.
The first HVL reduces
the radiation to one-half. The second
HVL reduces the radiation by one-half again, i.e. ½ × ½ = ¼ of the original level. The radiation levels after successive HVL's
are:
Radiation after 1 HVL = 1/2
of the original
Radiation after 2
HVL's = 1/2 × 1/2 =
1/4 of the original
Radiation after 3
HVL's = (1/2)3 =
1/8 of the original
Radiation after 4
HVL's = (1/2)4 =
1/16 of the original
Radiation after 5
HVL's = (1/2)5 =
1/32 of the original
The above is strictly
applicable only to a narrow beam of radiation .
A source emits radiation in all directions, and then the reduction in
the intensity of the radiation with shielding is less than would be
expected. However, with small sources
the error is not too great and the method is useful for estimating the
shielding required for such sources .
The most effective
gamma shields are those which have both a high density and a high atomic
number, such as uranium, tungsten, gold, lead, etc. Generally speaking, these heavy materials
tend to be expensive - even lead isn't cheap - and therefore less costly,
medium-weight materials such as iron and concrete are often used.
Concrete is a good
structural material, but lead is not. Large lead shields require some sort of a
supporting frame. On the other hand, lead shields will be thinner than shields
made of less dense materials, and therefore lead is often used where space is
very limited.
Water may be used
where it is necessary to see the source 1 of radiation or to work through the
shield with long-handled tools. Used
nuclear fuel (called spent fuel) is usually stored in deep bays filled with
water. The water also absorbs the heat
being generated by the fuel elements. If
the water requires cooling it can be pumped through a heat exchanger.
On page 5 the KVL's of
various materials are shown for a range of gamma energies. The HVL’s are not constant for a
given material, because the relative probabilities of the three gamma
absorption processes vary with the gamma energy (see lesson R.P.T. 1.2.3, pages
4 to 6). In the range of energies of interest
to us, it is generally true to say that the HVL will increase with energy.
For gamma radiations
with energies in the range where Compton scattering is the predominant
absorption process, the is generally about the same, regardless of the material used. For instance, the HVL of iron for 1 MeV gamma
radiation is about 0.65" as compared to 1.3" for heavy concrete (220
Ib/cu ft). Since the iron is just about
twice as dense as heavy concrete, the total mass required for a shield will be
roughly the same for both materials.
4.5 NEUTRON SHIELDING
Fast neutrons must be
slowed down before they are readily captured.
Fast neutrons may be slowed down by two interactions :
1) Inelastic scattering of neutrons with heavy elements (especially
iron). This interaction predominates
for neutron energies greater than 1 MeV.
2) Elastic scattering with light nuclei such as hydrogen.
The resulting slower
neutrons cire captured by nuclei in the shielding in an (n,γ) reaction. Therefore gamma radiation will be produced
as a result of the capture process and additional shielding must be cidded to
absorb the gamma rays produced.
Water, paraffin,
masonite and polyethylene contain a high proportion of hydrogen and are
therefore effective in slowing down neutrons.
Ten inches of water or paraffin will reduce the fast neutron dose rate
by more than a factor of 10. Concrete
retains some water permanently, and is therefore very useful as a neutron absorber. For example, the HVL of ordinary concrete
(150 Ib/cu ft) for 10 MeV neutrons is only about 3 inches.
4.6 REACTOR SHIELDING
To protect personnel
from neutron and gamma radiation from the core, it is necessary to completely
surround the reactor with a thick shield.
This is usually called the BIOLOGICAL SHIELD or PRIMARY SHIELD, because
its main purpose is to protect people rather than equipment.
The radiation
intensity on the outside of the shield must be such that exposures to personnel
are well below the maximum permissible limits.
Concrete, which is suitable for neutron and gamma ray shielding, is
commonly used because of its low cost and good structural qualities. Most reactors require 7 or more feet of
concrete to reduce the field at the outside of the shield to 1 mrem/h or less.
If space is too
limited to permit the use of sufficient ordinary concrete, then special heavy
concrete can be used. Such concrete has incorporated into it steel punchings,
iron ore or other mineral ores to increase its density. A shield fabricated from heavy concrete will
then not need to be as thick as one fabricated from ordinary concrete.
The inner face of the
shield will heat up because it absorbs a great deal of energy. If the shield requires cooling, water pipes are
embedded in the concrete near the inner surface where most of die heat is
generated.
Part of the NPD
shielding is shown in the diagram on page 7 to illustrate some of the problems
encountered in reactor shielding. The
reactor itself is housed in the reactor vault, whose roof, floor and walls
constitute the primary shield. There are
three types of area near the reactor zone:
1) Areas which may never be entered are said to be .inaccessible at
all times The reactor vault and the dump pipe room are the only rooms which are
never accessible.
2) Areas which are accessible at all times; that is, they may be
entered even during reactor operation.
These areas must be heavily shielded from the reactor, since the
radiation levels from the core are much higher while the reactor is
operating. In NPD, 7 feet of concrete
with a density of 220 Ib per cubic foot are sufficient to reduce the radiation
level to 1 mrem/h or less during reactor operation.
Areas which are
inaccessible during reactor operation.
The reactor, at full
power, is a source of gamma rays with energies up to 10 MeV and neutrons with
energies up to 15 MeV. When the reactor
is shut down,
FIG 4.6
on the other hand, only
gamma rays - emitted by fission products and activation products - with
energies up to about 2.5 MeV need be considered. Therefore, for areas only accessible during
reactor shutdown substantially thinner shielding is quite adequate. Such areas usually contain radiation sources
of their own during reactor operation
(e.g., short-lived activation products) and wouldn't then be accessible
anyway, even if they were fully shielded.
Here the use of thinner shields will save both space and cost.
An example of an area
which is inaccessible during reactor operation is the boiler room. It is accessible only during reactor
shutdown. The boiler room in NPD
requires only 4% feet of 220 Ib/ft3 concrete shielding to
reduce the radiation levels from the reactor to 7 mrem/h one minute after it is
shut down. Since the initial fission
product decay is very rapid , these levels of course soon drop below 7
mrem/h. (The fields actually measured in
the boiler room are much higher, because of the residual contribution from
activation products in the systems located there.)
The clue as to why the
boiler room is inaccessible; during reactor
operation is that this room
contains the primary heat transport and moderator equipment. The heavy water in both systems
passes through the reactor core and will become radioactive by neutron
activation during reactor operation.
Most of the gamma activity is clue to nitrogen-16, which is produced by
the (n,p) reaction in oxygen- 16:
0n1 + 8O16 → 7N16
+ 1P1
Nitrogen-16 emits
Jilgh energy gamma rays (6-7 MeV) and has a half-life of 7.4 seconds. Therefore the items of equipment which
contain this heavy water are high
radiation sources during
reactor operation, and cause a gamma radiation field of several R/h. The boiler room itself is shielded to protect
adjacent areas from this radiation field.
After the reactor is
shut down, no more N16 is formed and the Nl6 already
there decays very rapidly, so that the boiler room may soon be entered under
normal conditions.
5.1 RADIATION
PROTECTION 4
1. Radiation Protection
3. Radiation Exposure
5.1 RADIATION
PROTECTION 4
1. Radiation Protection 3. Radiation Exposure 5. INTERNAL RADIATION
INTRODUCTION
Radionuclides will be
potentially much more harmful when they have been taken into the body to become
INTERNAL SOURCES than they would have been outside the body. Therefore, one of the primary and also one of
the most difficult objectives of radiation protection is to minimize or prevent
the intake of radioactive materials into the body. In this lesson we will consider some of the
problems experienced with internal radiation.
5.2 INTERNAL RADIATION HAZARDS
Among the first people
to suffer injury and death from the effects of internal sources were the radium
dial painters They were employed in a factory during the 1920fs
applying radium-containing paint to instrument dials. Many of these workers later suffered from
anemia and bone injury. Investigations
showed that they used to point their brushes between their lips after dipping
them in the radioactive paint. In this
way relatively large quantities of radium entered their gastrointestinal
tracts, some was absorbed into their bodies, the majority of this being
deposited in their bones. After death it
was shown that some of their skeletons contained many micrograms of radium.
When dealing with
external exposure the protection problem is relatively straight forward;
usually the radiation level can easily be measured with an instrument, and if
desired the exposure can be terminated at any time. However, the hazard presented by internal
sources is much more difficult to cope with for the following reasons:
1) Internal sources irradiate the body tissues 24 hours a day, seven
days a week, until they have been eliminated from the body by excretion and
decay.
2) Many radionuclides remain in the body for years, and in many cases
it is difficult if not impossible to increase their rate of elimination from
the body.
3) It is difficult to determine the quantity and the distribution of
many of the radionuclides when they are contained in the body, and therefore
the dose rate frequently cannot be accurately assessed.
4) The decaying rcidioactive atoms emit particles within the
tissue. Thus alpha and low energy beta
particles which are not sufficiently penetrating to be an external hazard are a
very serious internal hazard. They
dissipate all of their energy in a very small volume of tissue. Gamma emitters taken internally are of course
a hazard too, but the damage is not so concentrated. In any case, only a fraction of the gamma
photon energies are absorbed before the photons leave the body.
5) Some radionuclides are concentrated chemically in certain organs
of the body, thus increasing the probability of injury to these organs.
5.3 ENTRY OF RADIONUCLIDES INTO THE BODY
Radioactive materials
may occur in many physical or chemical forms just as other materials do. They may appear as solids, powders, dusts,
liquids, gases, vapours or solutions.
Internal contamination can result from the careless handling of such
radioactive material. It may enter the
body in four different ways:
1) Inhalation (breathing it),
2) Ingestion (eating it), Absorption through the unbroken skin,
3) Absorption through wounds.
In the nuclear power
industry inhalation is generally considered to be the most likely route of
entry of toxic materials into the body.
Ingestion is the second most likely. Inhaled material cleared from the
lungs often enters the gastrointestinal tract and then a secondary ingestion
type of exposure occurs.
The amount of a
radionuclide taken up by the body depends on the magnitude of the intake,
solubility (which in turn depends on the particular chemical form of the
radionuclide), and whether the intake is via inhalation, ingestion or absorption.
Inhalation - A portion
of insoluble dust which is inhaled is retained for some time in the respiratory
tract and irradiates the lung tissues.
The rest is exhaled or swallowed. In the case of soluble substances
which are inhaled, a high percentage of that taken into the lungs
passes rapidly from the lungs into the blood stream.
Ingestion - Although ingested insoluble material is
mostly eliminated from the body in the faeces, the main hazard is the dose it
delivers to the gastrointestinal tract during its passage. Ingested soluble
material is largely absorbed into the blood stream.
Absorption -
Radioactive materials absorbed through the
skin or through a wound
also enter the blood stream. The latter can obviously be a route of rapid
entry.
To summarize the
above, soluble materials which are inhaled and ingested go largely to the blood
stream, while insoluble materials irradiate the respiratory tract or the
gastrointestinal tract while they are present.
5.4 DISTRIBUTION OF RADIONUCLIDES IN THE BODY
A large percentage of
radionuclides which have entered the body are eliminated in the first few
days. However, a portion will be
absorbed in various organs depending on the type of radionuclide. The body deals with elements and compounds on
a chemical basis. For example, normal
inactive iodine (I127) concentrates in the thyroid gland. If radio-afetive Il31 is
present as well, the body cannot differentiate between the two isotopes which
are chemically identical, and the active I131 also concentrates in
the thyroid.
Some elements are so
closely related chemically that the body cannot always effectively
differentiate between two different elements.
For example, chemists say that calcium, strontium, barium and radium are
in the same group (all have 2 electrons in their outer orbit). Calcium present in the body is largely
deposited in the bone, and any radioisotopes of strontium, barium and radium
which enter the body will therefore also collect to a considerable extent in
the bone. Such radioisotopes (called BONE-SEEKERS) are excreted at a very slow
rate once they have been deposited in the bone. If their radioactive half-life
is long, they may therefore irradiate the sensitive bone marrow, as well as the
bone, for many years.
5.6 elimination of
radionuclides from the body
In addition to the
tendency for a particular element to be taken up by a particular organ or
tissue, the main consideration in determining the hazard of a given
radioisotope inside the body is the total radiation dose delivered to the
critical organ while it is in the body.
The most important factors determining this dose are
1) The mass of radioactive material deposited,
2) The nature and energy of the radiations emitted,
3) The length of time it is effective in the body.
This time depends on
two factors: one is the ordinary radioactive half-life and the other is the
5.7 BIOLOGICAL HALF-LIFE.
The BIOLOGICAL
HALF-LIFE is the time taken for the amount of a particular element in the body
to decrease to half its initial value due to elimination by natural
(biological) processes alone.
The biological
half-life depends on the rate at which the body normally uses a particular
compound of an element. Combination of
the radioactive half-life and the biological half-life gives rise to the
EFFECTIVE HALF-LIFE.
The EFFECTIVE
HALF-LIFE is the time taken for the amount of a specified radionuclide in the
body to decrease to half its initial value as a result of both radioactive
decay and natural elimination.
The effective
half-life, Te, is given by the equation
Where Tr and Tb
are the radioactive and biological half lives respectively.
Serious internal
hazards are presented by those radio-nuclides which have long effective
half-lives, such as Ra226 and Pu239 with45 and 200 years
respectively. Once deposited in the
bones they remain there essentially unchanged in amount, during the lifetime of
the individual. The continued action of the
emitted alpha particles, which deposit their energy in a limited region, over a
period of years can cause significant injury.
This was the case with the radium dial painters .
A similar situation
exists for the beta-emitting bone-seeker Sr^O, one of the more common fission
products. It has '^radioactive half-life
of 28 years and a biological half-life estimated to be about 50 years. Its effective half-life, Te, is
then given by
This long effective
half-life of 18 years, coupled with the fact that it is a bone-seeker, makes Sr90 one of the most hazardous of fission
products.
5.8THE PHYSICAL FORM OF SOME COMMON INTERNAL
CONTAMINANTS
Dusts:
Many of the fission
products and activation products which, are encountered as air contaminants in a reactor are present as dust. The radionuclides are often collected on
small dust particles of other materials, and these particles floating about in
the air act as carriers for the radioactivity, which may then be inhaled. If the dust is collected u0n a filter paper,
so is the radioactivity.
Gases:
The radioisotopes of
the rare gases are of course present as gases.
Some of these are argon-41, xenon-133, xenon-135 and krypton-88. The rare gases are chemically inert, which means
they will not combine with other elements. Fortunately the body has no use for
these elements, and therefore they do not tend to become concentrated in the
body. The rare gases are considered to
be an external radiation hazard (i.e. exposure to a cloud of radioactive gas)
rather than an internal one. However,
this is not so for any radioactive daughters they may produce. Rubidium-88, formed by the beta decay of
krypton-88, is collected on dust particles and can present an internal hazard.
Vapour:
The radioiodines are
usually present in the form of vapours, although a part of the iodine may be
absorbed on dust. These radionuclides
are readily absorbed by the body and are concentrated in one specific organ,
namely the thyroid. The rare gases and
the iodines are the radioele-ments which escape most readily from defective
fuel elements.
Tritium vapour is an
internal radiation hazard of considerable importance in heavy water
reactors. For this reason the next but
one lesson is devoted entirely to tritium and therefore we need say no
more about it here.
