Radiation Protection Course PDF

Summary

These lecture notes offer an overview of radiation protection, discussing various types of radiation like alpha, beta, gamma, and X-rays, along with their properties and interactions with matter. Information about neutron radiation is also included.

Full Transcript

Common Radiation

Transmission of energy via:

Particles or Waves
 Radiation Protection Course
Atomic structure of helium

Helium’s sub-atomic composition
- +
2 protons
2 neutrons
+ 2 electrons
-

The helium atom
 Radiation Protection Course

Atomic structure of helium
Protons have a large mass and
a positive charge. The number
total number of + of protons identifies an
protons and neutrons element.
MASS NUMBER
4 Neutrons have a large mass

He
approximately equal to a
ELEMENT proton’s mass. Neutrons have
no charge.
SYMBOL

ATOMIC NUMBER
2 -
Electrons have a very small
mass and a negative charge.
Electrons travel outside the
nucleus.
number of protons
 Radiation Protection Course

Alpha radiation

α
This type of radiation does not consists of photons but rather, particles. More specifically He 2+ particles,
i.e. Helium nuclei.

Alpha particles, also called alpha rays or alpha radiation, consist of two protons and
two neutrons bound together into a particle identical to a helium -4 nucleus. They are
generally produced in the process of alpha decay, but may also be produced in other
ways. Alpha particles are named after the first letter in the Greek alphabet , α. The
symbol for the alpha particle is α or α2+. Because they are identical to helium nuclei, they
are also sometimes written as He2+ or 4
2He
2+

indicating a helium ion with a +2 charge (missing its two electrons). Once
the ions gains electrons from its environment, the alpha particle becomes a normal
(electrically neutral) helium atom 42He.
 Radiation Protection Course

β
Beta radiation
This consists of a stream of electrons or positrons

A beta particle, also called beta ray or beta radiation (symbol β), is a
high-energy, high-speed electron or positron emitted by the radioactive
decay of an atomic nucleus during the process of beta decay.There are
two forms of beta decay, β− decay and β+ decay.
Gamma radiation
Photons with higher energy than x-rays. Gamma, or γ-radiation is electromagnetic radiation of high
frequency (very short wavelength). It consists of frequencies above 10 exahertz (or >1019Hz), and
therefore have energies above 100 keV and wavelength less than 10 picometers, less than the diameter of
an atom.

γ
 Radiation Protection Course

X-Rays
These are photons with low X-RAY TUBE
HOUSING
energy, in the range 120 eV to 120 (ASSEMBLY)
HIGH
VOLTAGE
keV. They Have a shorter CABLES

wavelength than UV rays and
longer than gamma rays. X-
radiation is also called Röntgen
radiation. Named after Wilhelm
Conrad Roentgen, the discoverer
of its existence, and the man who
named it X-radiation. The "X" COLLIMATOR
standing for an unknown type of
radiation.
 Radiation Protection Course

X-Ray Production
The higher the atomic number of the X-ray target,
the higher the yield.
The higher the incident electron energy, the higher
the probability of X-ray production.
At any electron energy, the probability of generating
X-rays decreases with increasing X-ray energy.

electrons
Low to High
medium > 1MeV
energy target energy
(10-400keV)

X-rays
 Radiation Protection Course
Neutron radiation
This consists of a neutron stream (free neutrons). The stream of
free neutrons reacts with nuclei of other atoms forming new
isotopes resulting in a chain reaction. Nuclear fission or fusion,
consists of the release of free neutrons from atoms in the first
place. The chain reaction makes radiation this dangerous and
harmful over great areas of space.
Neutron Fission Fragment

Energy
Parent Atom

Neutron

Energy
Neutron Fission Fragment
 Radiation Protection Course

Neutron Properties Composition: two down quarks and one up quark
Rest Mass: 1.0086649 amu
Uses of Neutrons Energy equivalent: 939.5656 MeV
Electric charge: 0
❑ Reactor start up
❑ Density gauges Half-life: 10.4 minutes (outside the nucleus)
❑ Moisture gauges Decay scheme:
❑ Well logging
❑ Activation analysis
❑ Gemstone colorization neutron proton + beta +
❑ Research (physics, medicine) antineutrino
❑ Triggers for nuclear weapons
❑ Radiography
❑ Instrument calibration
 Radiation Protection Course

NEUTRON SOURCES 2. (α ,n) Source:
1. Californium-252 source: Mixed a source (226Ra, 241Am,..) with
A strong neutron source. One microgram light elements (9Be, Li,..)
of californium-252 produces about It produce fast neutrons
3,000,000 neutrons per second.
T1/2
Decay by both Alpha (97%) and Fission Source
Neutron Energy
(3%) (MeV)
226Ra + 9Be 5 1600 Year
Cf-252 has a half-life of about 2.6 years 241Am + 9Be 5 433 Year

It emits fast neutrons 239Pu + 9Be 4 24000 Year
 Radiation Protection Course
NEUTRON SOURCES
3. (γ,n) Reaction Source (Photo-neutron source):
Mixed g source (23Na, 88Y,..) with light elements (9Be, 2H,..)
Produce a defined energy of fast neutrons
γ + 21 H --- 1
1 H +01 n
γ + 94 Be --- 8 Be 1
n
Disadvantage: 4 0
+
Required gamma source with a high energy (need more shield for
gamma )
Short half life of g source (need to be activated again)
 Radiation Protection Course
NEUTRON SOURCES

4. Neutron Generator

D-D Reaction emits neutron with 2 MeV
D-T reaction emits neutron with 14 Mev

Neutron Fluence Rate
The intensity of a neutron source is usually described by the fluence rate.
This is often and incorrectly referred to as the flux.
The neutron fluence rate (N) is the number of neutrons that pass through a specified area
per unit time. Commonly employed units for this quantity are n/cm2/s (i.e., cm-2 s-
1).The direction of the neutrons is irrelevant.
 Radiation Protection Course

Measuring the Neutron Source Strength
The neutron emission rates for alpha neutron, gamma neutron, and
spontaneous fission neutron sources can be determined with the
manganese sulfate bath technique.

The source is positioned in the center of a tank filled with a solution of
manganese sulfate (the bath must be large enough to moderate all the
neutrons). By quantifying the Mn-56 (2.6 hr) production via gamma
spectrometry, the neutron emission rate can be calculated.
The manganese solution is inside the spherical tank and the source is
lowered through the top.

The white neutron detector on the right side of the tank is used to
measure neutron leakage. This value is used to make corrections to the
calculated neutron emission rate. Image courtesy of NPL.
 Radiation Protection Course
Alpha Neutron Sources
AmBe Sources

AmBe (“ambee”) sources are a mix of Am-241 and Be-9.
Yield: ca. 2.0 to 2.4 x neutrons/sec. per Ci
106 neutrons/sec. per GBq
ca. 5.4 to 6.5 x 104
Half-life:neutron
Average 432.2energy:
years 4.2 MeV (11 max)
Neutron dose rate: 2.2-2.7 mrem/hr at 1 m/Ci
0.59-0.73 uSv/hr at 1m/GBq
Gamma dose rate: 2.5 mrem/hr at 1 m/Ci
0.68 uSv/hr at 1m/GBq
 Radiation Protection Course

Alpha Neutron Sources
PuBe Sources

PuBe (“pewbee”) sources are a mix of Pu-239 or Pu-238 and Be-9.
Yield: ca. 1.5 to 2.0 x 10 neutrons/second per Ci
Half-life: 24,114 years
Average neutron energy: 4.2 – 5 MeV (11 max)
Neutron dose rate: 1.3-2.7 mrem/hr at 1 m/Ci
0.35-0.73 uSv/hr at 1m/GBq
Gamma dose rate: 0.1 mrem/hr at 1 m/Ci
0.027 uSv/hr at 1 m/GBq
 Radiation Protection Course

Alpha Neutron Sources
RaBe Sources

RaBe (“raybee”) source, a mix of Ra-226 and Be-9
Yield: ca. 15 x 106 neutrons/sec.
per Ci ca. 40 x 104 neutrons/sec.
per GBq
Half-life: 1,600 years
Average neutron energy: 3.6 MeV (13.2 MeV max)
Gamma exposure rates of these sources can be high. There
is also the problem of leakage. RaBe sources have been used
in moisture gauges sold by Seaman Nuclear - until
recently radium has been unregulated by the NRC.
 Radiation Protection Course
Alpha Neutron Sources
Alternatives to Beryllium

Beryllium is the most common low Z material to be used in alpha-
neutron sources because of its relatively high neutron yield.

Nevertheless, fluorine, lithium and boron have also been used.

Am-F and Am-Li sources have average neutron energies of
1.5 and 0.5 MeV respectively.
 Radiation Protection Course
Alpha Neutron Sources
Source Construction
The alpha emitter and beryllium must be in intimate The source is doubly encapsulated. The inner and outer
contact, e.g., by mixing powdered beryllium metal capsules are usually fabricated of stainless steel (type
with an oxide of the alpha emitter. This mixture is
then compressed into a cylindrical shape for 304) and the end caps are TIG welded. Space is left within the
encapsulation. Another approach is to employ a inner capsule to allow for the gradual buildup of helium that
metallic alloy of the beryllium and the alpha results from the alpha emissions.
emitting actinide.

Typical AmBe sources. Largest
pictured is 60 x 30 mm. Image
courtesy of NPL..
 Radiation Protection Course

Gamma-Neutron Sources A “typical” photo-neutron source might consist of an
inner aluminum-encapsulated gamma-emitting core
(e.g., 1 inch diameter) surrounded by an eighth of an
The major advantage of photo-neutron inch of the neutron emitting target.
sources is that the emitted neutrons are very
close to being monoenergetic. The overall shape of the source might be cylindrical
or spherical.
Their major disadvantage is the very high
activity of the gamma source-only one
gamma ray in one million (or so) might
produce a neutron.The resulting gamma In the case of an antimony-beryllium source, the core
exposure rates can pose a significant is antimony that has been activated in a reactor.
radiological hazard.
Aluminum wall

Gamma-
emitting core Neutron-emitting target
(H-2 or Be)
 Radiation Protection Course
Gamma-Neutron Sources
Sb-Be Source – Antimony-Beryllium Source
Characteristics
A mix of Sb-124 and Be-9.
Yield: ca 0.2-0.3 x 106 neutrons/sec. per Ci
ca. 0.54-0.81 x neutrons/sec. per GBq
104
Half-life: 60 days
Neutron
Gamma energy:
energy: 1.69
0.024MeV
MeV
Neutron dose rate: 0.18-0.27 mrem/hr at 1 m/Ci
0.049-0.073 uSv/hr at 1m/GBq
Gamma dose rate: 1000 mrem/hr at 1 m/Ci
270 uSv/hr at 1m/GBq