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Transcript of Basic radiation 061706
Basic Radiation
Animations in this training work best in Windows XP
May 2006
Topics
• Introduction to Radiation
• Types of Radiation
• How Radiation Interacts
with the Environment
• Radiation Safety
• Why We Need to Measure Radiation Today
Introduction to Radiation
• Radiation can be non-ionizing or ionizing
• Non-ionizing radiation is generally a low energy electromagnetic wave– Sunlight– Radio waves– Microwaves– Infrared waves
• Mostly harmless
Ionizing Radiation
• Ionizing (nuclear) radiation has enough energy to ionize the atoms and molecules it interacts with– Particles: alpha, beta, neutron– Waves: gamma
• Because it can ionize, it can cause biological damage
Introduction to Radiation
• Ionizing Radiation is all around us– We are constantly exposed to low levels of radiation
from outer space, the earth, and medical treatments– Low levels of naturally occurring radioactive material
are in our environment, the food we eat, and in many consumer products
– Some consumer products also contain small amounts of man-made radioactive material
– However, exposure to large doses of radiation is definitely not desirable
– Most of your annual dose of radiation comes from Radon gas in your house!
Topics
• Introduction to Radiation
• Types of Radiation
• How Radiation Interacts
with the Environment
• Radiation Safety
• Why We Need to Measure Radiation Today
Types of Radiation
The Atom
Particle Location Charge Relative Mass
Proton Nucleus +1 1
Neutron Nucleus neutral 1
Electron Orbit -1 1/1837
Carbon-12:• 6 Protons• 6 Neutrons• 6 Electrons
The Atom
Particle Determines…
Proton Element Chemical & physical properties
Neutron Isotope Radioactivity
Electron Ion Some bonding & interaction
Carbon-12:• 6 Protons• 6 Neutrons• 6 Electrons
Unstable Atoms Decay
• Certain atoms are radioactive because their nuclei are unstable– They have too few or too many neutrons, which
creates an imbalance
• To get stable, the atom “decays” and transforms into a new atom by emitting radiation in 4 forms:– Alpha particle (α)
– Beta particle (β)
– Gamma wave (γ)
– Neutron particle (n)
• Sometimes the new atom is also unstable, and it decays too, creating a “decay chain”
UCRL-PRES-149818. Understanding Radiation and it’s Effects.
Source Activity
• The number of decays per unit time tell us how radioactive a source is. This is called activity.
• Measured in Curies (Ci) or Becquerels (Bq)– 1 Becquerel = 1 Bq = 1 decay per second– 1 Curie = 1 Ci = 3.7 x 1010 Bq– 1 Ci = the activity of 1 gram of Radium-226
Half Life
• The half life of a radioactive material tells us how quickly it decays away
• Half life = how long it takes for ½ of the radioactive atoms in a sample to decay away
• Measured in units of time• Some examples:
– Some natural isotopes (like Uranium and Thorium) have half lives that are billions of years
– Most medical isotopes (like Technicium-99m) last only a few days
UCRL-PRES-149818. Understanding Radiation and it’s Effects.
Alpha Decay
• A +2 charged helium nucleus with 2 protons and 2 neutrons• Relatively heavy particle with a big charge• Travels 2-5 cm in air• Stopped by a piece of paper, or the top layer of your skin• Difficult to detect • Dangerous if inhaled– will cause localized severe damage to a thin
layer of tissue in the lungs and respiratory tract- possible precursor to lung cancer
• Radioactive “beach ball”
Beta Decay
• Negatively (or positively) charged electron• Relatively light particle, but still charged• Travels ~10 meters in air• Stopped by aluminum foil, glass plate or 2.5 cm of virtually anything• Difficult to detect• Dangerous if inhaled– will cause localized severe damage to a thin
layer of tissue in the lungs and respiratory tract- possible precursor to lung cancer
• Radioactive “golf ball”
Gamma Decay
• Energetic electromagnetic wave (photon) with no charge• Travels many kilometers/miles in air• Stopped by lead or concrete 10+ cm thick• Relatively easy to detect and direct exposure is likely• Normal to be exposed to small amounts everyday from ground radiation and
cosmic rays• γ rays vs. x-rays
– γ rays are emitted from the nucleus of an atom– X-rays are emitted from the orbital electrons of an atom
• Radioactive “9mm bullet”
Neutron “Decay”
Small, neutral particles (same size as a proton)• Travels many kilometers in air• Stopped by 30+ cm of water, polyethylene or paraffin
– Spent fuel rods are stored in water
• Self-fissioning radioactive materials (Plutonium, Californium) give off neutrons
• Large doses can do significant damage to people
Types of Radiation
Type of Radiation
Physical StructureTravel Distance in Air & Means
of Attenuation
Alpha Particles
Positively charged Helium nucleus (2 protons & 2 neutrons)
~1-2 inches
Stopped by a single sheet of paper
Beta ParticlesPositively or negatively charged electrons
~30 feet
Stopped by aluminum foil, glass plate, ~1 inch of anything
Gamma Rays (Photons)
Neutral, energetic electromagnetic wave
Many miles
Stopped by thick lead (4 inches) or very thick concrete
NeutronsSmall, neutral particles with mass very near a proton
Many miles
Stopped by 12 inches of water, polyethylene, paraffin
Topics
• Introduction to Radiation
• Types of Radiation
• How Radiation Interacts
with the Environment
• Radiation Safety
• Why We Need to Measure Radiation Today
What is a “Dose” of Radiation?
• When radiation hits your body, and it’s energy is transferred to your tissue, you have received a dose of radiation.
• The more energy deposited, the higher your dose.
• Measured in Roentgen Equivalent Man (rem) or sieverts (Sv – SI unit)
• Rads and Roentgens (R) are similar units that are often equated to the rem.
Topics
• Introduction to Radiation
• Types of Radiation
• How Radiation Interacts
with the Environment
• Radiation Safety
• Why We Need to Measure Radiation Today
Radiation Safety
• The fundamental principle of radiation safety is that radiation exposures should be maintained As Low As Reasonably Achievable (ALARA).
• The three factors influencing radiation dose are:– Time– Distance– Shielding
ALARA - Time
• The less time you’re exposed, the less exposure you get
• Dose = Dose Rate x Time• If you want to limit your exposure to 100 Rem
and the source is 200 Rem/hr then only stay near the source for 30 minutes:
200 µRem/hr x 0.5 hr = 100 µRem
• Limit your time near the radiation source!
ALARA - Distance
• The farther away from the source you are, the weaker the source is to you
• Exposure levels are based upon the inverse square law
• Increase the distance between you and the source!
ALARA - Shielding
• Shielding can stop the radiation from hitting you• Exposure levels can be reduced greatly by
putting shielding between yourself and the radiation source– α can be absorbed by a piece of paper– β can be absorbed by 1” of aluminum or glass– γ can be absorbed by thick lead shields– n can be absorbed by paraffin, water, polyethylene
• Increase the amount of shielding material between you and the source!
Shielding/Attenuating Radiation
Pap
er
Glass, th
in m
etal
Lead
, C
on
crete
Water,
Po
lyethylen
en
n
n
n
Shielding/Attenuating Radiation
Pap
er
Glass, th
in m
etal
Lead
, C
on
crete
W
ater, P
olyeth
ylene
Radiation Safety
• Another danger to the body is through the entry of radioactive substances into the body rather than a short external exposure to radiation.
• Routes of entry to the body:1.Air Lungs , e.g. Radon Gas2.Food, drinking water Mouth Bloodstream, GI
tract3.Body Cuts Bloodstream
• Once in the body, the radioactive substance is the “gift that keeps on giving”
• However, the human body is very resilient, and has very efficient repair mechanisms to deal with small, normal amounts of radiation damage
Irradiated or Contaminated?
• Irradiated– You are “irradiated” when radiation hits you– You do NOT become radioactive when you
are irradiated– Some forms of radiation CAN penetrate
personal protective clothing
Irradiated or Contaminated?
• Contaminated– Contamination is radioactive dirt– You can become contaminated by touching
radioactive dirt– Contamination can be washed off like any dirt– Personal protective equipment can protect
people from contamination
Typical Yearly Radiation Dosage
• Total average annual dosage: 440 mRem• Annual dosage can be increased by smoking, living at higher
elevations, living in a brick, stone or concrete house, flying, plutonium-powered pacemakers, watching TV, medical x-rays.
• Calculate your own exposure at: http://www.epa.gov/radiation/students/calculate.html
Average Annual Radiation Dosage*
Radon in homes (~240 mRem)
Medicine (70 mRem)
Natural radiation from ground (50mRem)Natural activity in body (40 mRem)
Cosmic radiation (30 mRem)
Others (10 mRem)
* Understanding Radiation: Bjorn Wahlstrom
Common Doses in Everyday Life**
Dosage Cause of Dose
Sv rem
100 10,000 Average annual chest x-ray exposure
2000 200,000 Annual exposure from radon gas in homes
810 81,000 Annual background radiation exposure at high elevation (Denver)
14,000 1,400,000 Gastro-intestinal Barium x-ray (GI series)
** Hazardous Materials Air Monitoring and Detection Devices: Chris Hawley
Important Dose Limits**
Dose Rate Limit Description of Limit
Sv rem
10 1,000 Limit for normal public activities
50,000 5,000,000 Limit for all activities
100,000 10,000,000
(10 rem)
Limit for protecting valuable property
250,000 25,000,000
(25 rem)
Limit for lifesaving or protection of large populations
>250K >25,000,000
(>25 rem)
Limit for lifesaving or protection of large populations only on a voluntary basis for persons aware of the risks
** Hazardous Materials Air Monitoring and Detection Devices: Chris Hawley
Acute Radiation Doses
Dose (Rads*) Effects25 – 50
(~25,000,000 – 50,000,000 rem)
First sign of physical effects – drop in white blood cell count
100
(~100,000,000 rem)
Vomiting within several hours of exposure
320 – 360
(~ 320,000,000 – 360,000,000 rem)
~50% die within 60 days with minimal supportive care
480 – 540
(~480,000,000 – 540,000,000 rem)
~50% die within 60 day with supportive care
1,000
(~ 1,000,000,000 rem)
~100% die within 30 days
*1 Rad can be approximated to 1 rem = 1,000,000 rem = for common external exposures
Topics
• Introduction to Radiation
• Types of Radiation
• How Radiation Interacts
with the Environment
• Radiation Safety
• Why We Need to Measure Radiation Today
Why Detect Radiation Today?
• Medicine– Imaging– Cancer treatment and therapy
• Industrial– Imaging– Gauges
• Power• Agriculture• Radiological terrorism
Radiological Terrorism
• Radiological Terrorism is a real and possible threat– High psychological/emotional impact– High economic impact– Many devices are easy to build– Al Qaeda has threatened radiological terrorism– It’s already being done
• Improvised Nuclear Device• Radiological Dispersion Devices (RDDs)• Radiation detection covers two letters of CBRNE
preparedness: Radiological and Nuclear
Radiological Terrorism
• Nuclear warheads use special nuclear materials and fission or fusion to create a nuclear payload
• Plutonium 239 and Uranium 235 are the special nuclear materials used in weaponry
• Medical and industrial radioactive materials CANNOT produce a nuclear warhead– they can only be used to contaminate!!!
Threat ComparisonS
ever
ity o
f in
cide
nt
Probability of incident
Stolen nuclear weapon
Improvised nuclear device
RDD
Radiological Dispersion Devices
• Radiological dispersion devices (RDDs) can take two main forms:– A dirty bomb- a core of radiological material
wrapped in conventional explosives– A simple radioactive source left discretely in a
public place
• The key to these devices is NOT destruction- it’s fear and contamination. It is a psychological and “denial of service” attack on the economy.
Making an RDD
• All you need is radiological material
• Optional: Explosives
• Orphan sources– Radiological materials are used everyday in a
variety of applications– Some sources are lost, forgotten, or disposed
of improperly – Orphan sources– Over 200,000 available today
Example of an RDD
• 1 pound of HE, two patient doses of liquid Technetium-99m (Tc-99m) near the HE
• Weather: 30 degrees F, sunny, light winds with gusts of 20 mph
• Tc-99m chosen due to level of radioactivity (high), short half-life, environmentally safe daughters, and availability
Example of an RDD
• Contamination measured at 4 times background• Due to short half-life, Tc-99m decayed to non-
hazardous daughters within 60 hours
Threats
Commonly Orphaned Isotopes
Radioisotope Half-Life Alpha Emission
Beta Emission Gamma Emission
Neutron Emission
Detect with GammaRAE
II?
Cobalt-60 5.3 yrs No Low Energy High Energy No Yes
Cesium-137 30 yrs No Low Energy Delayed High Energy
No Yes
Iridium-192 74 days No High Energy High Energy No Yes
Stronium-90 29 yrs No High Energy No No Yes
Americium-241 433 years High Energy
No Low Energy No Yes
Californium-252 2.6 years High Energy
No Low Energy Yes (Spont. Fission)
Yes
Plutonium-238 88 yrs High Energy
No Low Energy Yes (Spont. Fission)
Yes
Commonly Available Isotopes That Are Suitable For RDDs
Source: “Commercial Radioactive Sources: Surveying the Security Risks," Monterey Institute of International Studies, 1/2003
“Innocent” Sources
• Innocent Source: a radioactive source seen in typical day to day operations– May be the source of “false” alarms– Could be used to shield/disguise a real source
• Ship/truckloads of tile, bricks• Containers of bananas, fertilizer containing
potassium• Patients who have received radioactive
iodine, barium or other nuclear medicine treatments
Summary
• Radioactivity is all around us– There are 4 types of radiation: alpha, beta,
gamma, and neutron
• Radiation is used in many applications in everyday life
• Radiation can also be used for malicious/terrorist acts
• Knowing more about radiation can help to better understand the threat, and reduce the chances of an occurrence
Additional Slides
• Additional Slides
Mishaps
Mishaps
Terrorist Attacks
RDDs
RDDs
RDDs
Material Attacks
Material Theft
Specific Activity
• Specific Activity refers to the activity of 1 gram of a radioactive material
• Different isotopes have different specific activities.
• The longer the half-life of the isotope, the lower the specific activity of the isotope.– 1 gram of cobalt-60 has
the same activity as 3300 metric tons of uranium-238
Some Isotopes & Their Half-LivesIsotope Half-Life Applications
Uranium billions of years
Natural uranium is comprised of several different isotopes. When enriched in the isotope of U-235, it’s used to power nuclear reactor or nuclear weapons.
Carbon-14 5730 y Found in nature from cosmic interactions, used to“carbon date” artifacts and as radiolabel for detectionof tumors.
Cesium-137 30.2 y Blood irradiator, tumor treatment through externalexposure. Also used for industrial radiography.
Hydrogen-3 12.3 y Labeling biological tracers.
Iridium-192 74 d Implants or "seeds" for treatment of cancer. Alsoused for industrial radiography.
Technicium-99m
6 h Brain, heart, liver, lungs, bones,thyroid, and kidney, regional cerebral blood flowimaging.
UCRL-PRES-149818. Understanding Radiation and it’s Effects.
Exposure
• Exposure: how much radiation “hits” an object (or person)
• Measured in Roentgens (R)• Visualize the amount of light emitted by the sun
that hits you while sitting on the beach
Absorbed Dose
• Absorbed dose: how much energy is imparted on/transferred to the object by the radiation
• Measured in Rads (Radiation Absorbed Dose) or Grays (Gy)– Units of energy/mass– 1 Gy = 100 rad
• Imagine how much your skin heats up from the sunlight hitting it
Biologically Equivalent Dose
• Biologically equivalent dose: Radiation-weighted dose to quantify the effects of radiation on biological tissue
• Measured in Roentgen Equivalent Man (rem) or Sieverts (Sv)– 1 Sv = 100 rem
• Imagine how sunburnt you get from sitting out in the sun
How Radiation Interacts
• Imagine you’re relaxing on the beach on a sunny day:– The amount of light the sun emits is the “activity” of the sun– The amount of light that hits your skin is your exposure– The amount your skin heats up is your “absorbed dose”– The amount of sunburn you get is your “biologically equivalent
dose”
Radiation Units
Type Unit Definition
Source activity Curie (Ci)
Becquerel (Bq)
3.7 x 1010 disintegrations/second
1 disintegration per second
Exposure (X & gamma rays) Roentgen (R)
2.58 x 10-4 Coulombs/Kg in dry air at STP
1 Coulomb per 1cc dry air at STP
Absorbed dose rad
Gray (Gy)
0.01 J /Kg
1 J /Kg
1Gy = 100 Rad
Biologically equivalent dose
Rem
Sievert (Sv)
QFR x (dose in rad)
QFG x (dose in Gray)
Radiation Equivalents
RemMillirem (mrem)
Microrem (µrem)
1 1,000 1,000,000
0.1 100 100,000
0.01 10 10,000
0.001 1 1,000
0.0001 0.1 100
0.00001 0.01 10
0.000001 0.001 1
Radiation Equivalents
Unit Measured Quantity
Rad, Grey (Gy) Absorbed Dose
Rem, Sievert (Sv) Biologically Equivalent Dose
Unit Equivalents
100 Rem 1 Sv
1 Rem 10 mSv (millisievert)
1 mrem (millirem) 10 Sv (microsievert)
1 rem (microrem) 0.01 Sv
Radioactive Contamination
• Radiation cannot make you radioactive*
* Understanding Radiation: Bjorn Wahlstrom
Radioactive Contamination
• Radioactive contamination can stick to clothes & skin. It can be washed away like any dirt*.
* Understanding Radiation: Bjorn Wahlstrom
• When most people think of radiation, they When most people think of radiation, they think of the mushroom cloud from the think of the mushroom cloud from the atomic bomb tests in the 1940’s & 50’s.atomic bomb tests in the 1940’s & 50’s.
• If people thought the same way about If people thought the same way about electricity, their first image would be of the electricity, their first image would be of the electric chair instead of the light bulb!electric chair instead of the light bulb!
• The goal of this presentation is to The goal of this presentation is to demystify radiationdemystify radiation
1952, Operation Ivy, “Mike” H-Bomb