EPR-Public Communications L-02 Communicating Basics of Radiation.

Slides:

Advertisements

Similar presentations

Radiation biology and protection in dental radiology

Advertisements

Radiation Safety Course: Biological Effects

Module IV - Dose terms and units

7. RADIATION AND RADIATION PROTECTION

Radiation Protection Course

Basic of radiation Prof. Dr. Moustafa. M. Mohamed Vice Dean

Nuclear Physics. Outcomes What are some of the other uses for radiation? What are the effects of radiation on humans? How can we measure exposure to radiation?

Radiation Units & Quantities

Radiologic Units. Intensity Radiation intensity is the amount of energy passing through a given area that is perpendicular to the direction of radiation.

Radiation Exposure, Dose and Relative Biological Effectiveness in Medicine Background Image:

Mutants!.  The half-life of carbon-14 is 5730 years. Calculate how much of the original carbon- 14 would be left in a fossil that is years old.

“DOSIMETRY” Measuring Radiation National 5. Why should we measure radiation?

Radiation Samar El-Sayed. Radiation Radiation is an energy in the form of electro-magnetic waves or particulate matter, traveling in the air.

RADIATION SAFETY Phil Facey Lead Superintendent Radiographer

Radioactive waste and risk to health L.O: explain how time and source is a factor in disposing of waste Define the risk of radiation doses to health.

Radiation all Around Us Radon gas, cosmic rays, medical x- rays, food and body chemicals.

A Radiation Primer radiation … radioactive material What are they? exposure … contamination Are they the same?

RADIOACTIVE! Sheryl Hoffmann

Radioactive Materials.  Elements that emit radiation all the time are called radioactive  Radioactive elements that are found in the world around us.

BASIC PRINCIPLES IN OCCUPATIONAL HYGIENE Day IONIZING RADIATION.

IONIZING RADIATION ….. a discussion of the health hazards associated with handling and use of materials capable of producing ionization of matter.

Radiation. Ionising Radiation Alpha Radiation Beta Radiation Gamma Rays X-Rays Neutrons.

IONISING RADIATION PUT TO USE Modelling radioactive decay 18.1 Ionising radiation put to use.

Radioactivity Chapter 10 section 1 page

Higher Physics – Unit 3 3.5Dosimetry and Safety. Activity of Radiation The activity of a radioactive source is the average number of nuclei decaying per.

Fundamentals of Radiation

Nuclear Energy Radiation. What is a Radioactive Element? Radioactive elements have a nucleus that is unstable. It decays or breaks apart releasing energy.

Detecting Radiation in our Radioactive World. Nuclear Technology in our Lives Eaten Eggs? Driven over a Metal Bridge? Attached a Postage Stamp? Use Contact.

Nuclear Decay Lesson 6. Objectives You will be able to write nuclear decay reactions You will be able to write nuclear decay reactions.

/0409 Copyright ©2004 Business and Legal Reports, Inc. BLR’s Safety Training Presentations Ionizing Radiation 29 CFR

1 IONIZING RADIATION. 2 Non-Ionizing Radiation Does not have enough energy to remove electrons from surrounding atoms.

General, Organic, and Biological Chemistry Fourth Edition Karen Timberlake 4.3 Radiation Measurement Chapter 4 Nuclear Chemistry © 2013 Pearson Education,

Unit IV: Nuclear Physics. What is Radioactivity?  Is the spontaneous breakdown of an unstable nucleus.  Results in the emission of particles or electromagnetic.

ANALYTICAL X-RAY SAFETY User Training Centre for Environmental Health, Safety and Security Management.

Introduction to Radioisotopes: Measurements and Biological Effects

,  and  -rays as well as neutrons X-rays.. doubly charged helium nuclei (42He2+) emitted by radioactive elements with a very high atomic number not.

NUCLEAR VS. CHEMICAL CHEMICAL reactions involve rearranging of atoms: e.g., H 2 +O 2  H 2 O No new atoms are created. Chemistry involves electrons only.

1 Health Safety & Radiation Protection (RAD 453) Course : بسم الله الرّحمن الرّحيم Chapter 1: Fundamental Radiation Concepts Omrane KADRI, Ph.D.

Radiation Peter Lee. Radiation Radiation is energy that may take such forms as light, or tiny particles much too small to see. Visible light, the ultra-violet.

Radiation Safety and You Brian Kessler Zettl Group Safety Talk September 7, 2006.

IB Assessment Statements  I.3.1.State the meaning of the terms exposure, abosorbed dose, quality factor (relative biological effectiveness) and dose.

30.1 X-rays and radioactivity

RADIATION PROTECTION IN RADIOTHERAPY

BASICS OF RADIATION MEDICINE Prof. Igor Y. Galaychuk, MD Head, Department of Oncology & Radiology Ternopil State Medical University.

Half Life. Half-life is the time it takes for half of the atoms of a sample to decay. For example: A student was testing a sample of 8 grams of radioactive.

Radiation Units. 1-Radioactivity Units n Physical Units – Becquerel n Amount of radioactive sample s.t. there is 1 atomic decay per second n Henri Becquerel:

2/20/2016Chapter N*31 Radiation Exposure, Dose and Quantity Exposure is an index of the ability of a radiation field to ionize air. Dose is a measure of.

Higher Physics Radiation Dosimetry.

Dosimetry & Safety. Activity The term 'Activity' of a source describes the (in)stability of the atoms within a substance. One atom decaying per second.

August 2005 EMS & Trauma Systems Section Office of Public Health Preparedness RADIOLOGICAL NUCLEAR EXPLOSIVE.

BASIC PRINCIPLES IN OCCUPATIONAL HYGIENE

Louisiana State University Radiation Safety Office

S3 Physics Radioactivity

Radiation Units.

RADIOLOGICAL NUCLEAR EXPLOSIVE

Ionising radiation put to use

IONIZING RADIATION ….. a discussion of the health hazards associated with handling and use of materials capable of producing ionization of matter.

Radiation Dose.

IONIZING RADIATION 1.Introduce self

Sources and Dangers of Radiation

BASICS OF RADIATION MEDICINE

Radiation in the Workplace

The dangers of radioactivity

RADIATION AND HALF-LIFE

Biological Effects of Ionising Radiation

Presentation transcript:

EPR-Public Communications L-02 Communicating Basics of Radiation

Simple

Challenge Communicating with the public about radiation is challenging; Communicate in plain language; You will communicate better with people if you can think as they are thinking.

Sources Radiation is naturally present in the environment. This is called natural background radiation; People are exposed to natural radiation from outer space, the air, food and drink; People may also be exposed to artificial radiation from medical treatment, consumer products and occupational exposure; Often, medical exposures from diagnosis and in treatment account for the largest dose from artificial sources. Cosmic radiation and dose rates of exposure

Types of radiation Alpha radiation (α)Beta radiation (β)Gamma radiation (γ) Radiation that has a short range in air and can be stopped by paper or skin. This radiation can be hazardous if it enters the body by inhalation or ingestion because large exposures can result in nearby tissues. Radiation that can penetrate further into materials or tissue, but can be stopped by plastic, glass or metal. This radiation does not normally penetrate beyond the top layer of skin but large exposures can cause skin burns and is also hazardous if it enters the body. Very penetrating radiation for which only dense material such as steel or lead can provide an effective shield. It can deliver significant doses to internal organs without needing to be taken into the body.

Types of radiation

Exposure pathways Inadvertent ingestion

Common exposure pathways for a small radioactive source

Quantities and units Measuring radiation The becquerel (Bq) is a unit used to measure radiation. When ionising radiation interacts with biological tissue, it deposits energy there. The amount of energy deposited per unit mass of tissue is called the absorbed dose: the unit of this dose is called the gray (Gy). Since equal exposures to different types of radiation expressed as Gy do not necessarily produce equal biological effects, these doses are weighted to give units of dose as the effective dose, or sievert (Sv). The sievert determines the probability that an ill-health effect will ensue. Regardless of the type of radiation, 1 sievert of radiation produces the same probability of biological effect (cancer or hereditary effects). Sievert is calculated and not measured. Dose of radiation The amount of radiation – the “dose” – received by people is measured in sieverts (Sv). This takes into account the type of radiation and how a person is exposed to that radiation. Example: A typical dose received due to the natural sources of radiation is 3 milliSieverts in a year (written 3 mSv or Sv). The sievert belongs to the same family as the litre and kilogram. To explain the prefix “milli” compare with commonly used units such as litre (l) and millilitre (ml). Dose rate Dose rate is the rate at which dose is received. It is often used to calculate the intensity of a radiation source. Example: The dose rate at one metre from a source is 50 microsieverts per hour (written 50 µSv/h). If a person stood in this radiation field for 2 hours, he/she would receive a total dose of 100 µSv. Here, a µSv is a million times smaller than a Sv and a thousand times smaller than a mSv.

Effects of radiation Deterministic: short term, occurring early after exposure; Stochastic: long term, occurring years later.

Recognizing a radiation source Trefoil radiation warning symbol New standard ionizing radiation warning supplementary symbol

Radiation protection Time Distance Shielding

Am I safe? In addition to dose and dose rate quantities the following questions must be answered: What was measured or reported? How was the person exposed (exposure scenario)? Who was exposed?

Potential health effects Death; Severe health effects (severe deterministic effects): Severe burns; Other non-fatal effects. Health effects to foetus; Cancer risk.

Health effects from being near an unshielded radioactive source

Health effects from carrying an unshielded radioactive source

Health effects from being near an unshielded radioactive source

Let’s practice Some questions…