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Radiation - Quantities and Units of Ionizing Radiation

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What is ionizing radiation?

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Ionizing radiation is radiation that has enough energy to remove electrons from atoms or molecules (groups of atoms) when it passes through or collides with some material. The loss of an electron with its negative charge causes the atom (or molecule) to become positively charged. The loss (or gain) of an electron is called ionization, and a charged atom (or molecule) is called an ion.

Note: Microwave, infrared (IR) and ultraviolet (UV) radiation are examples of non-ionizing radiation. Non-ionizing radiation does not have enough energy to remove electrons.


What are some examples of ionizing radiation?

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There are natural and artificial sources of ionizing radiation. Artificial sources of radiation include X-ray machines, radioactive isotopes used in nuclear medicine, gamma cameras, nuclear gauges and nuclear power plants.

X-rays refer to a kind of electromagnetic radiation generated when a strong electron beam bombards metal inside a glass tube. The frequency of this radiation is very high— 0.3 to 30 EHz (exahertz or billion gigahertz). In comparison, FM radio stations transmit at frequencies around 100 MHz (megahertz) or 0.1 GHz (gigahertz).

Natural sources of radiation include:

  • background radiation from space,
  • cosmic radiation from cosmic rays,
  • terrestrial radiation from minerals in the earth’s crust,
  • radiation from inhaling radon gas, and
  • radiation from ingesting food and drinking water that may contain radioactive  potassium-40.

Minerals such as uranium and thorium are radioactive and give off radiation when the nucleus breaks down or disintegrates. The three kinds of radiation generated by radioactive materials or sources are alpha particles, beta particles and gamma rays.


What properties are considered when ionizing radiation is measured?

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Ionizing radiation is measured in terms of:

  • the strength or radioactivity of the radiation source,
  • the energy of the radiation,
  • the level of radiation in the environment, and
  • the radiation dose or the amount of radiation energy absorbed by the human body.

From the point of view of occupational exposure, the radiation dose is the most important measure. Occupational exposure limits such as the ACGIH TLVs® are given in terms of the permitted maximum dose. The risk of radiation-induced diseases depends on the total radiation dose a person receives over time.


What units are used for measuring radioactivity?

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Radioactivity or the strength of a radioactive source is measured in units of becquerel (Bq).

1 Bq = 1 event of radiation emission or disintegration per second.

One becquerel is an extremely small amount of radioactivity. Commonly used multiples of the Bq unit are kBq (kilobecquerel), MBq (megabecquerel), and GBq (gigabecquerel).

1 kBq = 1000 Bq, 1 MBq = 1000 kBq, 1 GBq = 1000 MBq.

An old and still popular unit of measuring radioactivity is the curie (Ci).

1 Ci = 37 GBq = 37000 MBq.

One curie is a large amount of radioactivity. Commonly used subunits are mCi (millicurie), µCi (microcurie), nCi (nanocurie), and pCi (picocurie).

1 Ci = 1000 mCi; 1 mCi = 1000 µCi; 1 µCi = 1000 nCi; 1 nCi = 1000 pCi.

Another useful conversion formula is:

1 Bq = 27 pCi.

Becquerel (Bq) or Curie (Ci) is a measure of the rate (not energy) of radiation emission from a source.


What does half-life mean when people talk about radioactivity?

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Radiation intensity from a radioactive source diminishes with time as more and more radioactive atoms (radionuclides) emit energy to become stable atoms. Radioactive decay is the decline in radiation intensity. Half-life is the time after which the radiation intensity is reduced by half. This happens because half of the radioactive atoms will have decayed in one half-life period. For example, a 50 Bq radioactive source will become a 25 Bq radioactive source after one half-life.

Table 1
Radioactive Decay
Number of half-lives elapsedPercent radioactivity remaining
0100
150
225
312.55
46.25
53.125

Half-lives differ widely from one radioactive material to another and range from a fraction of a second to millions of years.


What units are used for measuring radiation energy?

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The energy of ionizing radiation is measured in electronvolts (eV). One electronvolt is an extremely small amount of energy. Commonly used multiple units are kiloelectron (keV) and megaelectronvolt (MeV).

6,200 billion MeV = 1 joule

1 joule per second = 1 watt

1 keV = 1000 eV, 1 MeV = 1000 keV

Watt is a unit of power, which is the equivalent of energy (or work) per unit of time (e.g., minute, hour).


What units are used for measuring radiation exposure?

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X-ray and gamma-ray exposure is often expressed in units of roentgen (R). The roentgen (R) unit refers to the amount of ionization present in the air. One roentgen of gamma- or x-ray exposure produces approximately 1 rad (0.01 gray) tissue dose (see next section for definitions of gray (Gy) and rad units of dose).

Another unit of measuring gamma ray intensity in the air is "air dose or absorbed dose rate in the air" in grays per hour (Gy/h) units. This unit expresses gamma ray intensity in the air from radioactive materials in the earth and in the atmosphere.


What units are used for measuring radiation dose?

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When ionizing radiation interacts with the human body, it gives its energy to the body tissues. The absorbed dose is the amount of energy absorbed per unit weight of the organ or tissue and is expressed in units of gray (Gy). One gray dose is equivalent to one joule of radiation energy absorbed per kilogram of organ or tissue weight. Rad is the old and still used unit of absorbed dose. One gray is equivalent to 100 rads.

1 Gy = 100 rads

Equal doses of all types of ionizing radiation are not equally harmful to human tissue. Alpha particles produce greater harm than beta particles, gamma rays and X-rays for a given absorbed dose, so 1 Gy of alpha radiation is more harmful than 1 Gy of beta radiation. To account for the way in which different types of radiation cause harm to tissue or an organ, the radiation dose is expressed as the equivalent dose in units of sievert (Sv). The dose in Sv is equal to the total external and internal "absorbed doses" multiplied by a "radiation weighting factor" (WR - see Table 2 below) and is important when measuring occupational exposures. Before 1990, this weighting factor was called Quality Factor (QF).  

Table 2
Radiation Weighting Factors
 Column 1Column 2
ItemType of RadiationWeighting Factor
1Photons, all energies1
2Electrons and muons, all energies11
3Protons and charged pions2
4Alpha particles, fission fragments and heavy ions20
5NeutronsA continuous function of neutron energy2

1 Excluding Auger electrons emitted from nuclei bound to DNA.
2 Radiation weighting factors for these neutrons may also be obtained by referring to the continuous curve shown in Figure 1, and equation 4.3, on page 66 of the English version of the 2007 Recommendations of the International Commission on Radiological Protection, ICRP Publication 103, published in 2007.

Source: The Canadian Radiation Protection Regulations, Schedule 2 (SOR/2000-203).

Equivalent dose is often referred to simply as "dose" in every day use of radiation terminology. The old unit of "dose equivalent" or "dose" was rem.

Dose in Sv = Absorbed Dose in Gy x radiation weighting factor (WR)

Dose in rem = Dose in rad x QF

1 Sv = 100 rem

1 rem = 10 mSv (millisievert = one thousandth of a sievert)

1 Gy air dose equivalent to 0.7 Sv tissue dose (UNSEAR 1988 Report p.57)

1 R (roentgen) exposure is approximately equivalent to 10 mSv tissue dose


What is the relationship between SI units and non-SI units?

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Table 3 shows SI units (International System of Units or Systéme Internationale d'unités), the corresponding non-SI units, their symbols, and the conversion factors.

Table 3
Units of Radioactivity and Radiation Dose
QuantitySI unit and symbolNon-SI unitConversion factor
Radioactivitybecquerel, Bqcurie, Ci1 Ci = 3.7 x 1010 Bq
= 37 Gigabecquerels (GBq)
1 Bq = 27 picocurie (pCi)
Absorbed dosegray, Gyrad1 rad = 0.01 Gy
"Dose"
(Equivalent dose)
sievert, Svrem1 rem = 0.01 Sv
1 rem = 10 mSv

What is a "committed dose"?

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When radioactive material enters the body by inhalation or ingestion, the radiation dose constantly accumulates in an organ or a tissue. The total dose accumulated during the 50 years following the intake is called the committed dose. The quantity of committed dose depends on the amount of ingested radioactive material and the time it stays inside the body.


What is an "effective dose"?

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The effective dose is the sum of weighted equivalent doses in all the organs and tissues of the body.

Effective dose = sum of [organ doses x tissue weighting factor]. Effective dose is measured in millisieverts (mSv) or sieverts (Sv).

Tissue weighting factors (Table 4) represent the relative sensitivity of organs for developing cancer.

Table 4 
Organ Or Tissue Weighting Factors
 Column 1Column 2
ItemOrgan or TissueWeighting Factor
1Gonads (testes or ovaries)0.08
2Red bone marrow0.12
3Colon0.12
4Lung0.12
5Stomach0.12
6Bladder0.04
7Breast0.12
8Liver0.04
9Esophagus0.04
10Thyroid gland0.04
11Skin10.01
12Bone surfaces0.01
13Brain0.01
14Salivary glands0.01
15All organs and tissues not listed in items 1 to 14 (remainder organs and tissues) collectively, namely the adrenals, extra-thoracic region, gallbladder, heart, lymphatic nodes, small intestine, kidney, muscles, pancreas, spleen, thymus and prostate or uterus/cervix2,30.05
16Whole body1.0

1 The weighting factor for skin applies only when the skin of the whole body is exposed.

2 The weighting factor for the remainder organs and tissues applies to the arithmetic mean dose of the 13 remainder organs and tissues. 

3 Hands, feet and the lens of an eye have no weighting factor.

Source: The Canadian Radiation Protection Regulations, Schedule 1 (SOR/2000-203).


What are the limits of exposure to radiation?

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The applicable exposure limits to radiation a workplace must follow will depend on the type of radiation and exposure, how it is generated, whether workers are nuclear energy workers and the jurisdiction they work within. Workplaces should always strive to minimize a worker's exposure to ionizing radiation as low as reasonably achievable (ALARA) below the exposure limits. The Canadian Nuclear Safety and Control Act and the Radiation Protection Regulations are federal legislation that applies to Canadian Nuclear Safety Commission (CNSC) applicants and licensees. The Canada Labour Code also sets radiation exposure limits for federal workplaces.  Legislation on the maximum amount of radiation workers can be exposed to is also set by provincial and territorial governments. These exposure limits apply to workplaces without CNSC licensees (e.g., do not have nuclear energy workers).

The Threshold Limit Values (TLVs®) published by the ACGIH (American Conference of Governmental Industrial Hygienists) are occupational exposure limits adopted by many jurisdictions as guidelines or legal limits:

20 mSv - TLV® for the average annual effective dose for radiation workers, averaged over five years.

Some jurisdictions may have more stringent ionizing radiation exposure limits for workers, such as an effective dose limit of 20 mSv over any period of 12 consecutive months (BC Occupational Health and Safety Regulations, Part 7). Exposure limits for pregnant workers are also lower, with most jurisdictions setting a limit of 4 mSv

In Canada, the Radiation Protection Regulations set radiation exposure limits for the public and nuclear energy workers. The effective dose limit for nuclear energy workers is 50 mSv per year and 100 mSv over 5 years. This limit means over 5 years, the annual average effective dose limit is 20 mSv, and exposure cannot exceed 50 mSv in a single year. The limit for pregnant workers, once the pregnancy has been declared, is 4 mSv for the remainder of the pregnancy.  

The annual effective dose limit is 1mSv for the Canadian public. This dose limit aligns with the International Commission on Radiological Protection (ICRP) recommended annual dose limit of 1 mSv for the general public.

Based on information from regular monitoring of the most exposed workers, such as a radiographer, shows that the average annual doses are 5 mSv per year.


What are the main ways to control radiation exposure?

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The main ways to control radiation exposure include engineering controls, administrative controls and personal protective equipment. Examples of these controls include:

  • Education and training
  • Reducing exposure time
  • Increasing the distance from the radiation source
  • Using a physical barrier that modifies the pathway between the worker and the source of radiation e.g., concrete or lead
  • Monitoring of exposures (individual and collective monitoring)
    • Recording exposures
    • Providing health surveillance
    • Promoting a health and safety culture
    • Complying with established radiation exposure (dose) limits

Approximately forty-four (44) percent of monitored workers worldwide are exposed to artificial sources of radiation. Of those workers exposed to artificial sources, seventy-five percent work in the medical sector. Table 5 shows trends in global radiological exposure of workers since the 1970s.

Table 5 
Trends in Global Radiological Exposure of Workers (mSv)*
Sources1970s1980s1990s2000s
Natural
Aircrew-3.03.03.0
Coal mining-0.90.72.4
Other mining**-1.02.73.0
Miscellaneous-6.04.84.8
Total-1.71.82.9
Artificial
Medical uses0.80.60.30.5
Nuclear industry4.43.71.81.0
Other industries1.61.40.50.3
Miscellaneous1.10.60.20.1
Total1.71.40.60.5

* Estimates of average effective dose per worker in a year.

** Uranium mining is included in the nuclear industry.

Source: Radiation: Effects and Sources, United Nations Environmental Programme (UNEP), 2016


What effects do different doses of radiation have on people?

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One sievert (Sv) is a large dose. The recommended exposure limit for many workers in a single year is an effective dose of 0.05 Sv (50 mSv), or an annual average of 0.02 Sv (20 mSv). 

The effects of being exposed to large doses of radiation at one time (acute exposure) vary with the dose. Here are some examples:

10 Sv - Risk of death within days or weeks

1 Sv - Risk of cancer later in life (5 in 100)

100 mSv - Risk of cancer later in life (5 in 1000)

50 mSv - occupational exposure limit for annual effective dose for radiation workers in any one-year

20 mSv - occupational exposure limit for annual average effective dose, averaged over five years


What are "working level" and "working level month"?

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In underground uranium mines, as well as in some other mines, radiation exposure occurs mainly due to airborne radon gas and its solid short-lived decay products, called radon daughters or radon progeny. Radon daughters enter the body with the inhaled air. The alpha particle dose to the lungs depends on the concentration of radon gas and radon daughters in the air.

The concentration of radon gas is measured in units of picocuries per litre (pCi/L) or becquerels per cubic metre (Bq/m3) of ambient air. The concentration of radon daughters is measured in working level (WL) units which is a measure of the concentration of potential alpha particles per litre of air.

The worker's exposure to radon daughters is expressed in units of Working Level Months (WLM). One WLM is equivalent to 1 WL exposure for 170 hours.

1 WL = 130,000 MeV alpha energy per litre air

          = 20.8 µJ (microjoules) alpha energy per cubic meter (m3) air

WLM = Working Level Month

         = 1 WL exposure for 170 hours

1 WLM = 3.5 mJ-h/m3

Often people use the concentration of radon gas (pCi/L) in the air to estimate the WL level of radon daughters. Such estimates are subject to error because the ratio of radon to its decay products (radon daughters) is not constant.

Equilibrium factor is the ratio of the activity of all the short-lived radon daughters to the activity of the parent radon gas. Equilibrium factor is 1 when both are equal. Radon daughter activities are usually less than the radon activity, and hence, the equilibrium factor is usually less than 1.

Conversion of radon exposure units (equilibrium factor = 0.40)

1 WLM = 3.54 mJ-h/m3

1 MBq-h/m3 = 2.22 mJ-h/m3

1 MBq-h/m3 = 0.628 WLM 

Annual exposure from measured radon concentration

(A) At home: assuming 7000 hours spend indoors per year

1 Bq/m3 = 0.0156 mJ-h/m3

1 Bq/m3 = 0.0044 WLM 

1 WLM - 4 mSv

1 mJ-h/m3 = mSv

(B) At work: assuming 2000 hours per year

1 Bq/m3 = 0.00445 mJ-h/m3 = 0.00126WLM

1 mJ-h/m3 = 1.4 mSv

1 WLM = 5 mSv

Source: ICRP Publication 65, Protection against Radon at Home and Work

 

mJ-h/m3 = millijoule hours/per cubic metre

MBq-h/m3 = megabecquerel hours per cubic meter

Joule is unit of energy

1 J = 1 Watt-second = Energy delivered in one second by a 1 Watt power source

1 calorie = 4.2 J

MBq/m3 = megabecquerel per cubic metre

WLM = Working Level Months


  • Fact sheet last revised: 2024-04-23