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Background radiation

January 26, 2023

For background radiation from space, see cosmic background radiation.

Background radiation is a measure of the level of ionizing radiation present in the environment at a particular location which is not due to deliberate introduction of radiation sources.

Background radiation originates from a variety of sources, both natural and artificial. These include both cosmic radiation and environmental radioactivity from naturally occurring radioactive materials (such as radon and radium), as well as man-made medical X-rays, fallout from nuclear weapons testing and nuclear accidents.

Definition

Background radiation is defined by the International Atomic Energy Agency as "Dose or dose rate (or an observed measure related to the dose or dose rate) attributable to all sources other than the one(s) specified.[1] So a distinction is made between dose which is already in a location, which is defined here as being "background", and the dose due to a deliberately introduced and specified source. This is important where radiation measurements are taken of a specified radiation source, where the existing background may affect this measurement. An example would be measurement of radioactive contamination in a gamma radiation background, which could increase the total reading above that expected from the contamination alone.

However, if no radiation source is specified as being of concern, then the total radiation dose measurement at a location is generally called the background radiation, and this is usually the case where an ambient dose rate is measured for environmental purposes.

Background dose rate examples

Background radiation varies with location and time, and the following table gives examples:

Average annual human exposure to ionizing radiation in millisieverts (mSv) per year
Radiation source World[2] US[3] Japan[4] Remark
Inhalation of air 1.26 2.28 0.40 mainly from radon, depends on indoor accumulation
Ingestion of food & water 0.29 0.28 0.40 (K-40, C-14, etc.)
Terrestrial radiation from ground 0.48 0.21 0.40 depends on soil and building material
Cosmic radiation from space 0.39 0.33 0.30 depends on altitude
sub total (natural) 2.40 3.10 1.50 sizeable population groups receive 10–20 mSv
Medical 0.60 3.00 2.30 worldwide figure excludes radiotherapy;
US figure is mostly CT scans and nuclear medicine.
Consumer items 0.13 cigarettes, air travel, building materials, etc.
Atmospheric nuclear testing 0.005 0.01 peak of 0.11 mSv in 1963 and declining since; higher near sites
Occupational exposure 0.005 0.005 0.01 worldwide average to workers only is 0.7 mSv, mostly due to radon in mines;[2]
US is mostly due to medical and aviation workers.[3]
Chernobyl accident 0.002 0.01 peak of 0.04 mSv in 1986 and declining since; higher near site
Nuclear fuel cycle 0.0002 0.001 up to 0.02 mSv near sites; excludes occupational exposure
Other 0.003 Industrial, security, medical, educational, and research
sub total (artificial) 0.61 3.14 2.33
Total 3.01 6.24 3.83 millisieverts per year

Natural background radiation

 
The weather station outside of the Atomic Testing Museum on a hot summer day. Displayed background gamma radiation level is 9.8 μR/h (0.82 mSv/a) This is very close to the world average background radiation of 0.87 mSv/a from cosmic and terrestrial sources.
 
Cloud chambers used by early researchers first detected cosmic rays and other background radiation. They can be used to visualize the background radiation

Radioactive material is found throughout nature. Detectable amounts occur naturally in soil, rocks, water, air, and vegetation, from which it is inhaled and ingested into the body. In addition to this internal exposure, humans also receive external exposure from radioactive materials that remain outside the body and from cosmic radiation from space. The worldwide average natural dose to humans is about 2.4 mSv (240 mrem) per year.[2] This is four times the worldwide average artificial radiation exposure, which in 2008 amounted to about 0.6 millisieverts (60 mrem) per year. In some developed countries, like the US and Japan, artificial exposure is, on average, greater than the natural exposure, due to greater access to medical imaging. In Europe, average natural background exposure by country ranges from under 2 mSv (200 mrem) annually in the United Kingdom to more than 7 mSv (700 mrem) annually for some groups of people in Finland.[5]

The International Atomic Energy Agency states:

"Exposure to radiation from natural sources is an inescapable feature of everyday life in both working and public environments. This exposure is in most cases of little or no concern to society, but in certain situations the introduction of health protection measures needs to be considered, for example when working with uranium and thorium ores and other Naturally Occurring Radioactive Material (NORM). These situations have become the focus of greater attention by the Agency in recent years."[6]

Terrestrial sources

Main article: Environmental radioactivity

Terrestrial radiation, for the purpose of the table above, only includes sources that remain external to the body. The major radionuclides of concern are potassium, uranium and thorium and their decay products, some of which, like radium and radon are intensely radioactive but occur in low concentrations. Most of these sources have been decreasing, due to radioactive decay since the formation of the Earth, because there is no significant amount currently transported to the Earth. Thus, the present activity on earth from uranium-238 is only half as much as it originally was because of its 4.5 billion year half-life, and potassium-40 (half-life 1.25 billion years) is only at about 8% of original activity. But during the time that humans have existed the amount of radiation has decreased very little.

Many shorter half-life (and thus more intensely radioactive) isotopes have not decayed out of the terrestrial environment because of their on-going natural production. Examples of these are radium-226 (decay product of thorium-230 in decay chain of uranium-238) and radon-222 (a decay product of radium-226 in said chain).

Thorium and uranium (and their daughters) primarily undergo alpha and beta decay, and aren't easily detectable. However, many of their daughter products are strong gamma emitters. Thorium-232 is detectable via a 239 keV peak from lead-212, 511, 583 and 2614 keV from thallium-208, and 911 and 969 keV from actinium-228. Uranium-238 manifests as 609, 1120, and 1764 keV peaks of bismuth-214 (cf. the same peak for atmospheric radon). Potassium-40 is detectable directly via its 1461 keV gamma peak.[7]

The level over the sea and other large bodies of water tends to be about a tenth of the terrestrial background. Conversely, coastal areas (and areas by the side of fresh water) may have an additional contribution from dispersed sediment.[7]

Airborne sources

The biggest source of natural background radiation is airborne radon, a radioactive gas that emanates from the ground. Radon and its isotopes, parent radionuclides, and decay products all contribute to an average inhaled dose of 1.26 mSv/a (millisievert per year). Radon is unevenly distributed and varies with weather, such that much higher doses apply to many areas of the world, where it represents a significant health hazard. Concentrations over 500 times the world average have been found inside buildings in Scandinavia, the United States, Iran, and the Czech Republic.[8] Radon is a decay product of uranium, which is relatively common in the Earth's crust, but more concentrated in ore-bearing rocks scattered around the world. Radon seeps out of these ores into the atmosphere or into ground water or infiltrates into buildings. It can be inhaled into the lungs, along with its decay products, where they will reside for a period of time after exposure.

Although radon is naturally occurring, exposure can be enhanced or diminished by human activity, notably house construction. A poorly sealed dwelling floor, or poor basement ventilation, in an otherwise well insulated house can result in the accumulation of radon within the dwelling, exposing its residents to high concentrations. The widespread construction of well insulated and sealed homes in the northern industrialized world has led to radon becoming the primary source of background radiation in some localities in northern North America and Europe.[citation needed] Basement sealing and suction ventilation reduce exposure. Some building materials, for example lightweight concrete with alum shale, phosphogypsum and Italian tuff, may emanate radon if they contain radium and are porous to gas.[8]

Radiation exposure from radon is indirect. Radon has a short half-life (4 days) and decays into other solid particulate radium-series radioactive nuclides. These radioactive particles are inhaled and remain lodged in the lungs, causing continued exposure. Radon is thus assumed to be the second leading cause of lung cancer after smoking, and accounts for 15,000 to 22,000 cancer deaths per year in the US alone.[9][better source needed] However, the discussion about the opposite experimental results is still going on.[10]

About 100,000 Bq/m3 of radon was found in Stanley Watras's basement in 1984.[11][12] He and his neighbours in Boyertown, Pennsylvania, United States may hold the record for the most radioactive dwellings in the world. International radiation protection organizations estimate that a committed dose may be calculated by multiplying the equilibrium equivalent concentration (EEC) of radon by a factor of 8 to 9 nSv·m3/Bq·h and the EEC of thoron by a factor of 40 nSv·m3/Bq·h.[2]

Most of the atmospheric background is caused by radon and its decay products. The gamma spectrum shows prominent peaks at 609, 1120, and 1764 keV, belonging to bismuth-214, a radon decay product. The atmospheric background varies greatly with wind direction and meteorological conditions. Radon also can be released from the ground in bursts and then form "radon clouds" capable of traveling tens of kilometers.[7]

Cosmic radiation

Main article: Cosmic ray
 
Estimate of the maximum dose of radiation received at an altitude of 12 km 20 January 2005, following a violent solar flare. The doses are expressed in microsieverts per hour.

The Earth and all living things on it are constantly bombarded by radiation from outer space. This radiation primarily consists of positively charged ions from protons to iron and larger nuclei derived from outside the Solar System. This radiation interacts with atoms in the atmosphere to create an air shower of secondary radiation, including X-rays, muons, protons, alpha particles, pions, electrons, and neutrons. The immediate dose from cosmic radiation is largely from muons, neutrons, and electrons, and this dose varies in different parts of the world based largely on the geomagnetic field and altitude. For example, the city of Denver in the United States (at 1650 meters elevation) receives a cosmic ray dose roughly twice that of a location at sea level.[13] This radiation is much more intense in the upper troposphere, around 10 km altitude, and is thus of particular concern for airline crews and frequent passengers, who spend many hours per year in this environment. During their flights airline crews typically get an additional occupational dose between 2.2 mSv (220 mrem) per year [14] and 2.19 mSv/year,[15] according to various studies.[16]

Similarly, cosmic rays cause higher background exposure in astronauts than in humans on the surface of Earth. Astronauts in low orbits, such as in the International Space Station or the Space Shuttle, are partially shielded by the magnetic field of the Earth, but also suffer from the Van Allen radiation belt which accumulates cosmic rays and results from the Earth's magnetic field. Outside low Earth orbit, as experienced by the Apollo astronauts who traveled to the Moon, this background radiation is much more intense, and represents a considerable obstacle to potential future long term human exploration of the moon or Mars.

Cosmic rays also cause elemental transmutation in the atmosphere, in which secondary radiation generated by the cosmic rays combines with atomic nuclei in the atmosphere to generate different nuclides. Many so-called cosmogenic nuclides can be produced, but probably the most notable is carbon-14, which is produced by interactions with nitrogen atoms. These cosmogenic nuclides eventually reach the Earth's surface and can be incorporated into living organisms. The production of these nuclides varies slightly with short-term variations in solar cosmic ray flux, but is considered practically constant over long scales of thousands to millions of years. The constant production, incorporation into organisms and relatively short half-life of carbon-14 are the principles used in radiocarbon dating of ancient biological materials, such as wooden artifacts or human remains.

The cosmic radiation at sea level usually manifests as 511 keV gamma rays from annihilation of positrons created by nuclear reactions of high energy particles and gamma rays. At higher altitudes there is also the contribution of continuous bremsstrahlung spectrum.[7]

Food and water

Two of the essential elements that make up the human body, namely potassium and carbon, have radioactive isotopes that add significantly to our background radiation dose. An average human contains about 17 milligrams of potassium-40 (40K) and about 24 nanograms (10−9 g) of carbon-14 (14C),[17] (half-life 5,730 years). Excluding internal contamination by external radioactive material, these two are the largest components of internal radiation exposure from biologically functional components of the human body. About 4,000 nuclei of 40K [18] decay per second, and a similar number of 14C. The energy of beta particles produced by 40K is about 10 times that from the beta particles from 14C decay.

14C is present in the human body at a level of about 3700 Bq (0.1 μCi) with a biological half-life of 40 days.[19] This means there are about 3700 beta particles per second produced by the decay of 14C. However, a 14C atom is in the genetic information of about half the cells, while potassium is not a component of DNA. The decay of a 14C atom inside DNA in one person happens about 50 times per second, changing a carbon atom to one of nitrogen.[20]

The global average internal dose from radionuclides other than radon and its decay products is 0.29 mSv/a, of which 0.17 mSv/a comes from 40K, 0.12 mSv/a comes from the uranium and thorium series, and 12 μSv/a comes from 14C.[2]

Areas with high natural background radiation

Some areas have greater dosage than the country-wide averages.[21] In the world in general, exceptionally high natural background locales include Ramsar in Iran, Guarapari in Brazil, Karunagappalli in India,[22] Arkaroola in Australia[23] and Yangjiang in China.[24]

The highest level of purely natural radiation ever recorded on the Earth's surface was 90 µGy/h on a Brazilian black beach (areia preta in Portuguese) composed of monazite.[25] This rate would convert to 0.8 Gy/a for year-round continuous exposure, but in fact the levels vary seasonally and are much lower in the nearest residences. The record measurement has not been duplicated and is omitted from UNSCEAR's latest reports. Nearby tourist beaches in Guarapari and Cumuruxatiba were later evaluated at 14 and 15 µGy/h.[26][27] Note that the values quoted here are in Grays. To convert to Sieverts (Sv) a radiation weighting factor is required; these weighting factors vary from 1 (beta & gamma) to 20 (alpha particles).

The highest background radiation in an inhabited area is found in Ramsar, primarily due to the use of local naturally radioactive limestone as a building material. The 1000 most exposed residents receive an average external effective radiation dose of 6 mSv (600 mrem) per year, six times the ICRP recommended limit for exposure to the public from artificial sources.[28] They additionally receive a substantial internal dose from radon. Record radiation levels were found in a house where the effective dose due to ambient radiation fields was 131 mSv (13.1 rem) per year, and the internal committed dose from radon was 72 mSv (7.2 rem) per year.[28] This unique case is over 80 times higher than the world average natural human exposure to radiation.

Epidemiological studies are underway to identify health effects associated with the high radiation levels in Ramsar. It is much too early to draw unambiguous statistically significant conclusions.[28] While so far support for beneficial effects of chronic radiation (like longer lifespan) has been observed in few places only,[28] a protective and adaptive effect is suggested by at least one study whose authors nonetheless caution that data from Ramsar are not yet sufficiently strong to relax existing regulatory dose limits.[29] However, the recent statistical analyses discussed that there is no correlation between the risk of negative health effects and elevated level of natural background radiation.[30]

Photoelectric

Background radiation doses in the immediate vicinity of particles of high atomic number materials, within the human body, have a small enhancement due to the photoelectric effect.[31]

Neutron background

Most of the natural neutron background is a product of cosmic rays interacting with the atmosphere. The neutron energy peaks at around 1 MeV and rapidly drops above. At sea level, the production of neutrons is about 20 neutrons per second per kilogram of material interacting with the cosmic rays (or, about 100–300 neutrons per square meter per second). The flux is dependent on geomagnetic latitude, with a maximum near the magnetic poles. At solar minimums, due to lower solar magnetic field shielding, the flux is about twice as high vs the solar maximum. It also dramatically increases during solar flares. In the vicinity of larger heavier objects, e.g. buildings or ships, the neutron flux measures higher; this is known as "cosmic ray induced neutron signature", or "ship effect" as it was first detected with ships at sea.[7]

Artificial background radiation

 
Displays showing ambient radiation fields of 0.120–0.130 μSv/h (1.05–1.14 mSv/a) in a nuclear power plant. This reading includes natural background from cosmic and terrestrial sources.

Atmospheric nuclear testing

 
Per capita thyroid doses in the continental United States resulting from all exposure routes from all atmospheric nuclear tests conducted at the Nevada Test Site from 1951 to 1962.
 
Atmospheric 14C, New Zealand[32] and Austria.[33] The New Zealand curve is representative for the Southern Hemisphere, the Austrian curve is representative for the Northern Hemisphere. Atmospheric nuclear weapon tests almost doubled the concentration of 14C in the Northern Hemisphere.[34]

Frequent above-ground nuclear explosions between the 1940s and 1960s scattered a substantial amount of radioactive contamination. Some of this contamination is local, rendering the immediate surroundings highly radioactive, while some of it is carried longer distances as nuclear fallout; some of this material is dispersed worldwide. The increase in background radiation due to these tests peaked in 1963 at about 0.15 mSv per year worldwide, or about 7% of average background dose from all sources. The Limited Test Ban Treaty of 1963 prohibited above-ground tests, thus by the year 2000 the worldwide dose from these tests has decreased to only 0.005 mSv per year.[35]

Occupational exposure

The International Commission on Radiological Protection recommends limiting occupational radiation exposure to 50 mSv (5 rem) per year, and 100 mSv (10 rem) in 5 years.[36]

However, background radiation for occupational doses includes radiation that is not measured by radiation dose instruments in potential occupational exposure conditions. This includes both offsite "natural background radiation" and any medical radiation doses. This value is not typically measured or known from surveys, such that variations in the total dose to individual workers is not known. This can be a significant confounding factor in assessing radiation exposure effects in a population of workers who may have significantly different natural background and medical radiation doses. This is most significant when the occupational doses are very low.

At an IAEA conference in 2002, it was recommended that occupational doses below 1–2 mSv per year do not warrant regulatory scrutiny.[37]

Nuclear accidents

 
Radiation level in a range of situations, from normal activities up to the nuclear accidents. Each step up the scale indicates a tenfold increase in radiation level.

Under normal circumstances, nuclear reactors release small amounts of radioactive gases, which cause small radiation exposures to the public. Events classified on the International Nuclear Event Scale as incidents typically do not release any additional radioactive substances into the environment. Large releases of radioactivity from nuclear reactors are extremely rare. To the present day, there were two major civilian accidents – the Chernobyl accident and the Fukushima I nuclear accidents – which caused substantial contamination. The Chernobyl accident was the only one to cause immediate deaths.

Total doses from the Chernobyl accident ranged from 10 to 50 mSv over 20 years for the inhabitants of the affected areas, with most of the dose received in the first years after the disaster, and over 100 mSv for liquidators. There were 28 deaths from acute radiation syndrome.[38]

Total doses from the Fukushima I accidents were between 1 and 15 mSv for the inhabitants of the affected areas. Thyroid doses for children were below 50 mSv. 167 cleanup workers received doses above 100 mSv, with 6 of them receiving more than 250 mSv (the Japanese exposure limit for emergency response workers).[39]

The average dose from the Three Mile Island accident was 0.01 mSv.[40]

Non-civilian: In addition to the civilian accidents described above, several accidents at early nuclear weapons facilities – such as the Windscale fire, the contamination of the Techa River by the nuclear waste from the Mayak compound, and the Kyshtym disaster at the same compound – released substantial radioactivity into the environment. The Windscale fire resulted in thyroid doses of 5–20 mSv for adults and 10–60 mSv for children.[41] The doses from the accidents at Mayak are unknown.

Nuclear fuel cycle

The Nuclear Regulatory Commission, the United States Environmental Protection Agency, and other U.S. and international agencies, require that licensees limit radiation exposure to individual members of the public to 1 mSv (100 mrem) per year.

Energy sources

Per UNECE life-cycle assessment, nearly all sources of energy result in some level of occupational and public exposure to radionuclides as result of their manufacturing or operations. The following table uses man·Sievert/GW-annum:[42]

Source Public Occupational
Nuclear power 0.43 4.5
Coal (modern) 0.7 11
Coal (older) 1.4 11
Natural gas 0.1 0.02
Oil 0.0003 0.15
Geothermal 1–20 0.05
Solar power 0.8
Wind power 0.1
Biomass 0.01

Coal burning

Coal plants emit radiation in the form of radioactive fly ash which is inhaled and ingested by neighbours, and incorporated into crops. A 1978 paper from Oak Ridge National Laboratory estimated that coal-fired power plants of that time may contribute a whole-body committed dose of 19 µSv/a to their immediate neighbours in a radius of 500 m.[43] The United Nations Scientific Committee on the Effects of Atomic Radiation's 1988 report estimated the committed dose 1 km away to be 20 µSv/a for older plants or 1 µSv/a for newer plants with improved fly ash capture, but was unable to confirm these numbers by test.[44] When coal is burned, uranium, thorium and all the uranium daughters accumulated by disintegration – radium, radon, polonium – are released.[45] Radioactive materials previously buried underground in coal deposits are released as fly ash or, if fly ash is captured, may be incorporated into concrete manufactured with fly ash.

Other sources of dose uptake

Medical

The global average human exposure to artificial radiation is 0.6 mSv/a, primarily from medical imaging. This medical component can range much higher, with an average of 3 mSv per year across the USA population.[3] Other human contributors include smoking, air travel, radioactive building materials, historical nuclear weapons testing, nuclear power accidents and nuclear industry operation.

A typical chest x-ray delivers 20 µSv (2 mrem) of effective dose.[46] A dental x-ray delivers a dose of 5 to 10 µSv.[47] A CT scan delivers an effective dose to the whole body ranging from 1 to 20 mSv (100 to 2000 mrem). The average American receives about 3 mSv of diagnostic medical dose per year; countries with the lowest levels of health care receive almost none. Radiation treatment for various diseases also accounts for some dose, both in individuals and in those around them.

Consumer items

Cigarettes contain polonium-210, originating from the decay products of radon, which stick to tobacco leaves. Heavy smoking results in a radiation dose of 160 mSv/year to localized spots at the bifurcations of segmental bronchi in the lungs from the decay of polonium-210. This dose is not readily comparable to the radiation protection limits, since the latter deal with whole body doses, while the dose from smoking is delivered to a very small portion of the body.[48]

Radiation metrology

In a radiation metrology laboratory, background radiation refers to the measured value from any incidental sources that affect an instrument when a specific radiation source sample is being measured. This background contribution, which is established as a stable value by multiple measurements, usually before and after sample measurement, is subtracted from the rate measured when the sample is being measured.

This is in accordance with the International Atomic Energy Agency definition of background as being "Dose or dose rate (or an observed measure related to the dose or dose rate) attributable to all sources other than the one(s) specified.[1]

The same issue occurs with radiation protection instruments, where a reading from an instrument may be affected by the background radiation. An example of this is a scintillation detector used for surface contamination monitoring. In an elevated gamma background the scintillator material will be affected by the background gamma, which will add to the reading obtained from any contamination which is being monitored. In extreme cases it will make the instrument unusable as the background swamps the lower level of radiation from the contamination. In such instruments the background can be continually monitored in the "Ready" state, and subtracted from any reading obtained when being used in "Measuring" mode.

Regular Radiation measurement is carried out at multiple levels. Government agencies compile radiation readings as part of environmental monitoring mandates, often making the readings available to the public and sometimes in near-real-time. Collaborative groups and private individuals may also make real-time readings available to the public. Instruments used for radiation measurement include the Geiger–Müller tube and the Scintillation detector. The former is usually more compact and affordable and reacts to several radiation types, while the latter is more complex and can detect specific radiation energies and types. Readings indicate radiation levels from all sources including background, and real-time readings are in general unvalidated, but correlation between independent detectors increases confidence in measured levels.

List of near-real-time government radiation measurement sites, employing multiple instrument types:

  • Europe and Canada: European Radiological Data Exchange Platform (EURDEP) Simple map of Gamma Dose Rates
  • USA: EPA Radnet near-real-time and laboratory data by state

List of international near-real-time collaborative/private measurement sites, employing primarily Geiger-Muller detectors:

See also

References

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External links

January 26, 2023
background, radiation, background, radiation, from, space, cosmic, background, radiation, measure, level, ionizing, radiation, present, environment, particular, location, which, deliberate, introduction, radiation, sources, originates, from, variety, sources, . For background radiation from space see cosmic background radiation Background radiation is a measure of the level of ionizing radiation present in the environment at a particular location which is not due to deliberate introduction of radiation sources Background radiation originates from a variety of sources both natural and artificial These include both cosmic radiation and environmental radioactivity from naturally occurring radioactive materials such as radon and radium as well as man made medical X rays fallout from nuclear weapons testing and nuclear accidents Contents 1 Definition 2 Background dose rate examples 3 Natural background radiation 3 1 Terrestrial sources 3 2 Airborne sources 3 3 Cosmic radiation 3 4 Food and water 3 5 Areas with high natural background radiation 3 6 Photoelectric 3 7 Neutron background 4 Artificial background radiation 4 1 Atmospheric nuclear testing 4 2 Occupational exposure 4 3 Nuclear accidents 4 4 Nuclear fuel cycle 4 5 Energy sources 4 5 1 Coal burning 5 Other sources of dose uptake 5 1 Medical 5 2 Consumer items 6 Radiation metrology 7 See also 8 References 9 External linksDefinition EditBackground radiation is defined by the International Atomic Energy Agency as Dose or dose rate or an observed measure related to the dose or dose rate attributable to all sources other than the one s specified 1 So a distinction is made between dose which is already in a location which is defined here as being background and the dose due to a deliberately introduced and specified source This is important where radiation measurements are taken of a specified radiation source where the existing background may affect this measurement An example would be measurement of radioactive contamination in a gamma radiation background which could increase the total reading above that expected from the contamination alone However if no radiation source is specified as being of concern then the total radiation dose measurement at a location is generally called the background radiation and this is usually the case where an ambient dose rate is measured for environmental purposes Background dose rate examples EditBackground radiation varies with location and time and the following table gives examples Average annual human exposure to ionizing radiation in millisieverts mSv per year Radiation source World 2 US 3 Japan 4 RemarkInhalation of air 1 26 2 28 0 40 mainly from radon depends on indoor accumulationIngestion of food amp water 0 29 0 28 0 40 K 40 C 14 etc Terrestrial radiation from ground 0 48 0 21 0 40 depends on soil and building materialCosmic radiation from space 0 39 0 33 0 30 depends on altitudesub total natural 2 40 3 10 1 50 sizeable population groups receive 10 20 mSvMedical 0 60 3 00 2 30 worldwide figure excludes radiotherapy US figure is mostly CT scans and nuclear medicine Consumer items 0 13 cigarettes air travel building materials etc Atmospheric nuclear testing 0 005 0 01 peak of 0 11 mSv in 1963 and declining since higher near sitesOccupational exposure 0 005 0 005 0 01 worldwide average to workers only is 0 7 mSv mostly due to radon in mines 2 US is mostly due to medical and aviation workers 3 Chernobyl accident 0 002 0 01 peak of 0 04 mSv in 1986 and declining since higher near siteNuclear fuel cycle 0 0002 0 001 up to 0 02 mSv near sites excludes occupational exposureOther 0 003 Industrial security medical educational and researchsub total artificial 0 61 3 14 2 33Total 3 01 6 24 3 83 millisieverts per yearNatural background radiation Edit The weather station outside of the Atomic Testing Museum on a hot summer day Displayed background gamma radiation level is 9 8 mR h 0 82 mSv a This is very close to the world average background radiation of 0 87 mSv a from cosmic and terrestrial sources Cloud chambers used by early researchers first detected cosmic rays and other background radiation They can be used to visualize the background radiation Radioactive material is found throughout nature Detectable amounts occur naturally in soil rocks water air and vegetation from which it is inhaled and ingested into the body In addition to this internal exposure humans also receive external exposure from radioactive materials that remain outside the body and from cosmic radiation from space The worldwide average natural dose to humans is about 2 4 mSv 240 mrem per year 2 This is four times the worldwide average artificial radiation exposure which in 2008 amounted to about 0 6 millisieverts 60 mrem per year In some developed countries like the US and Japan artificial exposure is on average greater than the natural exposure due to greater access to medical imaging In Europe average natural background exposure by country ranges from under 2 mSv 200 mrem annually in the United Kingdom to more than 7 mSv 700 mrem annually for some groups of people in Finland 5 The International Atomic Energy Agency states Exposure to radiation from natural sources is an inescapable feature of everyday life in both working and public environments This exposure is in most cases of little or no concern to society but in certain situations the introduction of health protection measures needs to be considered for example when working with uranium and thorium ores and other Naturally Occurring Radioactive Material NORM These situations have become the focus of greater attention by the Agency in recent years 6 Terrestrial sources Edit Main article Environmental radioactivity Terrestrial radiation for the purpose of the table above only includes sources that remain external to the body The major radionuclides of concern are potassium uranium and thorium and their decay products some of which like radium and radon are intensely radioactive but occur in low concentrations Most of these sources have been decreasing due to radioactive decay since the formation of the Earth because there is no significant amount currently transported to the Earth Thus the present activity on earth from uranium 238 is only half as much as it originally was because of its 4 5 billion year half life and potassium 40 half life 1 25 billion years is only at about 8 of original activity But during the time that humans have existed the amount of radiation has decreased very little Many shorter half life and thus more intensely radioactive isotopes have not decayed out of the terrestrial environment because of their on going natural production Examples of these are radium 226 decay product of thorium 230 in decay chain of uranium 238 and radon 222 a decay product of radium 226 in said chain Thorium and uranium and their daughters primarily undergo alpha and beta decay and aren t easily detectable However many of their daughter products are strong gamma emitters Thorium 232 is detectable via a 239 keV peak from lead 212 511 583 and 2614 keV from thallium 208 and 911 and 969 keV from actinium 228 Uranium 238 manifests as 609 1120 and 1764 keV peaks of bismuth 214 cf the same peak for atmospheric radon Potassium 40 is detectable directly via its 1461 keV gamma peak 7 The level over the sea and other large bodies of water tends to be about a tenth of the terrestrial background Conversely coastal areas and areas by the side of fresh water may have an additional contribution from dispersed sediment 7 Airborne sources Edit The biggest source of natural background radiation is airborne radon a radioactive gas that emanates from the ground Radon and its isotopes parent radionuclides and decay products all contribute to an average inhaled dose of 1 26 mSv a millisievert per year Radon is unevenly distributed and varies with weather such that much higher doses apply to many areas of the world where it represents a significant health hazard Concentrations over 500 times the world average have been found inside buildings in Scandinavia the United States Iran and the Czech Republic 8 Radon is a decay product of uranium which is relatively common in the Earth s crust but more concentrated in ore bearing rocks scattered around the world Radon seeps out of these ores into the atmosphere or into ground water or infiltrates into buildings It can be inhaled into the lungs along with its decay products where they will reside for a period of time after exposure Although radon is naturally occurring exposure can be enhanced or diminished by human activity notably house construction A poorly sealed dwelling floor or poor basement ventilation in an otherwise well insulated house can result in the accumulation of radon within the dwelling exposing its residents to high concentrations The widespread construction of well insulated and sealed homes in the northern industrialized world has led to radon becoming the primary source of background radiation in some localities in northern North America and Europe citation needed Basement sealing and suction ventilation reduce exposure Some building materials for example lightweight concrete with alum shale phosphogypsum and Italian tuff may emanate radon if they contain radium and are porous to gas 8 Radiation exposure from radon is indirect Radon has a short half life 4 days and decays into other solid particulate radium series radioactive nuclides These radioactive particles are inhaled and remain lodged in the lungs causing continued exposure Radon is thus assumed to be the second leading cause of lung cancer after smoking and accounts for 15 000 to 22 000 cancer deaths per year in the US alone 9 better source needed However the discussion about the opposite experimental results is still going on 10 About 100 000 Bq m3 of radon was found in Stanley Watras s basement in 1984 11 12 He and his neighbours in Boyertown Pennsylvania United States may hold the record for the most radioactive dwellings in the world International radiation protection organizations estimate that a committed dose may be calculated by multiplying the equilibrium equivalent concentration EEC of radon by a factor of 8 to 9 nSv m3 Bq h and the EEC of thoron by a factor of 40 nSv m3 Bq h 2 Most of the atmospheric background is caused by radon and its decay products The gamma spectrum shows prominent peaks at 609 1120 and 1764 keV belonging to bismuth 214 a radon decay product The atmospheric background varies greatly with wind direction and meteorological conditions Radon also can be released from the ground in bursts and then form radon clouds capable of traveling tens of kilometers 7 Cosmic radiation Edit Main article Cosmic ray Estimate of the maximum dose of radiation received at an altitude of 12 km 20 January 2005 following a violent solar flare The doses are expressed in microsieverts per hour The Earth and all living things on it are constantly bombarded by radiation from outer space This radiation primarily consists of positively charged ions from protons to iron and larger nuclei derived from outside the Solar System This radiation interacts with atoms in the atmosphere to create an air shower of secondary radiation including X rays muons protons alpha particles pions electrons and neutrons The immediate dose from cosmic radiation is largely from muons neutrons and electrons and this dose varies in different parts of the world based largely on the geomagnetic field and altitude For example the city of Denver in the United States at 1650 meters elevation receives a cosmic ray dose roughly twice that of a location at sea level 13 This radiation is much more intense in the upper troposphere around 10 km altitude and is thus of particular concern for airline crews and frequent passengers who spend many hours per year in this environment During their flights airline crews typically get an additional occupational dose between 2 2 mSv 220 mrem per year 14 and 2 19 mSv year 15 according to various studies 16 Similarly cosmic rays cause higher background exposure in astronauts than in humans on the surface of Earth Astronauts in low orbits such as in the International Space Station or the Space Shuttle are partially shielded by the magnetic field of the Earth but also suffer from the Van Allen radiation belt which accumulates cosmic rays and results from the Earth s magnetic field Outside low Earth orbit as experienced by the Apollo astronauts who traveled to the Moon this background radiation is much more intense and represents a considerable obstacle to potential future long term human exploration of the moon or Mars Cosmic rays also cause elemental transmutation in the atmosphere in which secondary radiation generated by the cosmic rays combines with atomic nuclei in the atmosphere to generate different nuclides Many so called cosmogenic nuclides can be produced but probably the most notable is carbon 14 which is produced by interactions with nitrogen atoms These cosmogenic nuclides eventually reach the Earth s surface and can be incorporated into living organisms The production of these nuclides varies slightly with short term variations in solar cosmic ray flux but is considered practically constant over long scales of thousands to millions of years The constant production incorporation into organisms and relatively short half life of carbon 14 are the principles used in radiocarbon dating of ancient biological materials such as wooden artifacts or human remains The cosmic radiation at sea level usually manifests as 511 keV gamma rays from annihilation of positrons created by nuclear reactions of high energy particles and gamma rays At higher altitudes there is also the contribution of continuous bremsstrahlung spectrum 7 Food and water Edit Two of the essential elements that make up the human body namely potassium and carbon have radioactive isotopes that add significantly to our background radiation dose An average human contains about 17 milligrams of potassium 40 40K and about 24 nanograms 10 9 g of carbon 14 14C 17 half life 5 730 years Excluding internal contamination by external radioactive material these two are the largest components of internal radiation exposure from biologically functional components of the human body About 4 000 nuclei of 40K 18 decay per second and a similar number of 14C The energy of beta particles produced by 40K is about 10 times that from the beta particles from 14C decay 14C is present in the human body at a level of about 3700 Bq 0 1 mCi with a biological half life of 40 days 19 This means there are about 3700 beta particles per second produced by the decay of 14C However a 14C atom is in the genetic information of about half the cells while potassium is not a component of DNA The decay of a 14C atom inside DNA in one person happens about 50 times per second changing a carbon atom to one of nitrogen 20 The global average internal dose from radionuclides other than radon and its decay products is 0 29 mSv a of which 0 17 mSv a comes from 40K 0 12 mSv a comes from the uranium and thorium series and 12 mSv a comes from 14C 2 Areas with high natural background radiation Edit Some areas have greater dosage than the country wide averages 21 In the world in general exceptionally high natural background locales include Ramsar in Iran Guarapari in Brazil Karunagappalli in India 22 Arkaroola in Australia 23 and Yangjiang in China 24 The highest level of purely natural radiation ever recorded on the Earth s surface was 90 µGy h on a Brazilian black beach areia preta in Portuguese composed of monazite 25 This rate would convert to 0 8 Gy a for year round continuous exposure but in fact the levels vary seasonally and are much lower in the nearest residences The record measurement has not been duplicated and is omitted from UNSCEAR s latest reports Nearby tourist beaches in Guarapari and Cumuruxatiba were later evaluated at 14 and 15 µGy h 26 27 Note that the values quoted here are in Grays To convert to Sieverts Sv a radiation weighting factor is required these weighting factors vary from 1 beta amp gamma to 20 alpha particles The highest background radiation in an inhabited area is found in Ramsar primarily due to the use of local naturally radioactive limestone as a building material The 1000 most exposed residents receive an average external effective radiation dose of 6 mSv 600 mrem per year six times the ICRP recommended limit for exposure to the public from artificial sources 28 They additionally receive a substantial internal dose from radon Record radiation levels were found in a house where the effective dose due to ambient radiation fields was 131 mSv 13 1 rem per year and the internal committed dose from radon was 72 mSv 7 2 rem per year 28 This unique case is over 80 times higher than the world average natural human exposure to radiation Epidemiological studies are underway to identify health effects associated with the high radiation levels in Ramsar It is much too early to draw unambiguous statistically significant conclusions 28 While so far support for beneficial effects of chronic radiation like longer lifespan has been observed in few places only 28 a protective and adaptive effect is suggested by at least one study whose authors nonetheless caution that data from Ramsar are not yet sufficiently strong to relax existing regulatory dose limits 29 However the recent statistical analyses discussed that there is no correlation between the risk of negative health effects and elevated level of natural background radiation 30 Photoelectric Edit Background radiation doses in the immediate vicinity of particles of high atomic number materials within the human body have a small enhancement due to the photoelectric effect 31 Neutron background Edit Most of the natural neutron background is a product of cosmic rays interacting with the atmosphere The neutron energy peaks at around 1 MeV and rapidly drops above At sea level the production of neutrons is about 20 neutrons per second per kilogram of material interacting with the cosmic rays or about 100 300 neutrons per square meter per second The flux is dependent on geomagnetic latitude with a maximum near the magnetic poles At solar minimums due to lower solar magnetic field shielding the flux is about twice as high vs the solar maximum It also dramatically increases during solar flares In the vicinity of larger heavier objects e g buildings or ships the neutron flux measures higher this is known as cosmic ray induced neutron signature or ship effect as it was first detected with ships at sea 7 Artificial background radiation Edit Displays showing ambient radiation fields of 0 120 0 130 mSv h 1 05 1 14 mSv a in a nuclear power plant This reading includes natural background from cosmic and terrestrial sources Atmospheric nuclear testing Edit Per capita thyroid doses in the continental United States resulting from all exposure routes from all atmospheric nuclear tests conducted at the Nevada Test Site from 1951 to 1962 Atmospheric 14C New Zealand 32 and Austria 33 The New Zealand curve is representative for the Southern Hemisphere the Austrian curve is representative for the Northern Hemisphere Atmospheric nuclear weapon tests almost doubled the concentration of 14C in the Northern Hemisphere 34 Frequent above ground nuclear explosions between the 1940s and 1960s scattered a substantial amount of radioactive contamination Some of this contamination is local rendering the immediate surroundings highly radioactive while some of it is carried longer distances as nuclear fallout some of this material is dispersed worldwide The increase in background radiation due to these tests peaked in 1963 at about 0 15 mSv per year worldwide or about 7 of average background dose from all sources The Limited Test Ban Treaty of 1963 prohibited above ground tests thus by the year 2000 the worldwide dose from these tests has decreased to only 0 005 mSv per year 35 Occupational exposure Edit The International Commission on Radiological Protection recommends limiting occupational radiation exposure to 50 mSv 5 rem per year and 100 mSv 10 rem in 5 years 36 However background radiation for occupational doses includes radiation that is not measured by radiation dose instruments in potential occupational exposure conditions This includes both offsite natural background radiation and any medical radiation doses This value is not typically measured or known from surveys such that variations in the total dose to individual workers is not known This can be a significant confounding factor in assessing radiation exposure effects in a population of workers who may have significantly different natural background and medical radiation doses This is most significant when the occupational doses are very low At an IAEA conference in 2002 it was recommended that occupational doses below 1 2 mSv per year do not warrant regulatory scrutiny 37 Nuclear accidents Edit Radiation level in a range of situations from normal activities up to the nuclear accidents Each step up the scale indicates a tenfold increase in radiation level Under normal circumstances nuclear reactors release small amounts of radioactive gases which cause small radiation exposures to the public Events classified on the International Nuclear Event Scale as incidents typically do not release any additional radioactive substances into the environment Large releases of radioactivity from nuclear reactors are extremely rare To the present day there were two major civilian accidents the Chernobyl accident and the Fukushima I nuclear accidents which caused substantial contamination The Chernobyl accident was the only one to cause immediate deaths Total doses from the Chernobyl accident ranged from 10 to 50 mSv over 20 years for the inhabitants of the affected areas with most of the dose received in the first years after the disaster and over 100 mSv for liquidators There were 28 deaths from acute radiation syndrome 38 Total doses from the Fukushima I accidents were between 1 and 15 mSv for the inhabitants of the affected areas Thyroid doses for children were below 50 mSv 167 cleanup workers received doses above 100 mSv with 6 of them receiving more than 250 mSv the Japanese exposure limit for emergency response workers 39 The average dose from the Three Mile Island accident was 0 01 mSv 40 Non civilian In addition to the civilian accidents described above several accidents at early nuclear weapons facilities such as the Windscale fire the contamination of the Techa River by the nuclear waste from the Mayak compound and the Kyshtym disaster at the same compound released substantial radioactivity into the environment The Windscale fire resulted in thyroid doses of 5 20 mSv for adults and 10 60 mSv for children 41 The doses from the accidents at Mayak are unknown Nuclear fuel cycle Edit The Nuclear Regulatory Commission the United States Environmental Protection Agency and other U S and international agencies require that licensees limit radiation exposure to individual members of the public to 1 mSv 100 mrem per year Energy sources Edit Per UNECE life cycle assessment nearly all sources of energy result in some level of occupational and public exposure to radionuclides as result of their manufacturing or operations The following table uses man Sievert GW annum 42 Source Public OccupationalNuclear power 0 43 4 5Coal modern 0 7 11Coal older 1 4 11Natural gas 0 1 0 02Oil 0 0003 0 15Geothermal 1 20 0 05Solar power 0 8Wind power 0 1Biomass 0 01Coal burning Edit Coal plants emit radiation in the form of radioactive fly ash which is inhaled and ingested by neighbours and incorporated into crops A 1978 paper from Oak Ridge National Laboratory estimated that coal fired power plants of that time may contribute a whole body committed dose of 19 µSv a to their immediate neighbours in a radius of 500 m 43 The United Nations Scientific Committee on the Effects of Atomic Radiation s 1988 report estimated the committed dose 1 km away to be 20 µSv a for older plants or 1 µSv a for newer plants with improved fly ash capture but was unable to confirm these numbers by test 44 When coal is burned uranium thorium and all the uranium daughters accumulated by disintegration radium radon polonium are released 45 Radioactive materials previously buried underground in coal deposits are released as fly ash or if fly ash is captured may be incorporated into concrete manufactured with fly ash Other sources of dose uptake EditMedical Edit The global average human exposure to artificial radiation is 0 6 mSv a primarily from medical imaging This medical component can range much higher with an average of 3 mSv per year across the USA population 3 Other human contributors include smoking air travel radioactive building materials historical nuclear weapons testing nuclear power accidents and nuclear industry operation A typical chest x ray delivers 20 µSv 2 mrem of effective dose 46 A dental x ray delivers a dose of 5 to 10 µSv 47 A CT scan delivers an effective dose to the whole body ranging from 1 to 20 mSv 100 to 2000 mrem The average American receives about 3 mSv of diagnostic medical dose per year countries with the lowest levels of health care receive almost none Radiation treatment for various diseases also accounts for some dose both in individuals and in those around them Consumer items Edit Cigarettes contain polonium 210 originating from the decay products of radon which stick to tobacco leaves Heavy smoking results in a radiation dose of 160 mSv year to localized spots at the bifurcations of segmental bronchi in the lungs from the decay of polonium 210 This dose is not readily comparable to the radiation protection limits since the latter deal with whole body doses while the dose from smoking is delivered to a very small portion of the body 48 Radiation metrology EditIn a radiation metrology laboratory background radiation refers to the measured value from any incidental sources that affect an instrument when a specific radiation source sample is being measured This background contribution which is established as a stable value by multiple measurements usually before and after sample measurement is subtracted from the rate measured when the sample is being measured This is in accordance with the International Atomic Energy Agency definition of background as being Dose or dose rate or an observed measure related to the dose or dose rate attributable to all sources other than the one s specified 1 The same issue occurs with radiation protection instruments where a reading from an instrument may be affected by the background radiation An example of this is a scintillation detector used for surface contamination monitoring In an elevated gamma background the scintillator material will be affected by the background gamma which will add to the reading obtained from any contamination which is being monitored In extreme cases it will make the instrument unusable as the background swamps the lower level of radiation from the contamination In such instruments the background can be continually monitored in the Ready state and subtracted from any reading obtained when being used in Measuring mode Regular Radiation measurement is carried out at multiple levels Government agencies compile radiation readings as part of environmental monitoring mandates often making the readings available to the public and sometimes in near real time Collaborative groups and private individuals may also make real time readings available to the public Instruments used for radiation measurement include the Geiger Muller tube and the Scintillation detector The former is usually more compact and affordable and reacts to several radiation types while the latter is more complex and can detect specific radiation energies and types Readings indicate radiation levels from all sources including background and real time readings are in general unvalidated but correlation between independent detectors increases confidence in measured levels List of near real time government radiation measurement sites employing multiple instrument types Europe and Canada European Radiological Data Exchange Platform EURDEP Simple map of Gamma Dose Rates USA EPA Radnet near real time and laboratory data by stateList of international near real time collaborative private measurement sites employing primarily Geiger Muller detectors GMC map http www gmcmap com mix of old data detector stations and some near real time ones Netc http www netc com Radmon http www radmon org Radiation Network http radiationnetwork com Radioactive Home http radioactiveathome org map Safecast http safecast org tilemap the green circles are real time detectors uRad Monitor http www uradmonitor com See also EditBackground radiation equivalent time BRET Banana equivalent dose Environmental radioactivity Flight time equivalent dose Noise electronics Low background steelReferences Edit a b International Atomic Energy Agency 2007 IAEA Safety Glossary Terminology Used in Nuclear Safety and Radiation Protection ISBN 9789201007070 a b c d e United Nations Scientific Committee on the Effects of Atomic Radiation 2008 Sources and effects of ionizing radiation New York United Nations published 2010 p 4 ISBN 978 92 1 142274 0 Retrieved 9 November 2012 a b c Ionizing radiation exposure of the population of the United States Bethesda Md National Council on Radiation Protection and Measurements 2009 ISBN 978 0 929600 98 7 NCRP No 160 Archived from the original on 2 February 2014 Retrieved 9 November 2012 Ministry of Education Culture Sports Science and Technology of Japan Radiation in environment Archived 22 March 2011 at the Wayback Machine retrieved 2011 6 29 Naturally Occurring Radioactive Materials NORM World Nuclear Association March 2019 Archived from the original on 20 January 2016 Retrieved 26 August 2014 Exposure to radiation from natural sources Nuclear Safety amp Security IAEA Archived from the original on 9 February 2016 Retrieved 4 January 2016 a b c d e Gary W Philips David J Nagel Timothy Coffey A Primer on the Detection of Nuclear and Radiological Weapons Center for Technology and National Security Policy National Defense University May 2005 a b United Nations Scientific Committee on the Effects of Atomic Radiation 2006 Annex E Sources to effects assessment for radon in homes and workplaces PDF Effects of Ionizing Radiation Vol II New York United Nations published 2008 ISBN 978 92 1 142263 4 Archived PDF from the original on 9 October 2022 Retrieved 2 December 2012 Radon and Cancer Questions and Answers National Cancer Institute USA 6 December 2011 Fornalski K W Adams R Allison W Corrice L E Cuttler J M Davey Ch Dobrzynski L Esposito V J Feinendegen L E Gomez L S Lewis P Mahn J Miller M L Pennington Ch W Sacks B Sutou S Welsh J S 2015 The assumption of radon induced cancer risk Cancer Causes amp Control 10 26 1517 18 doi 10 1007 s10552 015 0638 9 PMID 26223888 S2CID 15952263 Thomas John J Thomas Barbara R Overeynder Helen M 27 30 September 1995 Indoor Radon Concentration Data Its Geographic and 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