Sources of Radiation Exposure Sources of Radiation Exposure to the US Population (from U.S. NRC, Glossary: Exposure. [updated 21 July 2003, cited 26 March 2004] http://www.nrc.gov/reading-rm/basic-ref/glossary/exposure.html In the US, the annual estimated average effective dose to an adult is 3.60 mSv. Sources of exposure for the general public ? Natural radiation of terrestrial origin ? Natural radiation of cosmic origin ? Natural internal radioisotopes ? Medical radiation ? Technologically enhanced natural radiation ? Consumer products ? Fallout ? Nuclear power Other 1% Occupational 3% Fallout <0.3% Nuclear Fuel Cycle 0.1% Miscellaneous 0.1% Radioactivity in Nature Our world is radioactive and has been since it was created. Over 60 radionuclides can be found in nature, and they can be placed in three general categories: Primordial - been around since the creation of the Earth Singly-occurring Chain or series Cosmogenic - formed as a result of cosmic ray interactions Primordial radionuclides When the earth was first formed a relatively large number of isotopes would have been radioactive. Those with half-lives of less than about 10 8 years would by now have decayed into stable nuclides. The progeny or decay products of the long-lived radionuclides are also in this heading. Primordial nuclide examples Nuclide Half-life (years) Natural Activity Uranium 235 7.04 x 10 8 0.72 % of all natural uranium Uranium 238 4.47 x 10 9 99.27 % of all natural uranium; 0.5 to 4.7 ppm total uranium in the common rock types Thorium 232 1.41 x 10 10 1.6 to 20 ppm in the common rock types with a crustal average of 10.7 ppm Radium 226 1.60 x 10 3 0.42 pCi/g (16 Bq/kg) in limestone and 1.3 pCi/g (48 Bq/kg) in igneous rock Radon 222 3.82 days Noble Gas; annual average air concentrations range in the US from 0.016 pCi/L (0.6 Bq/m 3 ) to 0.75 pCi/L (28 Bq/m 3 ) Potassium 40 1.28 x 10 9 Widespread, e.g., soil ~ 1-30 pCi/g (0.037-1.1 Bq/g) Natural Radioactivity in soil How much natural radioactivity is found in an area 1 square mile, by 1 foot deep (total volume ~ 7.9 x 10 5 m 3 )? Activity levels vary greatly depending on soil type, mineral make-up and density (~1.58 g/cm 3 ). This table represents calculations using typical numbers. Natural Radioactivity by the Mile Nuclide Activity used in calculation Mass of Nuclide Activity Uranium 0.7 pCi/gm (25 Bq/kg) 2,200 kg 0.8 curies (31 GBq) Thorium 1.1 pCi/g (40 Bq/kg) 12,000 kg 1.4 curies (52 GBq) Potassium 40 11 pCi/g (400 Bq/kg) 2000 kg 13 curies (500 GBq) Radium 1.3 pCi/g (48 Bq/kg) 1.7 g 1.7 curies (63 GBq) Radon 0.17 pCi/gm (10 kBq/m 3 ) soil 11 μg 0.2 curies (7.4 GBq) Image removed. “Single” primordial nuclides At least 22 naturally occurring single or nor-series primordial radionuclides have been identified. Most of these have such long half-lives, small isotopic and elemental abundances and small biological uptake and concentration that they give little environmental dose. The most important is potassium-40. Potassium is a metal with 3 natural isotopes, 39, 40 and 41. Only 40 K is radioactive and it has a half life of 1.26 x 10 9 years. Chain or series-decaying primordial radionuclides Radioactive series refers to any of four independent sets of unstable heavy atomic nuclei that decay through a sequence of alpha and beta decays until a stable nucleus is achieved. Three of the sets, the thorium series, uranium series, and actinium series, called natural or classical series, are headed by naturally occurring species of heavy unstable nuclei that have half-lives comparable to the age of the elements. Important points about series-decaying radionuclides ? 3 main series ? the fourth (neptunium) exists only with man-made isotopes, but probably existed early in the life of the earth ? the 3 main series decay schemes all produce radon (but primary radon source, the longest half-life, is the uranium series). Series name Begins T 1/2 Ends Gas (T 1/2 ) Thorium 232 Th 1.4 x 10 10 yr 208 Pb 220 Rn (55.6 sec) thoron Uranium 238 U 4.5 x 10 9 yr 206 Pb 222 Rn (3.8 days) radon Actinium 235 U 7.1 x 10 8 yr 207 Pb 219 Rn (4.0 sec) actinon Uranium 238 decay scheme. ? Branching occurs when the radionuclide is unstable to both alpha and beta decay, for example, 218 Po. ? Gamma emission occurs in most steps. Image removed. Fig. 15.4 in Alpen, E. L. Radiation Biophysics, 2 nd ed. San Diego, CA: Academic Press, 1998. Major characteristics of the radionuclides that comprise the natural decay series for 232 Th, 235 U, and 238 U Natural 232 Th decay series Natural 235 U decay series Natural 238 U decay series Nuclide Half-life b Principle mode of decay c Nuclide Half-life b Principle mode of decay c Nuclide Half-life b Principle mode of decay c 232 Th 1.4E+10 y α 235 U 7.0E+08 y α 238 U 4.5E+09 y α 228 Ra 5.75 y β 231 Th 1.06 d β 234 Th 24.10 d β 228 Ac 6.13 h β 231 Pa 3.3E+04 y α 234 Pa 1.17 min β 228 Th 1.913 y α 227 Ac 2.2E+01 y α (1.4 %) 234 U 2.5E+05 y α β (98.6 %) 224 Ra 3.66 d α 227 Th 18.7 d α 230 Th 7.5E+04 y α 220 Rn 55.6 s α 223 Fr 21.8 min β 226 Ra 1.6E+03 y α 216 Po 1.5E–02 s α 223 Ra 11.43 d α 222 Rn 3.85 d α 212 Pb 10.64 h β 219 At 56 s α 218 Po 3.1 min α 212 Bi 1.01 h α (36%) 219 Rn 3.96 s α 218 At 1.5 s α β (64%) 212 Po 3.0E–07 s α 215 Bi 7.6 min β 214 Pb 27 min β 208 Tl 3.053 min β 215 Po 1.8E–03 s α 214 Bi 19.9 min β 208 Pb (stable) (stable) 215 At 1.0E–07 s α 214 Po 1.6E–04 s α 211 Pb 36.1 min β 210 Tl 1.30 min β 211 Po 25.2 s α 210 Pb 22.6 y β 211 Bi 2.14 min α 210 Bi 5.01 d β 207 Tl 4.77 min β 210 Po 138.4 d α 207 Pb (stable) (stable) 206 Hg 8.2 min β 206 Tl 4.20 min β 206 Pb (stable) (stable) b y–years; d–days; h–hours; min–minutes; and s–seconds. c α–alpha decay; β–negative beta decay; EC–electron capture; and IT–isomeric transition (radioactive transition from one nuclear isomer to another of lower energy). Cosmogenic Radiation Cosmogenic Nuclides Nuclide Half-life Source Natural Activity C-14 5730 yr Cosmic-ray interactions, 14 N(n,p) 14 C ~15 Bq/g Tritium 12.3 yr Cosmic-ray interactions with N and O; spallation from cosmic-rays, 6 Li(n,alpha) 3 H 1.2 x 10 -3 Bq/kg Be-7 53.28 days Cosmic-ray interactions with N and O 0.01 Bq/kg Some other cosmogenic radionuclides are 10 Be, 26 Al, 36 Cl, 80 Kr, 14 C, 32 Si, 39 Ar, 22 Na, 35 S, 37 Ar, 33 P, 32 P, 38 Mg, 24 Na, 38 S, 31 Si, 18 F, 39 Cl, 38 Cl, 34m Cl. Source: NASA. “Cosmic Rays.” [updated 25 Nov 2001, cited 29 March 2004] http://www-istp.gsfc.nasa.gov/Education/wcosray.html Track structure of a cosmic ray collision in a nuclear emulsion Variations in cosmic ray intensity at the earth’s surface are due to: ? Time: sunspot cycles ? Latitude: magnetic field lines ? Altitude: attenuation in the upper atmosphere Dose at the surface from cosmic rays Image removed. Fig. 16.3 in [Alpen]. Image removed. Breakdown of radiation exposures from external sources Image removed. Fig. 16.1 in [Alpen]. In most places on earth, natural radioactivity varies only within relatively narrow limits. In some places there are wide deviations from these limits due to the presence of abnormally high concentrations of radioactive minerals in local soils. Internal Radiation What makes a radionuclide biologically important? ? Abundance (both elemental and isotopic) ? Half-life ? Decay scheme (emission type and energy) ? Chemical state ? Chemical behavior in the body ? Does it concentrate? ? Ultimate location ? Rate of excretion How do the series radionuclides contribute to our dose? Inhalation Isotopes of radon (inert gas, but may decay in the lung) Dust; e.g., our main source of uranium is due to resuspension of dust particles from the earth. Uranium is ubiquitous, a natural constituent of all rocks and soil. Externally- gamma emission occurs in most decay steps. Internally-Consumption in food and drinking water Natural Radioactivity in the body Nuclide Total Mass of Nuclide Total Activity of Nuclide Daily Intake of Nuclides Uranium 90 μg 30 pCi (1.1 Bq) 1.9 μg Thorium 30 μg 3 pCi (0.11 Bq) 3 μg Potassium 40 17 mg 120 nCi (4.4 kBq) 0.39 mg Radium 31 pg 30 pCi (1.1 Bq) 2.3 pg Carbon 14 95 μg 0.4 μCi (15 kBq) 1.8 μg Tritium 0.06 pg 0.6 nCi (23 Bq) 0.003 pg Polonium 0.2 pg 1 nCi (37 Bq) ~0.6 μg It would be reasonable to assume that all of the radionuclides found in your environment would exist in the body in some small amount. The internally deposited radionuclides contribute about 11% of the total annual dose. Uranium ? Present in all rocks and soil, and thus in both our food and in dust. ? High concentrations in phosphate rocks (and thus in commercial fertilizers). ? Absorbed by the skeleton which receives roughly 3 μSv/year from uranium. Radium ? Also present in all rocks and soils. ? Food is a more important source of intake ? 226 Ra and its daughter products (beginning with 222 Rn) contribute the major dose components from naturally occurring internal emitters. ? Dissolves readily, chemically similar to calcium. ? Absorbed from the soil by plants and passed up the food chain to humans ? variations in Ra levels in soil lead to variations in Ra levels in food ? 80% of the total body Ra is in bone (~7mrem/year). ? The rest is uniformly distributed in soft tissue. Thorium ? Lots in dust but little is incorporated in food ? Thorium is present in the highest concentrations in pulmonary lymph nodes and lung, indicating that the principle source of exposure is due to inhalation of suspended soil particles. ? Ultimately a bone seeker with a long residence time ? Since it is very slowly removed from bone, concentration increases with age. Lead ? Also a bone seeker, half-life in bone is ~ 10 4 days. Polonium ? Unlike other naturally occurring α-emitters, 210 Po deposits in soft tissue not bone. ? Two groups exist for which the dose from 210 Po is apt to be exceptionally high. ? Cigarette smokers ? Residents of the north who subsist on caribou and reindeer. ? Reindeer eat lichens that absorb trace elements in the atmosphere ( 210 Po and 210 Pb). The 210 Po content of Lapps living in northern Finland is ~12 times higher than the residents of southern Finland. ? Liver dose in the Laplanders is 170 mrem/year compared to 15 mrem/year for those in the south. Image removed. Fig. 16.4 in [Alpen]. See [Alpen], Table 16.6 Doses from Medical Applications Image removed. Civilian Nuclear Power Fuel Cycle ? Mining ? Extraction, milling, refining ? Enrichment ? Power generation ? Fuel reprocessing ? Fuel storage ? Transwportation ? High level waste storage Estimation of population dose ? Committed equivalent dose ? Collective effective dose commitment ? Maximally exposed individual See [Alpen], Table 16.7 Consumer products Doses usually negligible Significant public awareness? Tobacco 210Pb and 210Po Coal//natural gas Th and U in ceramics and glass Airport x rays Smoke detectors Gaslamp mantles Commercial Air Travel Calculated cosmic ray doses to a person flying in subsonic and supersonic aircraft under normal solar conditions Subsonic flight at 36,000 ft (11 km) Supersonic flight at 62,000 (19 km) Dose per round trip Dose per round trip Route Flight duration (hrs) (mrad) (μGy) Flight duration (hrs) (mrad) (μGy) Los Angeles- Paris 11.1 4.8 48 3.8 3.7 37 Chicago-Paris 8.3 3.6 36 2.8 2.6 26 New York-Paris 7.4 3.1 31 2.6 2.4 24 New York- London 7.0 2.9 29 2.4 2.2 22 Los Angeles-New York 5.2 1.9 19 1.9 1.3 13 Sydney-Acapulco 17.4 4.4 44 6.2 2.1 21 Issues: ? Should airline people be considered general public? or radiation workers? ? What about corporate aviation? (altitudes almost as high as supersonic Concorde but travel is sub-sonic and thus time in air is high) ? Business travelers: frequent fliers have no restriction of # hours per year in flight. ? What about pregnant women? ? Should the traveling public be alerted to sunspot activity? ? Is legal action possible? Image removed.