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www.ceh.ac.uk/PROTECT Jordi Vives i Batlle Centre for Ecology and Hydrology, Lancaster, 1 st – 3 rd April 2014 Radiation dosimetry for animals and plants
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www.radioecology-exchange.org Key concepts Radioactivity, kerma, absorbed dose, units, radiation weighting factor, absorbed fraction, dose conversion coefficient (DCC) ERICA approach to absorbed fraction calculation Reference habitats, organisms and shapes, Monte Carlo approach, sphericity, dependence with energy / size ERICA DCCs for internal and external exposure Internal and external DCC formulae, energy / size dependency, allometric scaling Comparing ERICA with other tools Special cases Gases, inhomogeneous sources, non-equilibrium Lecture plan
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www.radioecology-exchange.org Introduction
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www.radioecology-exchange.org Role of dosimetry in assessment
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www.radioecology-exchange.org ERICA exposure scenarios Plant geometry: is it a root or is it a stem? Height above ground for grass & herbs - cm to m
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www.radioecology-exchange.org Key concepts
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www.radioecology-exchange.org Atoms and atomic structure Atoms are the smallest quantities of an element that preserve all of its chemical properties. Essential components of all atoms: Proton (m = 1 unit, charge = +1 unit) Neutron (m = 1 unit, charge = 0) Electron (m = 5.48 × 10 -4 units, charge = -1 units) Mass unit: 1.67 x 10 -27 kg - Charge: =1.6 × 10 -19 C Electrons surround the nucleus, equal in number to the protons (atomic number Z). Atoms have a small positively charged nucleus comprised of protons (Z) plus neutrons (N)
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www.radioecology-exchange.org Radioactive decay Spontaneous process by which an atomic nucleus of an unstable atom loses energy by emitting ionizing particles (ionizing radiation). Activity is the rate at which its atoms are undergoing transformation (rate at which individual emissions of radiation occur). Expressed in units of Becquerels (Bq) where one Becquerel equates to one atom transformation per second.
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www.radioecology-exchange.org Henri A. Becquerel (1896) - radiation from U salts expose film. Marie Curie (ca 1898) - radiation from thorium, polonium, radium – 2 Nobel prizes! Ernest Rutherford (ca 1903) - alpha radiation as helium nuclei. The great discoverers
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www.radioecology-exchange.org Time Activity Radioactive decay occurs as a statistical exponential rate process. The number of atoms likely to decay (dN/dt) is proportional to the number (N) of atoms present. The proportionality constant, l, is the decay constant. Half-life = 0.693/ Law of radioactive decay
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www.radioecology-exchange.org α rays - most massive, positive charge (helium nuclei) rays - negative charge, same as electron, arise from weak interaction rays - no electric charge, quanta of electromagnetic radiation Radioactive isotopes found in nature emit three types of radiation: All three types can excite and ionise atoms. Marie Curie’s apparatus shows deflection of rays from Ra Different types of radiation
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www.radioecology-exchange.org Biological effects result directly from energy loss as radiation passes through tissue. Formation of ions and free radicals (radiolysis). Damage effect at sub-cellular level. Reaction with chromosomes and damage to DNA strands. Biological effects of radiation
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www.radioecology-exchange.org Kerma: sum of the initial kinetic energies of all the charged particles transferred to a target by non-charged ionising radiation, per unit mass Absorbed dose: total energy deposited in a target by ionising radiation, including secondary electrons, per unit mass Similar at low energy - Kerma an approximate upper limit to dose Different when calculating dose to a volume smaller than the range of secondary electrons generated Kerma and absorbed dose
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www.radioecology-exchange.org Units of absorbed dose (Grays) = Energy deposited (J kg -1 ) Only small amounts of deposited energy from ionising radiation are required to produce biological harm - because of how energy is deposited (ionisation and free radical formation) For example - drinking a cup of hot coffee transfers about 700 Joules of heat energy per kg to the body. To transfer the same amount of energy from ionising radiation would involve a dose of 700 Gy - but doses in the order of 1 Gy are fatal I Gy = 1 J kg -1 = 6.24 10 15 keV ~ 10 12 alphas Units and their significan ce
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www.radioecology-exchange.org Need to make allowance of such factors as LET or RBE in the description of absorbed dose Equivalent dose = absorbed dose radiation weighting factor (w r ) Units of equivalent dose are Sieverts (Sv) No firm consensus - suggested values for w r : 1 for and high energy (> 10keV) radiation 3 for low energy ( 10keV) radiation 10 for (non stochastic effects in the species) vs. 20 for humans (to cover stochastic effects of radiation i.e. cancer in an individual) Radiation weighting factor
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www.radioecology-exchange.org Fraction of energy E emitted by a source absorbed within the target tissue / organism Internal and external exposures of an organism in a homogeneous medium: D int = k A org (Bq kg -1 ) E (MeV) AF(E) D ext = k A medium (Bq kg -1 ) E [1-AF(E)] k = 5.76 10 -4 Gy h -1 per MeV Bq kg -1 If the radiation is not mono-energetic, then the above need to be summed over all the decay energies (spectrum) of the radionuclide Some models make conservative assumptions: Infinitely large organism (internal exposure) Infinitely small organism (external exposure) Absorbed fraction (AF)
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www.radioecology-exchange.org Defined as the ratio of dose rate per unit concentration in organism or the medium: D int = k A org E AF(E) = DCC int A org D ext = k A medium E[1-AF(E)] = DCC ext A medium Where A = activity concentration, E = energy and AF(E) = absorbed fraction Constant k adjusted to give dose units of Gy h -1 Concentration in organisms as a function of time, c(t), is concentration in the medium times a transfer function: A org =A medium c(t) In equilibrium, the transfer function is known as the ‘concentration ratio”, CR Dose conversion coefficient
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www.radioecology-exchange.org The dose is the result of a complex interaction of energy, mass and the source - target geometry: Define organism mass and shape Consider exposure conditions (internal, external) Simulate radiation transport for mono-energetic photons and electrons: absorbed fractions Link calculations with nuclide-specific decay characteristics: Dose conversion coefficients Only a few organisms with simple geometry can be simulated explicitly In all other cases interpolation gives good accuracy Strategy for dose calculation
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www.radioecology-exchange.org Calculation of AFs: the ERICA approach
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www.radioecology-exchange.org The enormous variability of biota requires the definition of reference organisms that represent: Plants and animals Different mass ranges Different habitats Exposure conditions are defined for different habitats: In soil/on soil In water/on water In sediment/interface water sediment Reference habitats & organisms
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www.radioecology-exchange.org Organism shapes approximated by ellipsoids, spheres or cylinders of stated dimensions Homogeneous distribution of radionuclides within the organism: organs are not considered Oganism immersed in uniformly contaminated medium Dose rate averaged over organism volume Reference organism shapes
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www.radioecology-exchange.org Image from N. Semioschkina, Germany So The world looks like this…
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www.radioecology-exchange.org Monte Carlo simulations of photon and electron transport through matter (ERICA uses MCNP code) Includes all processes: photoelectric absorption, Compton scattering, pair creation, fluorescence Monte Carlo approach
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www.radioecology-exchange.org Monte Carlo calculations are very time-consuming : Long range of high-energy photons in air, a large area around the organism has to be considered A large contaminated area has to be considered as source Small targets get only relatively few hits Probability ~ 1/source-target distance 2 Simulations require high number of photon tracks Therefore, a two-step method has been developed : KERMA calculated in air from different sources on or in soil Dose to organism / dose in air ratio calculated for the different organisms and energies Problems and limitations
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www.radioecology-exchange.org ElectronsPhotons Spherical AFs v. mass & energy For alpha and beta <10 keV the absorbed fraction is ~1
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www.radioecology-exchange.org Absorbed fractions for electrons in different terrestrial organisms (Brown et al., 2003) AF versus gamma energy
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www.radioecology-exchange.org Represented by ellipsoidal shapes having the same mass as the spherical ones. AFs always less than those for spheres of equal mass. Non-sphericity parameter: = surface area of sphere of equal mass (S0) / surface area (S). The absorbed fraction for the non-spherical body is the absorbed fraction of the “equivalent sphere” multiplied by a re-scaling factor. Non-spherical bodies
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www.radioecology-exchange.org Calculation of DCCs: ERICA database
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www.radioecology-exchange.org For a radionuclide with various , or decay transitions we make the following groupings having the same radiation weighting factor: Low energy (energy 10 keV) + ; and Then for each category we sum all transitions (represented by sub-index i) of probability p i : The total DCC is: Internal DCC formulas
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www.radioecology-exchange.org It’s nearly the same except we replace AF by 1 - AF: The total DCC is: External DCC formulas
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www.radioecology-exchange.org Occupancy factor : External exposure : Internal exposure : Calculation of dose rates
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www.radioecology-exchange.org External DCCs decrease with size due to the increasing self-shielding, especially for low energy g-emitters Small organism DCCs from high-energy photons higher for underground organisms and vice versa for larger organisms External exposure to low-energy emitters is higher for organisms above ground, due to lack of shielding by soil DCCs for internal exposure to -emitters (esp. high- energy) increase with mass due to the higher absorbed fractions For and -emitters, the DCCs for internal exposure are virtually size-independent DCCs versus size and energy
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www.radioecology-exchange.org Data from Vives i Batlle et al. (2004) Data shows smooth dependency of DCC with area/volume DCC correlation with size
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www.radioecology-exchange.org DCCs for earthworm at various soil depths for monoenergetic photons. Assumes uniformly contaminated upper 50 cm of soil DCCs for various soil organisms at a depth of 25 cm in soil for monoenergetic photons. Assumes uniformly contaminated upper 50 cm of soil (density: 1600 kg/m³) External DCCs for soil organisms
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www.radioecology-exchange.org DCCs for mono-energetic photons for soil organisms as a function of photon energy (Brown et al., 2003) Energy dependence of DCCs
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www.radioecology-exchange.org Comparing ERICA with other tools
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www.radioecology-exchange.org International comparison of 7 models performed under the EMRAS project: EDEN, EA R&D 128, ERICA, DosDimEco, EPIC-DOSES3D, RESRAD- BIOTA, SÚJB 5 ERICA runs by different users: default DCCs, ICRP, SCK-CEN, ANSTO, K-Biota 67 radionuclides and 5 ICRP RAP geometries Internal doses: mostly within 25% around mean External doses: mostly within 10% around mean There are exceptions e.g.α and soft β-emitters reflecting variability in AF estimations ( 3 H, 14 C…) ERICA making predictions similar to other models Intercomparison analysis
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www.radioecology-exchange.org Estimate ratio of average (ERICA) to average (rest of models) Skewed distribution centered at 1.1 Fraction < 0.75 = 40% Fraction > 1.25 = 3% Fraction between 0.75 and 1.25 = 57% Worst offenders (< 0.25): 51 Cr, 55 Fe, 59 Ni, 210 Pb, 228 Ra, 231 Th and 241 Pu Worst offenders (>1.25): 14 C, 228 Th Conclude reasonably tight fit (most data < 25% off) Internal dosimetry comparison
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www.radioecology-exchange.org Same ratio method for external dose in water Two data groups at < 0.02 and ~ 1.32 Fraction < 0.5 = 37% Fraction > 1.5 = 13% Fraction between 0.5 and 1.5 =50 % Worst offenders (< 0.02): 3 H, 33 P, 35 S, 36 Cl, 45 Ca, 55 Fe, 59,63 Ni, 79 Se, 135 Cs, 210 Po, 230 Th, 234,238 U, 238,239,241 Pu, 242 Cm Worst offenders (>1.25): 32 P, 54 Mn, 58 Co, 94,95 Nb, 99 Tc, 124 Sb, 134,136 Cs, 140 Ba, 140 La, 152,154 Eu, 226 Ra, 228 Th Still acceptable fit (main data < 50% “off”) External dosimetry comparison
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www.radioecology-exchange.org Special cases outside the ERICA approach
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www.radioecology-exchange.org The following formulae can be used for radionuclides whose concentration is referenced to air: 3 H, 14 C, 32 P, 35 S, 41 Ar and 85 Kr Approach for gases
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www.radioecology-exchange.org Inhomogeneous distributions Only a few nuclides homogeneously distributed: 3 H, 14 C, 40 K, 137 Cs Many concentrate in specific organs e.g. Green gland ( 99 Tc), Thyroid ( 129,131 I), Bone ( 90 Sr, 226 Ra), Liver ( 239 Pu), Kidney ( 238 U) Data from Gómez-Ros et al. (2009) Shows moderate influence in organ position within ellipsoid for various animals
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www.radioecology-exchange.org Internal dose negligible: Ar and Kr CFs set to 0 No deposition but some migration into soil pores Assume pore air is at the same concentration as ground level air concentrations assume a free air space of 15%, density = 1500 kg m -3, so free air space = 10 -4 m 3 kg -1 & Bq m -3 (air) * 10 -4 = Bq kg -1 (wet) Hence, a TF of 10 -4 for air (Bq m -3 ) to soil (Bq kg -1 wet) For plants and fungi occupancy factors set to 1.0 soil, 0.5 air (instead of 0) Biota in the subsurface soil and are exposed only to 41 Ar and 85 Kr in the air pore spaces External DCCs for fungi are those calculated for bacteria (i.e. infinite medium DCCs) Argon and krypton
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www.radioecology-exchange.org - i N L RR+h Conceptual representation of irradiated respiratory tissue Simple respiratory model for 222 Rn daughters At equilibrium: Radon - a complex problem
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www.radioecology-exchange.org Each sub-model contains the decay chain of radon: 222 Rn 218 Po 214 Pb 214 Bi 214 Po Incorporates internal, surface and external dose ICRP radon model for plants
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www.radioecology-exchange.org ERICA makes many assumptions and simplifications Geometry greatly simplified by using ellipsoids Homogeneous distribution in uniformly contaminated medium - organs not considered (some tests done) Only a few organisms with simple geometry can be defined Size interpolation works only within predefined mass ranges: 0.0017 to 550 kg for animals above ground 0.0017 to 6.6 kg for animals in soil 0.035 to 2 kg for birds 1E-06 to 1000 kg for aquatic organisms Otherwise use Table 10 in ERICA help file to estimate the uncertainty Summary – ERICA key features
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www.radioecology-exchange.org There are some things ERICA cannot do Limitations on which reference organisms appear under which ecosystems e.g. cannot calculate DCC for marine bird in air Do conservative run for bird on water or sediment Plant geometries in ERICA are unrealistic - root versus stem. Variable height above ground for grasses. They do not really represent whole-organisms The grass geometry is taken from the ICRP Wild Grass RAP - no ‘in soil’ dose rates are estimated, but only dose above ground. If you are concerned create an organism to represent your plant (e.g. leaf) and compare DCC values to the default grass. Gaseous radionuclides are beyond the scope of the tool and require specialised models Summary – what ERICA can’t do
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www.radioecology-exchange.org References Brown J., Gomez-Ros J.-M., Jones, S.R., Pröhl, G., Taranenko, V., Thørring, H., Vives i Batlle, J. and Woodhead, D, (2003) Dosimetric models and data for assessing radiation exposures to biota. FASSET Deliverable 3 Report under Contract No FIGE- CT-2000-00102, G. Pröhl (Ed.). Gómez-Ros, J.M., Pröhl, G., Ulanovsky, A. and Lis, M. (2008). Uncertainties of internal dose assessment for animals and plants due to non-homogeneously distributed radionuclides. Journal of Environmental Radioactivity 99(9): 1449-1455. Ulanovsky, A. and Pröhl, G. (2006) A practical method for assessment of dose conversion coefficients for aquatic biota. Radiation and Environmental Biophysics 45: 203 -214. Vives i Batlle, J., Jones, S.R. and Gómez-Ros, J.M. (2004) A method for calculation of dose per unit concentration values for aquatic biota. Journal of Radiological Protection 24(4A): A13-A34. Vives i Batlle, J., Jones, S.R. and Copplestone, D. (2008) Dosimetric Model for Biota Exposure to Inhaled Radon Daughters. Environment Agency Science Report – SC060080, 34 pp. Vives i Batlle, J., Barnett, C.L., Beaugelin-Seiller, K., Beresford, N.A., Copplestone, D., Horyna, J., Hosseini, A., Johansen, M., Kamboj, S., Keum, D-K., Newsome, L., Olyslaegers, G., Vandenhove, H., Vives Lynch, S. and Wood, M. (2011) Absorbed dose conversion coefficients for non-human biota: an extended inter-comparison of data. Radiation and Environmental Biophysics 50(2): 231-251.
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