1 / 43

How do We Age the Earth? or ‘Measurement of Environmental Radioactivity’

How do We Age the Earth? or ‘Measurement of Environmental Radioactivity’. Paddy Regan Dept. of Physics, University of Surrey, Guildford, UK & Radioactivity Group, National Physical Laboratory, Teddington p.regan@surrey.ac.uk.

mercury
Download Presentation

How do We Age the Earth? or ‘Measurement of Environmental Radioactivity’

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. How do We Age the Earth? or‘Measurement of Environmental Radioactivity’ Paddy Regan Dept. of Physics, University of Surrey, Guildford, UK & Radioactivity Group, National Physical Laboratory, Teddington p.regan@surrey.ac.uk

  2. Scientific methods for estimating the age of the earth? (Literature surveys and radiometric dating). • Which isotopes and how you do it ? • What is NORM…where does it come from ? • How do measure NORMs ? • Why do you want to measure it ? • An example (Map of Qatar)

  3. Nuclear and Atomic Physics Module, MSc in Radiation and Environmental Protection, University of Surrey Tutorial Question (2012) (equation to work this out given later…..)

  4. …ageing the earth using the available literature…Famous example is Archbishop Ussher, Bishop James Ussher (1581-1656) Annals of the Old Testament, Deduced From the First Origins of the World

  5. Others also tried similar methods to age the Earth, including Isaac Newton and Johannes Kepler.

  6. …new information / discoveries… a Chronology of Chronologies… • Comte de Buffon (1779) - Believes earth is slowly cooling, from the rate compared to a small globe, estimated ~75,000 years. • James Hutton (1795) - ‘The Theory of the Earth (1795)’ Geological evolution of the earth’s crust, rock strata formed in layers? • Lord Kelvin aka William Thompson (1862) - Earth had formed between 20 and 40 million years, estimated from time to cool and heat assuming heat generated by gravitational contraction and scientific estimates of earth’s heat conduction (2nd law of thermodynamics etc.) • Rutherford and Soddy (1903) - Explanation of radioactivity of Uranium (U); earth’s internal heat could come from radioactivity. Half-lives for decays could be billions of years. Rutherford suggests use of helium (alpha particles) in rocks to age them. • Boltwood (1907) - ratios of U to Lead to get age of rocks > 109 years. e.g. L. Badash, ‘The Age of the Earth Debate’ Scientific American, August 1989 p 90ff

  7. What is NORM? • Naturally Occurring Radioactive Materials • Two main sub-groups… • Cosmogenic (from cosmic ray interactions) • 14C (from 14N(n,p)14C), 7Be, 26Al • Primordial (i.e. very old) • Single nuclei (e.g., 40K) • Decay chains (232Th, 235U, 238U/226Ra)

  8. Natural decay ‘chains’. Sequences of a and b decaying radioisotopes from Uranium (Z=92) or Thorium (Z=90) to Lead (Z=82). On earth since formed. Isotope ratios (e.g., 235U/238U) also used to estimate earth age..

  9. Laws of radioactive decay defined: A(t) =Ao exp (-lt) A(t) = number of decays per unit time at time t =‘activity’

  10. What if the ‘daughter’ nucleus is also radioactive? and ..if l2 >> l1 (T1/21 >> T1/22) then A2≈A1

  11. Secular Equilibrium… If there is a ‘long’ decay half-life beginning a radioactive decay chain (e.g., 238U), the activity or (number of atoms which decay per second) of all of the successive daughter decays tends to the activity of the long-lived parent.

  12. i.e. measuring the Activity, A(t), of any member of the 238U decay chain can be used to estimate amount of 238U present in the sample from A=lN: We can measure A(t) & know l, therefore we can estimate N, number of atoms present.

  13. Radiation occurs in nature…the earth is ‘bathed’ in radiation from a variety of sources. • Humans have evolved with these levels of radiation in the environment. Naturally Occurring Radioactive Materials These include Uranium-238, which has radioactive half-life of 4.47 billion years. 238U decays via a series of alpha and beta decays (some of which also emit gamma rays). These create radionuclides including: • Radium-226 • Radon-222 • Polonium-210

  14. Calculation of age of rocks from 206Pb to 238U ratios(assumes secular equilibrium) where l is ln2 /T1/2 and T1/2 is the decay half-life of 238U (~4.5x109 years). which solves to (can do the same for 235U : 207Pb ratios in the same samples…)

  15. Radiation occurs in nature…the earth is ‘bathed’ in radiation from a variety of sources. • Humans have evolved with these levels of radiation in the environment. Naturally Occurring Radioactive Materials These include Uranium-238, which has radioactive half-life of 4.47 billion years. 238U decays via a series of alpha and beta decays (some of which also emit gamma rays). These create radionuclides including: • Radium-226 • Radon-222 • Polonium-210 (all of which are a emitters). Other NORM includes 40K (in bones!)

  16. Can also use other (primordial) isotope ratios… • 40K decay to 40Ar. • T1/2 for 40K is 1.2x109 years. • Taking mass ratios using mass spectrographs in rock inclusions, can date the rock using the equation: • The factor 0.109 is due to the ‘branching ratio’ in the decay of 40K, i.e., only 10.9% of the time does it decay to 40Ar (see later). • 87Rb - 87Sr. • 147Sm -143Nd (alpha decay)

  17. ‘signature’ 1461 keV gamma Interesting aside: 40K decays by all three forms of ‘beta’ decay, b+ and electron capture (ec) to 40Ar; & b- to 40Ca. Signature of decay of 40K is the 1461 keV gamma ray.

  18. Why are primordial nuclei so long lived?

  19. The alpha particle quantum mechanically ‘tunnels’ through a ‘Coulomb energy barrier’ to escape the mother nucleus. The width of this energy barrier depends on the energy released in alpha decay (Qa ≈ Ea). The relationship between Qa and tunnelling probability and hence the decay lifetime is the Geiger-Nuttall rule. See H. Geiger & J.M.Nuttall Philosophical Mag. 22 (1911) p613-621. ‘The ranges of a particles from various radiaoctive substances and a relation between range and period of transformation’

  20. How (and why) do you measure the gamma rays from NORMs?

  21. Nuclear Data Evaluations:

  22. RISING array @ GSI (105 germanium detectors)

  23. Gamma-ray spectra show clearly the levels and nature of the Naturally Occurring Radioactive Material (NORM) in, for example, beach sand. Note, also other radioactivities might be present which don’t emit signature gamma rays. Examples are: 14C from cosmic ray interactions & 90Sr fission reside from weapons tests / fission fallout. D.Malain, PhD thesis, University of Surrey (2011)

  24. ‘sand sample (2 days) ‘background (2 days)

  25. Making a Radiological Map of Qatar • Arabic Gulf state, • Oil Rich (oil industry all around) • To host World Cup (2022)

  26. How do we use the Activity Concentration measurements? The gamma dose rate (D) in units of nGy/hour in the outdoor air can be estimated using dose conversion coeffs… 40K 226Ra 232Th A = measured specific activity concentration (Bq/kg) Gy = unit of radiation dose = 1 Joule / kg (1 Sv = Wr x 1Gy) This leads to calculation of effective annual doses from NORM (in mSv/year) = 0.00123D assuming an outdoor occupancy of 20%.

  27. Other useful calculated properties? 1) Radium equivalent activity, Raeq: On assumption that 370 Bq/kg of 226Ra (max permissable Raeq) or 259 Bq/kg of 232Th or 4810 Bq/kg of 40K produce the same gamma-ray dose. 2) External Hazard Index (Hex): Hex should be <1 for an ‘insignificant radiation hazard).

  28. Summary • Very old NORMs such as 238U, 232Th, 40K are everywhere. • Do they cause additional biological harm? • Need to measure the levels and types of radiation / nuclei present to make a scientific assessment of this. • Provision of measurement of background levels is also important regarding non-proliferation and remediation following nuclear power decommissioning / nuclear accidents. • Useful in ageing the earth (to around 4.5 x109 years).

More Related