“Radioactive Clocks” or Radiometric Dating The time span of “relevant” events varies from a few centuries to billions of years ? historians ? archeologists, ? anthropologists, ? geologists, ? astrophysicists Radioactive Decay ? independent of the age of the nucleus ? unaffected by heat ? pressure, ? magnetic and electric influences ? in fact, all external forces. The basis for all radioactive dating methods is this constancy of decay rate. t eNN λ? = 0 ? Radioactive clocks are widely used for the dating of archeological and geological and cosmic materials. ? The time elapsed since the incorporation of a “long-lived” radioactive element into a closed system can be inferred from the residual activity or from the amount of elements formed in the decay. Uncertainties: ? What is the amount of the daughter present when the rocks were formed? ? Have any parent or daughter atoms been added or lost during the process? 1 Some Naturally occurring Radioactive Isotopes and their Half-lives Radioactive Isotope (Parent) Product (Daughter) Half-life (years) Samarium-147 Neodymium-143 106 billion Rubidium-87 Strontium-87 48.8 billion Rhenium-187 Osmium-187 42 billion Lutecium-176 Halfnium-176 38 billion Thorium-232 Lead-208 14 billion Uranium-238 Lead-206 4.5 billion * Potassium-40 Argon-40 1.26 billion Uranium-235 Lead-207 0.7 billion Beryllium-10 Boron-10 1.52 million Chlorine-36 Argon-36 300,000 * Carbon-14 Nitrogen-14 5730 Uranium-234 Thorium230 248,000 Thorium-230 Radium-226 75,400 2 Radiocarbon dating The radiocarbon method was developed by a team of scientists led by the late Professor Willard F. Libby of the University of Chicago in the late 1940s. Libby later received the Nobel Prize in Chemistry in 1960: "for his method to use Carbon-14 for age determinations in archaeology, geology, geophysics, and other branches of science." According to one of the scientists who nominated Libby as a candidate for this honour; “Seldom has a single discovery in chemistry had such an impact on the thinking of so many fields of human endeavour. Seldom has a single discovery generated such wide public interest." Carbon-14 Images removed. See 1 st and 2 nd figures in Hyperphysics, “Carbon Dating.” [cited 26 March 2004]. http://hyperphysics.phy-astr.gsu.edu/hbase/nuclear/cardat.html ? 14 C is produced in the upper atmosphere: ? cosmic ray bombardment of molecules produces neutrons ? 14 N(n,p) 14 C reaction produces 14 C ? 14 C combines with O 2 to form CO 2 ? 14 CO 2 equilibrates with 12 CO 2 and is incorporated into organic matter ? Carbon dating only applicable to matter which was living 14 C Equilibrium Activity Living organisms continually exchange CO 2 with the atmosphere ? At equilibrium with the atmosphere ? Assumes that rate of 14 C production is constant (not true) 12 12 6 14 6 103.1 ? ≈ x C C 3 Specific Activity of 14 C ~ 15 Bq/gram total carbon 14 C half-life = 5730 years Beta-minus emission to 14 N Beta energy = 0.016 MeV (not very penetrating), will not come out of solid samples Samples usually oxidized to form CO 2 14 C in the gas is counted Required large samples (1-2 g carbon) and long counting times (up to 15 hours) Image removed. See 3rd figure in Hyperphysics, “Carbon Dating.” [cited 26 March 2004]. http://hyperphysics.phy-astr.gsu.edu/hbase/nuclear/cardat.html Image removed. t eNN λ? = 0 Image removed. Figure 1: The "Curve of Knowns" after Libby and Arnold (1949). The first acid test of the new method was based upon radiocarbon dating of known age samples primarily from Egypt (the dates are shown in the diagram by the red lines, each with a ±1 standard deviation included). The Egyptian King's name is given next to the date obtained. The theoretical curve was constructed using the half-life of 5568 years. The activity ratio relates to the carbon 14 activity ratio between the ancient samples and the modern activity. Each result was within the statistical range of the true historic date of each sample. The original measurements of Libby were calibrated by using organic samples of known age—including historical artifacts from Egypt. 4 Corrections required Image removed. Tree rings ? Bristlecone Pines ? Some living speciments > 4000 years old ? Dead specimens overlap back to ~ 8000 years old ? Same samples used for 14 C dating Corrections are needed for ages greater than ~ 2000 years. E.g., 14 C date of 3000 B.C. Corrected date = 3650 B.C. Suess Effect or Industrial Effect (Hans Suess, 1950) ? Burning of fossil fuel since ~ 1890 has added 12 CO 2 to the atmosphere ? Effectively dilutes the 14 C/ 12 C ratio by ~2% ? 1890 wood was used as a calibration standard and corrected for decay to 1950. Nuclear Weapons ? Weapons testing in the atmosphere produces enormous amounts of neutrons ? Neutrons interact with nitrogen producing 14 C through the same 14 N(n,p) 14 C reaction. ? Maximum effect was in ~ 1963 ? The amount of 14 C in the atmosphere was doubled! ? Ratio is returning to “normal” 5 Accelerator Mass Spectrometry: A more sensitive approach 15 Bq/g beta count rate for a 1 gram sample, when there are actually ~ 10 12 atoms of 14 C present in the 1 gram sample is not very efficient. Accelerator Mass Spectrometry counts all atoms: the ratio of 14 C to 12 C can be directly measured. Sensitivity ~ 10 -15 in the 14 C/ 12 C ratio has been achieved Modern techniques require only mg samples. Image removed. See 1 st figure in Hyperphysics, “Mass Spectrometer.” [cited 26 March 2004]. http://hyperphysics.phy-astr.gsu.edu/hbase/magnetic/maspec.html. contaminants of mass 14: 14 N 12 CH 2 13 CH removed during the sputtering, acceleration, stripping process.. 6 The Shroud of Turin Images removed. ? Said to be the burial cloth of Christ. ? Bears faint impression (in 3D) of a naked crucified man. ? Libby offered to carbon date the Shroud in the 1940s (sample size required was too large) ? AMS techniques: 1988 3 samples dated in three separate laboratories ? 1290-1390 A.D. dates widely publicized ? (see http://www.shroud.com) The dating controversy continues… Image removed. See Damon, P.E. et. al. “Radiocarbon dating of the Shroud of Turin.” Nature 337 (1989) 302. The shroud samples (0.25 inch x 0.25 inch ) and three control samples were put in encoded stainless steel cylinders and taken back to the three laboratories. The age of the shroud, as determined by the 14 C/ 12 C ratio measured by AMS, was found to be 1290-1390 AD (95% confidence) in a widely publicized series of 'blind' measurements at 3 AMS labs throughout the world. 7 Potassium-40/Argon-40 Method 40 K: half-life = 1.2 x 10 9 years Major Advantage: offers a means to eliminate daughter atoms present at time=0. ? 40 K → 40 Ar daughter is a noble (non-reactive) gas ? 40 Ar is assumed to be completely volatilized in igneous rocks. Crystals: no gas exchange ? All 40 Ar present within the crystal must have been created in situ by 40 K decay. The “Age Equation” (show that this is equivalent to ) t eNN λ? = 0 Oldest terrestrial rocks: ~ 3.8 x 10 9 years Oldest meteor/moon rocks: ~ 4.5 x 10 9 years 8 Image removed. The Isochron Method 87 Rb → 87 Sr ? Three other non-radiogenic isotopes of Sr usually present along with 87 Sr ? 84 Sr, 86 Sr, 88 Sr ? The ratio of 87 Sr/ 87 Rb increases over time ? 87 Sr ratios to 84 Sr, 86 Sr 88 Sr also increase ? Plotted ratios form straight lines ? Slope proportional to the age of the sample 9 The Age of the Earth Some of the oldest rocks on earth are found in Western Greenland. Because of their great age, they have been especially well studied. The table below gives the ages, in billions of years, from twelve different studies using five different techniques on one particular rock formation in Western Greenland, the Amitsoq gneisses. Technique Age Range (billion years) uranium-lead 3.60±0.05 lead-lead 3.56±0.10 lead-lead 3.74±0.12 lead-lead 3.62±0.13 rubidium-strontium 3.64±0.06 rubidium-strontium 3.62±0.14 rubidium-strontium 3.67±0.09 rubidium-strontium 3.66±0.10 rubidium-strontium 3.61±0.22 rubidium-strontium 3.56±0.14 lutetium-hafnium 3.55±0.22 samarium-neodymium 3.56±0.20 10