Keywords:
Isotope geology.
;
Electronic books.
Description / Table of Contents:
Written by one of the most respected geochemists, this is a comprehensive introduction to radiogenic and stable isotope techniques. It is a superb textbook specifically tailored for undergraduate and graduate courses, and is also an excellent reference for earth scientists. There are problems at the end of each chapter, with solutions at the end of the book.
Type of Medium:
Online Resource
Pages:
1 online resource (534 pages)
Edition:
1st ed.
ISBN:
9780511454202
URL:
https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=377899
DDC:
551.9
Language:
English
Note:
Cover -- Half-title -- Title -- Copyright -- Dedication -- Contents -- Preface -- Acknowledgments -- Chapter One: Isotopes and radioactivity -- 1.1 Reminders about the atomic nucleus -- 1.2 The mass spectrometer -- 1.2.1 The principle of the mass spectrometer -- 1.2.2 The components of a mass spectrometer -- The source -- The magnet -- The collectors -- The vacuum -- Efficiency -- Power of resolution -- Abundance sensitivity -- 1.2.3 Various developments in mass spectrometers -- Ionization -- Ion optics -- 1.2.4 Preparatory chemistry and final accuracy -- 1.2.5 Ionization techniques and the corresponding spectrometers -- Thermal-ionization mass spectrometry (TIMS) -- Electronic bombardment -- Inductively coupled plasma mass spectrometry (ICPMS) in an argon plasma -- Ionic bombardment in secondary-ion mass spectrometry (SIMS) -- 1.3 Isotopy -- 1.3.1 The chart of the nuclides -- 1.3.2 Isotopic homogenization and isotopic exchange -- 1.3.3 A practical application of isotopic exchange: isotopic dilution -- 1.4 Radioactivity -- 1.4.1 Basic principles -- 1.4.2 Types of radioactivity -- Beta-minus radioactivity -- Beta-plus radioactivity and electron capture -- Alpha radioactivity -- Spontaneous fission -- 1.4.3 Radioactivity and heat -- Problems -- Chapter Two: The principles of radioactive dating -- 2.1 Dating by parent isotopes -- 2.2 Dating by parent-daughter isotopes -- 2.2.1 Principle and general equations -- 2.2.2 Special case of multiple decay -- 2.2.3 Main geochronometers based on simple parent-daughter ratios -- 2.3 Radioactive chains -- 2.3.1 Principle and general equations -- 2.3.2 Secular equilibrium: uranium-lead methods -- 2.3.3 The special case of lead-lead methods -- 2.3.4 The helium method -- 2.3.5 The fission track method -- 2.3.6 Isolation of a part of the chain and dating young geological periods.
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The radioactive isotope becomes isolated on its own -- The parent isotope is isolated and engenders its daughters -- 2.3.7 General equation and equilibration time -- Uranium-238 chain -- Uranium-235 series -- Thorium-232 chain -- 2.4 Dating by extinct radioactivity -- 2.4.1 The historical discovery -- 2.4.2 Iodine-xenon dating -- 2.4.3 Discoveries of other forms of extinct radioactivity -- 2.5 Determining geologically useful radioactive decay constants -- 2.5.1 Measurement of activity -- 2.5.2 The radiogenic isotope produced -- 2.5.3 The method of geological comparison -- Moon rocks -- Eucrites (basaltic achondrites) -- Ordinary chondrites -- 2.5.4 Conclusions -- Problems -- Chapter Three: Radiometric dating methods -- 3.1 General questions -- 3.1.1 Rich systems, poor systems -- 3.1.2 Closed system, open system -- 3.1.3 Continuous or episodic losses -- 3.1.4 Concordant and discordant ages -- 3.2 Rich systems and solutions to the problem of the open system -- 3.2.1 The semi-quantitative systematic comparative approach -- Laboratory study of diffusion and extrapolation -- The study of contact metamorphism -- 3.2.2 The concordia method -- Uranium-lead systems -- Generalizing the concordia method -- 3.2.3 Stepwise thermal extraction -- The 39Ar-40Ar method -- Direct 206Pb-207Pb analysis -- 3.3 Poor systems and the radiometric isotopic correlation diagram -- 3.3.1 The 87Rb-87Sr system -- 3.3.2 Two-stage models -- 3.3.3 Extension of the isochron graph to other radiochronometers -- The case of 147Sm-144Nd -- The case of 176Lu-176Hf -- The case of 187Re-187Os -- The case of uranium-thorium-lead -- 3.3.4 The lead-lead method -- 3.3.5 The 230Th-238U method and disequilibria of radioactive chains -- 3.3.6 Extinct radioactivities -- The case of 26Al-26Mg -- The case of 129I-129Xe -- 3.3.7 Conditions of use of the isochron diagram.
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3.4 Mixing and alternative interpretations -- 3.4.1 Mixing -- 3.4.2 The (1/C) test -- 3.5 Towards the geochronology of the future: in situ analysis -- 3.5.1 The ion probe -- 3.5.2 Laser ionization -- Problems -- Chapter Four: Cosmogenic isotopes -- 4.1 Nuclear reactions -- 4.1.1 General principles -- 4.1.2 Effective cross-sectional area -- The kinetics of a nuclear reaction -- Energy dependence of the effective cross-sectional area -- 4.1.3 Classification of nuclear reactions -- Nucleon absorption -- Proton-neutron or neutron-proton exchange -- Reactions involving alpha particles -- Spallation reactions -- Fission reactions -- 4.1.4 Absorption of particles by matter in the case of nuclear reactions -- 4.1.5 Galactic cosmic radiation -- 4.2 Carbon-14 dating -- 4.2.1 The principle of 14C dating -- 4.2.2 Measuring 14C -- The counting method -- The accelerator mass spectrometry method (AMS) -- 4.2.3 Conditions for performing 14C dating -- The closed system -- Determining the initial 14C content -- Synthetic formula for age calculation -- 4.2.4 Other forms of cosmogenic radioactivity -- Beryllium-10 -- 4.2.5 Dating oceanic cycles with 14C -- 4.3 Exposure ages -- 4.3.1 Meteorites -- Stable isotopes -- Radioactive isotopes -- 4.3.2 Terrestrial rocks -- Exploitable chronometers -- Calibration of production rates, erosion rates, etc. -- Erosion ratemeasurements -- Measuring the rate of uplift -- Interestand limits of thesemethods -- 4.4 Cosmic irradiation: from nucleosynthesis to stellar and galactic radiation -- 4.4.1 The transition from the proton to helium -- 4.4.2 The synthesis of alpha elements -- 4.4.3 The iron peak -- 4.4.4 Neutron addition -- 4.4.5 The p-process -- 4.4.6 The light elements lithium, beryllium, and boron -- 4.4.7 The stellar adventure: the life and death of stars -- Problems.
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Chapter Five: Uncertainties and results of radiometric dating -- 5.1 Introduction -- 5.2 Some statistical reminders relative to the calculation of uncertainties -- 5.2.1 Systematic uncertainties -- 5.2.2 Pseudo-random uncertainties -- 5.2.3 Composite uncertainty -- Addition of operations -- Multiplication or division operations -- 5.3 Sources of uncertainty in radiometric dating -- 5.3.1 Uncertainties introduced when collecting samples -- 5.3.2 Physical uncertainties on an individual measurement -- Uncertainties on ages obtained from parent decay methods (14C, 10Be, etc.) -- Overall estimation of uncertainty on long half-life parent-daughter methods -- 5.3.3 Uncertainties on age calculations -- Individual age statistics -- Uncertainties in measuring straight lines of isotope evolution -- Presence or absence of alignment -- The correlation coefficient -- Inclusion of experimental uncertainties -- 5.3.4 Calculating the equation of the straight line of correlation -- 5.4 Geological interpretations -- 5.4.1 General remarks -- 5.4.2 Case studies -- Contact metamorphism of the Eldora stock -- TheU^Pb systemon zircon -- The 87Rb^87Sr system in isochron construction -- The (Rb^Sr,K^Ar) measurements onmicas discussed with the generalized concordia diagram -- The 40Ar^39 Armeasurements -- The very ancient rocks of Greenland -- Archean komatiites -- The rhyolite of Long Valley, California -- Conclusions -- 5.5 The geological timescale -- 5.5.1 History -- 5.5.2 The absolute scale of fossiliferous (Phanerozoic) times -- The case of the Quaternary -- 5.5.3 The Precambrian timescale -- 5.6 The age of the Earth -- 5.6.1 History -- 5.6.2 The isotopic approach -- 5.6.3 The modern approach -- 5.7 The cosmic timescale -- 5.7.1 Meteorite ages -- 5.7.2 The history of the Moon -- 5.7.3 Pre-solar cosmochronology -- The different scenarios of uranium nucleosynthesis12.
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The contribution of extinct radioactivity -- Discussion and conclusions -- 5.8 General remarks on geological and cosmic timescales -- 5.8.1 Overall geological myopia -- 5.8.2 The use of radiochronometers -- Domains for using geochronometers based on analytical criteria -- Geological modulation of the time domains for the use of radiochronometers -- 5.9 Conclusion -- Problems -- Chapter Six: Radiogenic isotope geochemistry -- 6.1 Strontium isotope geochemistry -- 6.1.1 Continents and oceansgranite and basalt -- 6.1.2 Isotope evolution diagrams and multi-episode evolution models -- 6.1.3 Granites and granites -- 6.1.4 Basalt and oceanic basalt -- 6.1.5 Comparative "prehistoric" evolution of MORB and OIB: the concept of a model age -- 6.1.6 The problem of mixtures -- 6.1.7 Isotopic exchange -- 6.1.8 The Schilling effect -- 6.2 Strontium-neodymium isotopic coupling -- 6.2.1 Neodymium isotope variations -- 6.2.2 The epsilonNd notation -- 6.2.3 The Sr-Nd isotope correlation of basalts -- 6.2.4 Position of granites in the (Sr, Nd) diagram -- 6.2.5 Back to the isotope evolution diagrams -- 6.2.6 Evolution of time in the (Nd, Sr) isotope diagram and the questiongeochemical differentiation or mixing? -- 6.2.7 Mixing in isotope ratio correlation diagrams -- 6.2.8 The Sr-Nd-Hf system -- 6.3 The continental crust-mantle system -- 6.3.1 The chronology of extraction of continental crust -- 6.3.2 The mass of the depleted mantle and the mantle structure -- 6.3.3 Changes in the Rb-Sr and Sm-Nd systems over geological time -- Comments -- Strontium -- Neodymium -- 6.3.4 The process of development of continental crust over geological time -- Continental reworking -- The neodymium model age and its geological applications -- Neodymium model ages of granites over geological time -- Genetic cartography of continents -- Australian detrital zircons.
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6.4 Isotope geochemistry of rare gases.
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