DOCSLIB.ORG

V Semester Zoology Fossils and Fossil Dating

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
V Semester Zoology Fossils and Fossil Dating V SEMESTER ZOOLOGY FOSSILS AND FOSSIL DATING Fossils can include anything that gives an indication of the existence of prehistoric organisms. The Latin word Fossilium means ‘dug out’, which in earlier times meant to include any traces of body of animals and plants buried and preserved by natural causes. George Curvier (1769-1832) is considered ‘Father of palaeontology’, who studied fossils scientifically to develop phylogenies. Types of fossils Based on the mode of formation of fossils, they can be categorised in several types. Fossilisation is a rare phenomenon, which takes place under specialised conditions. The study of natural process of death, burial, decomposition, preservation and transformation into fossil is called taphonomy. Fossils are the only direct evidence of the biological events in the history of earth and hence important in the understanding and construction of the evolutionary history of different groups of animals and plants. 1. Petrifaction Petrifaction is molecule-by-molecule replacement of organic matter by inorganic compounds, viz. silica, calcium carbonate or iron pyrites. It literally means “turned into stone” and takes place in buried situations, particularly at the bottom of lakes, ponds or sea, where there are sediments rich in calcium carbonate and silica. Over millions of years, inorganic matter replaces the entire bony material, making an exact replica of the original. By this time sediments transform into sedimentary rocks, in which fossils can remain preserved for a long time. Most of the old fossils are petrified, e.g. shells of molluscs, arthropods and fish skeletons. 2. Preservation of footprints When animals walk on wet soil and sand, they leave trail of footprints or limbless animals and worms may leave tracks and trails in mud. If these footprints are covered by volcanic ash, they can be preserved for a long time as the clay containing footprints and the volcanic ash covering it will harden to form different types of rocks. Mary Leakey discovered footprints of prehistoric man along with those of giraffes, elephants, guinea fowls etc. in Kenya. 3. Burrows and borings Annelid worms, arthropods and molluscs make burrows in soil or bore into hard wood, rocks or corals. These are preserved as the soil hardens to form rock. 1 4. Coprolites Sometimes excreta of animals is buried and fossilised, which gives an indication of the diet of animals. For example, carboniferous nodular excreta of salamanders have been found in Illinois in USA. Huge deposits of guano of sea birds have been found in South American seacoast. 5. Impressions Impressions of body parts, skin, feathers, leaves etc. are formed when they are pressed hard against the soft clay, which subsequently hardens to form rock. Fossil of Archaeopteryx is such an impression. More bird fossils in the form of impressions have been discovered in China recently, e.g. fossils of Sinosauropteryx, Caudipteryx and Confusiusornis. 6. Moulds and casts Moulds are formed by hardening of the material surrounding the body of an animal, such as volcanic ash or lava that flows into the sea and traps molluscs and arthropods. Animal body disintegrates leaving the hollow mould, which gives an indication of the contour of the animal. If this mould is filled with inorganic material such as calcium carbonate or silica that will harden to form a cast, it will be an exact replica of the animal body. 7. In petroleum and asphalt In some coastal areas where there is abundance of petroleum pools and tar- pits, small animals, birds and insects get entrapped in them. In asphalt the process of decay is very slow and if these are buried in soil, they are preserved for a long time. 8. In resin and amber Resin is a sticky substance that exudes from coniferous trees and traps small insects such as flies and mosquitoes. Resin hardens to form amber and preserves the insects with all fine details. Most of the insect fossils are fossilized in this way. 9. In ice Ice is a good preservative even of softer body parts. If animals are buried deep in snow that never melts, then they are preserved entirely for a long time. Fossil of woolly mammoth from the permafrost in Siberia is an excellent example of preservation in ice, in which even flesh, skin and hair are preserved. Index fossils: Fossils that are found in undisturbed sedimentary rocks and in short geological time period generally lie in recognisable strata of older rocks below and subsequently formed layers above. Based on the presence of such fossils in rocks, age of other fossils in the same rock can be determined without dating, because such fossils are an index to a particular geological period. 2 Ammonites are considered good index fossils as different species represent specific geological periods in rocks. Determination of the age of fossils Age of fossils is determined by Radioactive Clock Method, or Radiometric dating, which was devised by Boltwood in 1907 and later by Rutherford in 1955. The rate of disintegration of radioactive material is always constant and is not affected by the environmental factors. The time taken by 50% of the radioactive material to disintegrate into stable element is known as its half-life. If we know the half-life of an element, then the age of the fossil can be calculated by finding out the ratio of radioactive element and its stable daughter element using scintillation counter or Geiger-Muller counter. For example, half-life of Uranium238 is 4.5 billion years. With this rate of decay, one million grams of U238 would yield about 1.7400 grams of Pb206 in one year. OR, in one year one gram of U238 would yield 1/7,400,000,000 grams of Pb206. The radioactive isotope U238 disintegrates into its stable isotope, Pb206 by emitting 8 alpha particles and 6 beta emissions through a chain of daughter radioactive elements. This method is also explained in the following table. Different radioactive materials have different half-life and, therefore, age of recent as well as very old fossils can be determined by selecting the appropriate radioactive element, provided that the element is present in that particular rock. Carbon dating This method was devised by W.F. Libby in 1956 by recognising the fact that all living organisms have C14, the radioactive isotope of carbon in their bodies, which starts disintegrating after their death into C12 or N14 by the release of an electron, as it is no longer replenished after the death of animal or plant. This radioactive carbon is taken up by plants in the form of carbon dioxide, and animals get it into their bodies from plants. Since after death, animals and plants do not replenish C14 through food, it only decays at a constant rate. The rate of decay is found out by counting the number of beta particles emitted by C14 per unit time, using Scintillation counter, Wilson-cloud chamber or Geiger- Muller counter (that use CO2 gas) and then feeding the data into a computer. Fluorine dating When there is water seepage through the bones, fluorine in water combines with calcium in bones to form fluorapatite, whose proportion in the bones can be detected to find out the age of the fossil. Nitrogen dating This method works on collagen degradation in the bones and accumulation of other materials such as fluorine. How much nitrogen is retained in the bone gives an idea of the age of the fossil. 3 Uranium dating Bones buried in soil absorb uranium at a constant rate and longer they lay in those strata more uranium they will absorb. Since uranium is radioactive, its presence in the bones can be detected using scintillation counter. Fission-track dating Trace amount of Uranium238 impurities are commonly found in nature and spontaneous fission of this radioactive element produces small, permanent, microscopic damage trails in the insulating solids through long periods. Simple count of numbers of such trails gives the age of the fossils. Potassium-Argon dating Potassium is abundant in nature and its isotope K39 comprises over 93% of the total, while K40 is only 0.0118% and K41 6.8%. K40 decays into its daughter isotopes, viz. Ca40 by beta decay and A40 by K capture, in a half life of 1.3 billion years. The ratio of the daughter isotopes can be detected in a mass spectrophotometer. This method is used to detect the age of very old fossils but theoretically potassium rich samples as young as 5,000 year old can also be dated. Amino acid racemization dating The method is based on the fact that all animals have L-amino acids in their proteins which after death transform by racemization into D-amino acids, whose proportion increases with time. The ratio of the two types of amino acids will give the age of the skeletal material in the fossil. 4 .
Load more

Recommended publications
  • An Annotated Select Bibliography of the Piltdown Forgery
    An annotated select bibliography of the Piltdown forgery Informatics Programme Open Report OR/13/047 BRITISH GEOLOGICAL SURVEY INFORMATICS PROGRAMME OPEN REPORT OR/13/47 An annotated select bibliography of the Piltdown forgery Compiled by David G. Bate Keywords Bibliography; Piltdown Man; Eoanthropus dawsoni; Sussex. Map Sheet 319, 1:50 000 scale, Lewes Front cover Hypothetical construction of the head of Piltdown Man, Illustrated London News, 28 December 1912. Bibliographical reference BATE, D. G. 2014. An annotated select bibliography of the Piltdown forgery. British Geological Survey Open Report, OR/13/47, iv,129 pp. Copyright in materials derived from the British Geological Survey’s work is owned by the Natural Environment Research Council (NERC) and/or the authority that commissioned the work. You may not copy or adapt this publication without first obtaining permission. Contact the BGS Intellectual Property Rights Section, British Geological Survey, Keyworth, e-mail [email protected]. You may quote extracts of a reasonable length without prior permission, provided a full acknowledgement is given of the source of the extract. © NERC 2014. All rights reserved Keyworth, Nottingham British Geological Survey 2014 BRITISH GEOLOGICAL SURVEY The full range of our publications is available from BGS shops at British Geological Survey offices Nottingham, Edinburgh, London and Cardiff (Welsh publications only) see contact details below or shop online at www. geologyshop.com BGS Central Enquiries Desk Tel 0115 936 3143 Fax 0115 936 3276 The London Information Office also maintains a reference collection of BGS publications, including maps, for consultation. email [email protected] We publish an annual catalogue of our maps and other publications; this catalogue is available online or from any of the Environmental Science Centre, Keyworth, Nottingham BGS shops.
    [Show full text]
  • Relative Dating
    Relative Dating Introduction: In the early stage of prehistoric studies, dating of any event or site was obtained tentatively. A particular event or specimen is dated in relation to other event or some reference point. Such type of dating techniques are known as relative dating by which one can know or understand whether a particular culture is younger or older than the other one. That is, through relative dating, it is known that culture A is older than culture B but how old A and B are, or how much later B is than A in terms of number of years is unknown. These dating methods have never been able to provide a date in terms of numerical value or years, nor it can calculate the total time span involved in each cultural period. However, with the help of such dating methods a series of events or things can be arranged in a sequential time frame. The relative chronology, in the words of Wheeler (1956), is “... the arrangement of the products of non-historic societies into a time relationship which may not have any dates but which has a sequence....” Types of Relative Dating: Till the early part of 19th century quite a good number of relative dating methods have been in used in archaeological studies. These relative dating methods are basically depending upon stratigraphic position of the site or kind of remains associated with the site. Some of the relative dating methods are: 1 i) Stratigraphy ii) Typology iii) Fluorine test iv) Uranium and nitrogen analysis v) Palaeontology vi) Palynology vii) Cross dating viii) Sequence dating All these relative dating methods tend to compare a given event with some other events in a time sequence.
    [Show full text]
  • Ancient Protein Analysis in Archaeology
    This is a repository copy of Ancient protein analysis in archaeology. White Rose Research Online URL for this paper: https://eprints.whiterose.ac.uk/171551/ Version: Published Version Article: Hendy, Jessica orcid.org/0000-0002-3718-1058 (2021) Ancient protein analysis in archaeology. Science Advances. eabb9314. ISSN 2375-2548 https://doi.org/10.1126/sciadv.abb9314 Reuse This article is distributed under the terms of the Creative Commons Attribution-NonCommercial (CC BY-NC) licence. This licence allows you to remix, tweak, and build upon this work non-commercially, and any new works must also acknowledge the authors and be non-commercial. You don’t have to license any derivative works on the same terms. More information and the full terms of the licence here: https://creativecommons.org/licenses/ Takedown If you consider content in White Rose Research Online to be in breach of UK law, please notify us by emailing [email protected] including the URL of the record and the reason for the withdrawal request. [email protected] https://eprints.whiterose.ac.uk/ SCIENCE ADVANCES | REVIEW ANTHROPOLOGY Copyright © 2021 The Authors, some Ancient protein analysis in archaeology rights reserved; exclusive licensee Jessica Hendy1,2 American Association for the Advancement of Science. No claim to The analysis of ancient proteins from paleontological, archeological, and historic materials is revealing insights original U.S. Government into past subsistence practices, patterns of health and disease, evolution and phylogeny, and past environments. Works. Distributed This review tracks the development of this field, discusses some of the major methodological strategies used, and under a Creative synthesizes recent developments in archeological applications of ancient protein analysis.
    [Show full text]
  • Research Notes and Application Reports Nitrogen and Fluorine Dating of Moundville Skeletal Samples
    Archaeometry 24, 1 (1982) 37-44. Printed in Great Britain RESEARCH NOTES AND APPLICATION REPORTS NITROGEN AND FLUORINE DATING OF MOUNDVILLE SKELETAL SAMPLES A. HADDY Museum of Anthropology, University of Michigan, Ann Arbor, Michigan, U.S.A. and A. HANSON Brookhaven National Laboratory, Upton, New York 11 973, U.S.A. INTRODUCTION A large group of human bones were excavated during the 1930’s from the Moundville archae- ological site in Alabama. If a chronology could be assigned to them, the bones might provide a guide to the changes which took place as Moundville flourished, since pottery and other objects were often buried with the individuals. A recent pottery classification based on style suggests three major time periods at Moundville (Steponaitis, 1978): Moundville I A.D. 1100-1250 Moundville I1 A.D. 1250-1400 Moundville 111 A.D. 1400-1550 Since all of the bones were treated upon unearthing with the preservative Alvar, the trade name for polyvinyl acetate, absolute dating by carbon-14 is not possible. In this preliminary study nineteen bone samples from fifteen individuals were analyzed for nitrogen and fluorine, since the concentrations of these elements will provide relative dates for the bones. Nitrogen dating is based on the fact that buried bones and teeth lose nitrogen over time. Fresh human bone contains about 5% nitrogen (Ortner et al. 1972), mostly in the form of the protein collagen. As bone decomposes, collagen breaks down into its constituent amino acids whch then leach out of the bone. Thus the nitrogen concentration decreases with time. The rate of nitrogen loss is dependent on environmental factors such as temperature, soil pH, ground water content and collagen-degrading micro-organisms (Ortner et al.
    [Show full text]
  • UNIT 3 ABSOLUTE CHRONOLOGY Relative Chronology
    UNIT 3 ABSOLUTE CHRONOLOGY Relative Chronology Contents 3.1 Introduction 3.2 Absolute Method of Dating 3.3 Radiocarbon Dating or C14 Dating 3.4 Potassium – Argon Method 3.5 Thermoluminescence or TL Dating 3.6 Palaeomagnetic or Archaeomagnetic Dating 3.7 Varve Analysis 3.8 Dendrochronology or Tree-ring Dating 3.9 Amino Acid Racemization Dating 3.10 Oxygen Isotope and Climatic Reconstruction 3.11 Uranium Series Dating 3.12 Summary Suggested Reading Sample Questions Learning Objectives & Once you have studied this unit, you should be able to: Ø define the different types of dating techniques – Relative and Absolute Chronology; Ø understand underlying principles of different absolute dating techniques; Ø understand reasons why particular techniques are appropriate for specific situation; and Ø understand the limitations of different dating techniques. 3.1 INTRODUCTION Archaeological anthropology is unique with respect to the other branches of the social sciences and humanities in its ability to discover, and to arrange in chronological sequence, certain episodes in human history that have long since passed without the legacy of written records. But the contributions of archeology to this sort of reconstruction depend largely on our ability to make chronological orderings, to measure relative amounts of elapsed time, and to relate these units to our modern calendar. Many important problems in archeology like origins, influences, diffusions of ideas or artifacts, the direction of migrations of peoples, rates of change, and sizes of populations in settlements can be solved with the help of different methods of dating. In general, any question that requires a definite statement like the type, A is earlier than B, depends on dating.
    [Show full text]
  • Paleoanthropological Methods: Dating Fossils "Archaeologists Will Date Any Old Thing" (Jim Moore, UCSD)
    Paleoanthropological methods: Dating fossils "Archaeologists will date any old thing" (Jim Moore, UCSD) Taphonomy: study of processes of fossilization (literally, "laws of burial"; study of diagenetic processes acting on a dead animal's remains). Diagenesis: sum of the physical, chemical, and biological changes affecting a fossil-bearing sediment; for sedimentary deposits, includes the length of time over which fossils were deposited (single catastrophe or slow accumulation?). mya: Million years ago (my, million years); kya/ky: thousand years I: Why it matters Morris (1985: 220-221) talks about methods used to date fossils. He claims that "... fossils are not dated by the rocks in which they are found; rather, the rocks are 'dated' and correlated by the fossils found in them. ... rocks are 'dated' on the basis of the stage of evolution of their fossils." (p. 220); he argues that this makes dating follow from a belief in evolution rather than the other way round, and so we should reject estimates of an ancient earth (as well as evolution) as based on circular logic. He supports his statements with 3 lengthy quotations from other authors; here's one (Morris, 1985: 220): "The only chronometric scale applicable in geologic history for the stratigraphic classification of rocks and for dating geologic events exactly is furnished by the fossils. Owing to the irreversibility of evolution, they offer an unambiguous time-scale for relative age determinations and for world- wide correlations of rocks" (O. H. Schindewolf, Am. Journal of Science, Vol. 225, June 1957, p. 394). The other two were written in 1952 and 1961.
    [Show full text]
  • Fluorine Dating of Human Bone at the Pre-Columbian Maya Cemetery of Caves Branch Rockshelter, Belize
    University of Mississippi eGrove Electronic Theses and Dissertations Graduate School 2016 Fluorine Dating Of Human Bone At The Pre-Columbian Maya Cemetery Of Caves Branch Rockshelter, Belize Morgan Isaacs University of Mississippi Follow this and additional works at: https://egrove.olemiss.edu/etd Part of the Archaeological Anthropology Commons Recommended Citation Isaacs, Morgan, "Fluorine Dating Of Human Bone At The Pre-Columbian Maya Cemetery Of Caves Branch Rockshelter, Belize" (2016). Electronic Theses and Dissertations. 356. https://egrove.olemiss.edu/etd/356 This Thesis is brought to you for free and open access by the Graduate School at eGrove. It has been accepted for inclusion in Electronic Theses and Dissertations by an authorized administrator of eGrove. For more information, please contact [email protected]. FLUORINE DATING OF HUMAN BONE AT THE PRE-COLUMBIAN MAYA CEMETERY OF CAVES BRANCH ROCKSHELTER, BELIZE A Thesis Presented for the Master of Arts Degree The University of Mississippi Morgan Isaacs December 2016 Copyright © 2016 by Morgan Isaacs All rights reserved ABSTRACT This thesis tests the ion-selective electrode fluorine dating method on the remains from the Maya mortuary site Caves Branch Rockshelter (CBR) in Belize. CBR is a cemetery containing at least 400 burials from the late Preclassic to the Postclassic periods. The intensive use and reuse of the site has disturbed the burial matrices, making it difficult to seriate the burials. Fluorine dating analyzes the amount of fluorine that has accumulated in bone over time. In principle, an older burial will contain more fluorine from groundwater than a more recently buried bone; however, this principle must be tested at each site as fluorine absorption is affected by many environmental factors.
    [Show full text]
  • Taphonomy Has Been Defined As the Study of the Processes by Which Animal and Plant Remains Become Fossilized
    Victim's cranium demonstrating taphonomic evidence of partial burial Taphonomy has been defined as the study of the processes by which animal and plant remains become fossilized. The discipline arose from the work of paleontologists to explain the contexts and conditions of fossilized remains. Taphonomy, with its roots in the Greek “taphos” for tomb or burial, and “nomos”-laws, was adapted by physical anthropologists to explain, and sometimes predict, the condition and contexts of more recent and often forensically significant finds. In this respect, and especially as it applies to forensic situations, taphonomy has come generally to refer to the science of examining transitions of remains from the biosphere to the lithosphere as impacted by weather, animals, plants, biochemical reactions, and cultural factors. Haglund and Sorg (2002), Tibbett and Carter (2006), and Schmidt and Symes (2007) serve as some of the most recent compilations of works discussing the various forms those transitions might entail. They represent three of many source, offered below, which demonstrates the multitude of areas currently being researched to explain reasons for, and the results of, particular transitional events. In this fourteenth edition The general Taphonomy section has been broken into individual sections for topics of "Decomposition and Time Since Death", "Disease, Illness, and Physical Abnormalities", "Thermal Alterations", "Scavenging and Bitemark Evidence", "Trauma" and "General or Miscellaneous Topics". References in each of these sections may be related to other sections of the bibliography. For example, the topic of wounds comprise part of the taphonomic record on a body or it's remains. As a result, one of the largest subsections under Taphonomy is devoted to sharp, blunt, ballistic and other traumas.
    [Show full text]
  • MAN-002 Archaeological Anthropology Indira Gandhi National Open University School of Social Sciences
    MAN-002 Archaeological Anthropology Indira Gandhi National Open University School of Social Sciences Block 4 DATING METHODS UNIT 1 Relevance of Dating 5 UNIT 2 Relative Chronology 21 UNIT 3 Absolute Chronology 33 Expert Committee Professor I. J. S. Bansal Professor S.Channa Retired, Department of Human Biology Department of Anthropology Punjabi University, Patiala University of Delhi, Delhi Professor K. K. Misra Professor P. Vijay Prakash Director Department of Anthropology Indira Gandhi Rashtriya Manav Andhra University, Visakhapatnam Sangrahalaya, Bhopal Dr. Nita Mathur Professor Ranjana Ray Associate Professor Retired, Department of Anthropology Faculty of Sociology Calcutta University, Kolkata SOSS, IGNOU, New Delhi Professor P. Chengal Reddy Dr. S. M. Patnaik Retired, Department of Anthropology Associate Professor S V University, Tirupati Department of Anthropology University of Delhi, Delhi Professor R. K. Pathak Department of Anthropology Dr. Manoj Kumar Singh Panjab University, Chandigarh Assistant Professor Department of Anthropology Professor A. K. Kapoor University of Delhi, Delhi Department of Anthropology University of Delhi, Delhi Faculty of Anthropology SOSS, IGNOU Professor V.K.Srivastava Dr. Rashmi Sinha, Reader Principal, Hindu College University of Delhi, Delhi Dr. Mitoo Das, Assistant Professor Dr. Rukshana Zaman, Assistant Professor Professor Sudhakar Rao Department of Anthropology Dr. P Venkatramana, Assistant Professor University of Hyderabad, Hyderabad Dr. K. Anil Kumar, Assistant Professor Programme Coordinator: Dr. Rashmi Sinha, SOSS, IGNOU, New Delhi Course Coordinator: Dr. P. Venkatramana, SOSS, IGNOU, New Delhi Content Editor Language Editor Professor V. H. Sonawane Dr. Mukesh Ranjan Dept. of Archaeology and Ancient History Associate Professor The Maharaja Sayajirao University of Baroda Jamia Millia Islamia, New Delhi Varansi Blocks Preparation Team Unit Writers Prof.
    [Show full text]
  • Subfossil Lemur Discoveries from the Beanka Protected Area in Western Madagascar
    Quaternary Research Copyright © University of Washington. Published by Cambridge University Press, 2019. doi:10.1017/qua.2019.54 Subfossil lemur discoveries from the Beanka Protected Area in western Madagascar David A. Burneya*, Haingoson Andriamialisonb, Radosoa A. Andrianaivoariveloc, Steven Bourned, Brooke E. Crowleye, Erik J. de Boerf, Laurie R. Godfreyg, Steven M. Goodmanh,l, Christine Griffithsc, Owen Griffithsc,i, Julian P. Humej, Walter G. Joycek, William L. Jungersl, Stephanie Marciniakm, Gregory J. Middletonn, Kathleen M. Muldoono, Eliette Noromalalab, Ventura R. Pérezg, George H. Perrym, Roger Randalanac, Henry T. Wrightp aNational Tropical Botanical Garden, 3530 Papalina Road, Kalaheo, Hawaii 96741, USA bMention Anthropobiologie et Développement Durable, Domaine Sciences et Technologie, Université de Antananarivo, B.P. 906, Antananarivo 101, Madagascar cBiodiversity Conservation Madagascar, B.P. 11028, Antananarivo 101, Madagascar dNaracoorte Lucindale Council, P.O. Box 2153, Naracoorte, Australia eDepartments of Geology and Anthropology, University of Cincinnati, Cincinnati, Ohio 45221, USA fInstitute of Earth Sciences Jaume Almera (ICTJA-CSIC), Lluís Solé i Sabaris s/n, 08028 Barcelona, Spain gDepartment of Anthropology, University of Massachusetts–Amherst, 240 Hicks Way, Amherst, Massachusetts 01003, USA hField Museum of Natural History, 1400 South Lake Shore Drive, Chicago, Illinois 60605, USA iAustralian Museum, 1 William St., Sydney, New South Wales 2010, Australia jBird Group, Department of Life Sciences, Natural History
    [Show full text]
  • Module-4 Excavation and Dating Techniques Topic
    MODULE-4 EXCAVATION AND DATING TECHNIQUES TOPIC- DATING METHODS PRIYANKA.E.K ASSISTANT PROFESSOR DEPARTMENT OF HISTORY LITTLE FLOWER COLLEGE, GURUVAYOOR 2020-2021 DATING METHODS- ABSOLUTE AND RELATIVE DATING TECHNIQUES Archaeologists have used many methods to find out the date of artifacts collected from the archaeological sites. They are mainly classified into three; 1. Relative Dating Methods that identify the order in which sites or artifacts were used in a sequence from earliest to latest. It include historical dating, typology, sequence dating series, geological timescales, varve, pollen analysis, stratigraphy, Geochronology etc Absolute Dating (Chronometric) that try to establish an exact or approximate calendar date for a site or artifacts. It includes Radio-carbon dating, Potassium- argon method, Uranium series method, Thermoluminescence, Electron spin resource (ESR), Dendrochronolgy etc Along with these two broad categories there is another technique named derivative dating method that includes Fluorine test, Uranium test, Nitrogen test, Amino acid test, Obsidian hydration dating, Archaeomagnetic dating, Cation-ratio dating (CR) etc. DENDROCHRONOLOGY A.E Douglass has developed this method in the first half of 20th century. This is the most accurate chronometric dating method. It is an approach based on counting the annual growth rings observable in the cross-sections of cut trees. Every year trees produce a visible ring of new wood under their bark. Early in the annual growing season trees produce thin walled ‘early wood cells. Towards the end of the year thick walled ‘late wood’ cells are produced. This cycle produces a visible ‘ring’ in the wood each year. The rings are wider in good weather conditions than in poor ones and can provide a record of local climate variation.
    [Show full text]
  • UNIT 1 RELEVANCE of DATING Relevance of Dating
    UNIT 1 RELEVANCE OF DATING Relevance of Dating Contents 1.1 Introduction 1.2 Relative Dating 1.2.1 Stratigraphy 1.2.2 Geological Calendar 1.2.3 Glacial Calendar 1.2.4 Fossil Fauna Calendar 1.2.5 River Terraces 1.2.6 Fluorine Test Dating 1.2.7 Nitrogen Dating 1.2.8 Palynology 1.2.9 Patination 1.3 Absolute Dating 1.3.1 Radio Carbon (C14) Dating 1.3.2 Potassium-Argon (K-Ar) Dating 1.3.3 Thermoluminescence (TL) Dating 1.3.4 Archaeomagnetic Dating 1.3.5 Dendrochronology (Tree Ring Analysis) 1.3.6 Varve Analysis 1.3.7 The Oxygen 16/18 Ratio Method 1.3.8 Obsidian Hydration Method 1.4 Summary Suggested Reading Sample Questions Learning Objectives & Once you have studied this unit, you should be able to: Ø discuss about the different kinds of methods to date the archaeological / pre-historic sites; and Ø describe the importance of dating methods in pre-historic Archaeology. 1.1 INTRODUCTION In the study of archaeology, time is no more and no less important than environment. Dating is used to generate temporal units such as period and horisons, which in turn are useful in the study of the growth and development of society. Time is employed in evolutionary studies in order to measure the direction of cultural growth and development as well as rates of change. In practical sense, time is defined by the archeologist / palaeoanthropologist as a succession of events whose order can be defined. In archaeological literature, two types of dating are customarily recognised- relative and absolute.
    [Show full text]