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Fossils and Evolution 870:125

Fossils and Evolution 870:125. Review syllabus Text Supplemental resources Objectives Tests and grading Trip to Ashfall (NE). Ch. 1—Key concepts to know. The fossil record is incomplete. Biological, mechanical and diagenetic agents all destroy potential fossils.

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Fossils and Evolution 870:125

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  1. Fossils and Evolution870:125 • Review syllabus • Text • Supplemental resources • Objectives • Tests and grading • Trip to Ashfall (NE) Fossils & Evolution—Chapter 1

  2. Ch. 1—Key concepts to know • The fossil record is incomplete. Biological, mechanical and diagenetic agents all destroy potential fossils. • Normal fossil preservation is favored by rapid burial of durable hard parts. • Exceptional preservation occurs via rapid burial in fine-grained sediments under low oxygen conditions. • The fossil record is biased because of differential preservation and uneven sampling. It is biased in favor of: 1) durably skeletonized organisms; 2) marine organisms; 3) geologically recent organisms • Because of biases, knowledge of past life is far better at higher taxonomic levels than at lower taxonomic levels Fossils & Evolution—Chapter 1

  3. Key terms(know definitions) • Taphonomy • Biocenosis • Thanatocenosis • Necrolysis • Biostratinomy • Diagenesis • Lagerstätten Fossils & Evolution—Chapter 1

  4. Why study fossils? • Fossil = remains or traces of a once-living organism • Paleontology = the study of fossils • Importance of paleontology • Biostratigraphy (age dating of rocks) • Evolution • Paleoecology/paleoenvironmental interpretation • Paleogeography/paleobiogeography • Simple fascination Fossils & Evolution—Chapter 1

  5. Modes of preservation • Unaltered remains (frozen mammoths; insects in amber; unaltered shells & bones) • Permineralization (infilling of void spaces) • Replacement (molecule by molecule substitution) • Impressions • Carbonization • Molds / casts Fossils & Evolution—Chapter 1

  6. Eocene mammal with partially preserved fur and flesh (Germany) Carbonized Jurassic leaf Fossils & Evolution—Chapter 1

  7. Taphonomy = science of fossilization • Many steps in the process of fossilization, with significant removal of specimens at every step • Once fossilized, the odds of being collected are low (uplift and exposure; weathering; discovery; chance, etc.) Life assemblage (biocenosis) Death assemblage (thanatocenosis) Necrolysis (scavenging, decay) Biostratinomy (break-up, scattering and shallow burial of remains) Diagenesis (deep burial, recrystallization, dissolution, metamorphism, etc.) Initial fossil assemblage Final fossil assemblage Fossils & Evolution—Chapter 1

  8. Life assemblage (biocenosis) Destruction of most soft tissues Death assemblage (thanatocenosis) Destruction of most hard tissues Total fossil assemblage Destruction of most fossils Fossils actually discovered Fossils & Evolution—Chapter 1

  9. Quality of the fossil record • The fossil record is highly biased • Number of fossils is but a fraction of the number of once-living plants and animals Fossils & Evolution—Chapter 1

  10. Fossilization is a rare event! • Some estimates: • > 4,500,000 living species of plants and animals • 250,000 described fossil species • Thus, all described fossil species represent < 5% of the total number of living species • Yet, fossil record covers billions of years and today’s biota is but a snapshot • If preservation were truly efficient, then number of fossil species should dwarf number of extant species Fossils & Evolution—Chapter 1

  11. Standing crop in ¼ m2(offshore Japan) ½ m • 197 shells (~ 200) • Average lifespan = 2 years, thus:……… • 1000 empty shells in 10 years • 100,000,000 empty shells in 1 m.y. • A stack of shells 1000 m high if a layer of 1000 shells is 1 cm thick (actual sedimentary thickness is ~320 m/m.y.) ½ m Fossils & Evolution—Chapter 1

  12. Sources of bias • Uneven preservation potential • Sampling bias Fossils & Evolution—Chapter 1

  13. Uneven preservation potential • Preservation potential of organisms is goverened by • Resistance to destruction • Biological, mechanical, chemical • Hard parts vs. soft parts • Habitat (during life) Fossils & Evolution—Chapter 1

  14. Destruction • Biologic destruction includes • Predation • Scavenging • Boring • Bacterial decay Example: Radiograph of heavily bored gastropod Fossils & Evolution—Chapter 1

  15. Destruction • Mechanical destruction includes breakage and abrasion due to particle interactions caused by wind, waves, currents • Some shells and bones are more resistant to abrasion and breakage than others • Different sizes of the same shells vary in their resistance to abrasion and breakage Fossils & Evolution—Chapter 1

  16. Abrasion experiment (multitaxa) gastropod coral alga coral gastropod Fossils & Evolution—Chapter 1

  17. Abrasion experiment (marine bivalves) large shells small shells Fossils & Evolution—Chapter 1

  18. Durability of vertebrate bones • Durability is governed by bone density and thickness; also by surface area-to-volume ratio: • Least durable • Ribs, vertebrae, breastbone, hip (part), shoulder blade, fingers, toes • Intermediate • Thigh, shin, upper and lower arms, ankles and wrists, hip (part) • Most durable • Teeth, jaws, skull Fossils & Evolution—Chapter 1

  19. Destruction • Chemical destruction varies with: • the original skeletal mineralogy of a fossil • the chemistry of subsurface fluids • temperature of burial environment Fossils & Evolution—Chapter 1

  20. Relative chemical stability Fossils & Evolution—Chapter 1

  21. Destruction • Chemical stability vs. temperature and pressure • Silica is more stable in cold water • Carbonate is more stable in warm water and under low pressures • Dissolution occurs under high pressure and low temperature conditions Fossils & Evolution—Chapter 1

  22. Distribution of modern deep sea pelagic sediments Fossils & Evolution—Chapter 1

  23. Resistance to destruction • Hard parts are much more likely to be preserved than soft parts (but soft parts and even pigments can be preserved) Fossils & Evolution—Chapter 1

  24. Environment and preservability • Best preservation generally occurs in calm, aquatic environments • Exceptional preservation occurs in fine-grained sediments in the absence of oxygen, (“biologically inert” burial conditions) Fossils & Evolution—Chapter 1

  25. Environment and preservability • Lagerstätten (“Mother lode”) = deposits that contain large numbers of unusually well preserved fossils • Burgess Shale (Cambrian, Canada) • Hunsrück Shale (Devonian, Germany) • Mazon Creek Shale (Pennsylvanian, Illinois) • Solnhofen Limestone (Jurassic, Germany) • Baltic amber (Oligocene, Germany) • La Brea tar deposits (Pleistocene, California) Fossils & Evolution—Chapter 1

  26. Lagerstätten(Hunsrück Shale, Devonian of Germany) Fossils & Evolution—Chapter 1

  27. Lagerstätten(Solnhofen Limestone, Germany) Fossils & Evolution—Chapter 1

  28. Lagerstätten(Burgess Shale, Cambrian of Alberta) Fossils & Evolution—Chapter 1

  29. Tully monster(Mazon Creek Shale,Pennsylvanian of Illinois) Check out U-Haul website http://www.uhaul.com/supergraphics/tully/the_graphic.html Fossils & Evolution—Chapter 1

  30. Sampling bias • Fossil record is best in most recent geologic systems • Younger rocks are less likely to be covered or obscured by other rocks • Younger rocks are less likely to have been eroded, metamorphosed or subducted Fossils & Evolution—Chapter 1

  31. Fossil species diversity vs sediment volume/exposure Fossils & Evolution—Chapter 1

  32. Consequences of preservation and sampling bias • Knowledge of past life is far better at higher taxonomic levels than at lower taxonomic levels • In a given sample, you’d only need to look at a small number of specimens to find all of the phyla present, but you’d have to look at a lot of specimens to find all of the species present! Fossils & Evolution—Chapter 1

  33. Sampling bias:Danish Miocene mollusks Phyla 1 Classes 3 Orders 12 Families 44 Genera 64 Species 86 Individual shells 2,954 Fossils & Evolution—Chapter 1

  34. Sampling bias:Danish Miocene mollusks • If sample size were larger, then more species and possibly more genera might have been found, but probably no more classes or phyla • If sample size were smaller, then fewer genera and species would have been found, but probably no fewer classes or phyla Fossils & Evolution—Chapter 1

  35. Rarefaction curve[How many taxa would have been found had the sample been smaller?] Fossils & Evolution—Chapter 1

  36. Conclusions • Every assemblage of fossils represents an extremely biased sample of the organisms once living in an area • Lack of fossils in a rock cannot be taken to mean that organisms were not living in the area • “Absence of evidence is not evidence of absence” Fossils & Evolution—Chapter 1

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