Lagerstätten: extraordinary fossil localities

Konzentrat-Lagerstätten:

  • Concentration deposits—deposits are remarkable because the fossils are abundant
  • Examples include bone beds, coquinas, etc.
  • Usually collect over a long interval of time, represent time-averaging
  • Preservationally skewed towards durable organically produced materials

Konservat-Lagerstätten:

  • Conservation deposits—deposits are remarkable because of exceptional preservation, normally of “soft” organics that are typically destroyed during death, decay, decomposition, biostratinomic processes, and diagenesis.
  • Usually represent a catastrophic event that induces both death, and subsequently enhances preservation
  • Examples include articulated multipartic fossils, and fossilized soft tissues
  • Konservat-Lagerstätten give us a more transparent view through the taphonomic filter of pre-death paleobiology than any other type of deposit.
  • Often referred to as a “taphonomic window”
  • Typical environments enhancing “Konservat” formation include:
  • Microbial mats (e.g. Ediacaran biota)
  • Episodic sedimentation on submarine slopes and fans without significant deep bioturbation
  • Episodic sedimentation in highly bioproductive, fluctuating saline waters of lagoons and bays of the upper delta plain.
  • Shallow restricted marine basins in tropical, semiarid regions enhancing formation stratified water bodies and sediment/water interfacial microbial mats
  • Lacustrine deposits in stratified water, again with sediment/water interfacial microbial mats (usually Cenozoic due to preservational potential)
  • Plant Resinal interment—amber inclusions
  • Impregnation by hydrocarbons in seeps, bogs, etc.
  • Authigenic minerals form quickly in decay-prone tissues
  • Often induced by microbial decomposition, may preserve tissues as molds produced by petrifaction of encasing bacteria. Limits resolution of structure to size of bacteria sheathing the tissues
  • Concretionary preservation results from steep biogeochemical gradients around organisms through authigenic mineral formation
  • May be induced through anaerobic steep chemical gradients around organism
  • Minerals include apatite, clay minerals, pyrite, opalline silica, and calcite

Important Lagerstatten:

  • 3450-3470 Ma, Apex Chert of the Warawoona Group, Western Australia
  • Lakhanda Formation (mudstone), 1000Ma, (eu- and prokaryota)
  • Doushantuo Formation, China, 570 Ma nodular cherts with actritarchs and prokaryotes in lower carbonaceous shales, and overlying phosphorites with colonial algae and Ediacaran biota.
  • Chengjiang, China, Lower Cambrian, phosphatic and pyritized in mudstones
  • Soom Shale, South Africa, Upper Ordovician
  • Rhynie Chert, Scotland, Lower Devonian
  • Hunsrück Slate, western Germany, Lower Devonian
  • La Voulte-sur Rhône, France, Upper Middle Jurassic (e.g. pyritized squid)
  • Santana Formation, Lower Cretaceous, Brazil, concretionary phosphatic, fish
  • La Huérguina Limestone Formation of the Las Hoyas basin, Spain, Lower Cretaceous, lacustrine
  • PrincetonChert, British Columbia, Canada, Middle Eocene flora, lacustrine
  • Dominican Amber, 15-40 Ma, produced by Hymenaea protera, a Leguminosae, 490 genera and 372 families
  • Burgess Shale, Mt. Stephan, British Columbia, Canada, Middle Cambrian
  • Solnhofen Limestone, Bavaria, Jurassic
  • Francis Creek Shale (Mazon Creek), southern Illinois, Carboniferous
  • Messel Oil Shale, Eocene, near Frankfurt, Germany
  • Barstow Formation, Miocene, BarstowCalifornia, insects

© WB Leatham 2006