Fossil


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A fossil (from Classical Latin fossilis; literally, "obtained by digging")[1] is any preserved remains, impression, or trace of any once-living thing from a past geological age. Examples include bones, shells, exoskeletons, stone imprints of animals or microbes, objects preserved in amber, hair, petrified wood, oil, coal, and DNA remnants. The totality of fossils is known as the fossil record.

Paleontology is the study of fossils: their age, method of formation, and evolutionary significance. Specimens are usually considered to be fossils if they are over 10,000 years old.[2] The oldest fossils are around 3.48 billion years old[3][4][5] to 4.1 billion years old.[6][7] The observation in the 19th century that certain fossils were associated with certain rock strata led to the recognition of a geological timescale and the relative ages of different fossils. The development of radiometric dating techniques in the early 20th century allowed scientists to quantitatively measure the absolute ages of rocks and the fossils they host.

There are many processes that lead to fossilization, including permineralization, casts and molds, authigenic mineralization , replacement and recrystallization, adpression, carbonization, and bioimmuration.


Fossil of a Seymouria (extinct)

Fossils vary in size from one-micrometre (1 µm) bacteria[8] to dinosaurs and trees, many meters long and weighing many tons. A fossil normally preserves only a portion of the deceased organism, usually that portion that was partially mineralized during life, such as the bones and teeth of vertebrates, or the chitinous or calcareous exoskeletons of invertebrates. Fossils may also consist of the marks left behind by the organism while it was alive, such as animal tracks or feces (coprolites). These types of fossil are called trace fossils or ichnofossils, as opposed to body fossils. Some fossils are biochemical and are called chemofossils or biosignatures.



PROCESS  OF  FOSSILIZATION


The process of fossilization varies according to tissue type and external conditions.


Permineralization


Silicified (replaced with silica) fossils from the Road Canyon Formation (Middle Permian of Texas)

Permineralization is a process of fossilization that occurs when an organism is buried. The empty spaces within an organism (spaces filled with liquid or gas during life) become filled with mineral-rich groundwater. Minerals precipitate from the groundwater, occupying the empty spaces. This process can occur in very small spaces, such as within the cell wall of a plant cell. Small scale permineralization can produce very detailed fossils. For permineralization to occur, the organism must become covered by sediment soon after death, otherwise decay commences. The degree to which the remains are decayed when covered determines the later details of the fossil. Some fossils consist only of skeletal remains or teeth; other fossils contain traces of skin, feathers or even soft tissues. This is a form of diagenesis.


Casts and molds


External mold of a bivalve from the Logan Formation, Lower Carboniferous, Ohio

In some cases, the original remains of the organism completely dissolve or are otherwise destroyed. The remaining organism-shaped hole in the rock is called an external mold. If this hole is later filled with other minerals, it is a cast. An endocast, or internal mold, is formed when sediments or minerals fill the internal cavity of an organism, such as the inside of a bivalve or snail or the hollow of a skull.


Authigenic mineralization


This is a special form of cast and mold formation. If the chemistry is right, the organism (or fragment of organism) can act as a nucleus for the precipitation of minerals such as siderite, resulting in a nodule forming around it. If this happens rapidly before significant decay to the organic tissue, very fine three-dimensional morphological detail can be preserved. Nodules from the Carboniferous Mazon Creek fossil beds of Illinois, USA, are among the best documented examples of such mineralization.


Replacement and recrystallization


Recrystallized scleractinian coral (aragonite to calcite) from the Jurassic of southern Israel

Replacement occurs when the shell, bone or other tissue is replaced with another mineral. In some cases mineral replacement of the original shell occurs so gradually and at such fine scales that microstructural features are preserved despite the total loss of original material. A shell is said to be recrystallized when the original skeletal compounds are still present but in a different crystal form, as from aragonite to calcite.


Adpression (compression-impression)


Compression fossils, such as those of fossil ferns, are the result of chemical reduction of the complex organic molecules composing the organism's tissues. In this case the fossil consists of original material, albeit in a geochemically altered state. This chemical change is an expression of diagenesis. Often what remains is a carbonaceous film known as a phytoleim, in which case the fossil is known as a compression. Often, however, the phytoleim is lost and all that remains is an impression of the organism in the rock—an impression fossil. In many cases, however, compressions and impressions occur together. For instance, when the rock is broken open, the phytoleim will often be attached to one part (compression), whereas the counterpart will just be an impression. For this reason, one term covers the two modes of preservation: adpression.[9]


Soft tissue, cell and molecular preservation


Because of their antiquity, an unexpected exception to the alteration of an organism's tissues by chemical reduction of the complex organic molecules during fossilization has been the discovery of soft tissue in dinosaur fossils, including blood vessels, and the isolation of proteins and evidence for DNA fragments.[10][11][12][13] In 2014, Mary Schweitzer and her colleagues reported the presence of iron particles (goethite-aFeO(OH)) associated with soft tissues recovered from dinosaur fossils. Based on various experiments that studied the interaction of iron in haemoglobin with blood vessel tissue they proposed that solution hypoxia coupled with iron chelation enhances the stability and preservation of soft tissue and provides the basis for an explanation for the unforeseen preservation of fossil soft tissues.[14] However, a slightly older study based on eight taxa ranging in time from the Devonian to the Jurassic found that reasonably well-preserved fibrils that probably represent collagen were preserved in all these fossils, and that the quality of preservation depended mostly on the arrangement of the collagen fibers, with tight packing favoring good preservation.[15] There seemed to be no correlation between geological age and quality of preservation, within that timeframe.


Carbonization


Carbonaceous films are thin coatings which consist predominantly of the chemical element carbon. The soft tissues of organisms are made largely of organic carbon compounds and during diagenesis under reducing conditions only a thin film of carbon residue is left which forms a silhouette of the original organism.


Bioimmuration


Bioimmuration occurs when a skeletal organism overgrows or otherwise subsumes another organism, preserving the latter, or an impression of it, within the skeleton.[17] Usually it is a sessile skeletal organism, such as a bryozoan or an oyster, which grows along a substrate, covering other sessile sclerobionts. Sometimes the bioimmured organism is soft-bodied and is then preserved in negative relief as a kind of external mold. There are also cases where an organism settles on top of a living skeletal organism that grows upwards, preserving the settler in its skeleton. Bioimmuration is known in the fossil record from the Ordovician[18] to the Recent.


………………..


AS  YOU  CAN  SEE  THERE  IS  MUCH  TO  FOSSILIZATION.


THE  ARTICLE  FROM  WIKIPEDIA  GOES  ON  IN  SOME  DETAIL  ABOUT  “DATING”  METHODS.


IT  IS  NOT  MY  INTENT  HERE  TO  DEBATE  THE  DATING  METHODS.


I  WILL  PRESUME  BOTH  SIDES  OF  DATING  DINOSAUR  BONES  HAVE  TRUTH  TO  THEM.


THE  PROBLEM  THAT  “YOUNG  EARTH  CHRISTIAN  SCIENTISTS”  HAVE  IS  THAT  MOST  OF  THEM  STILL  WANT  TO  ARGUE  THE  EARTH  IS  ABOUT  6,OOO  YEARS  OLD.


BELIEVING  THAT  SOME  DINOSAUR  BONES  HAVE  BEEN  CORRECTLY  DATED  TO  AROUND  35,000  YEARS,  GIVEN  SOME  LESS  AND  SOME  MORE;  THIS  BLOWS  AWAY  THE  TEACHING  OF  AN  EARTH  6,000  OR  SO  YEARS  OLD.


THEN  GIVEN  THAT  MOST  DINOSAUR  BONES  HAVE  MOVED  INTO  FULL  FOSSILIZATION—— FULL  MINERAL  DEPOSITS  TO  MAKE  THEM  ROCK;  WE  CANNOT  CARBON  14  DATE  THEM,  AS  CARBON  14  METHOD  IS  PRETTY  WELL  USELESS  AFTER  50  TO  75  THOUSAND  YEARS.


SO  THOSE  DINOSAURS  COULD  BE….. WELL  CERTAINLY  AFTER  CARBON  14  METHOD  IS  USELESS,  COULD  BE…. WHO  KNOWS  HOW  OLD  THEY  COULD  BE,  AS  BY  THEMSELVES  AND  NOT  FIGURED  BY  ANY  SURROUNDINGS  THEY  ARE  FOUND  IN.


I  SUBMIT  BOTH  SIDES  OF  THE  COIN  ON  THIS  MATTER  COULD  BE  CORRECT.


SO  HOW  DO  BE  RECONCILE  BOTH  SIDES?


THAT  IS  FOR  THE  NEXT  UPLOAD.


Keith Hunt