FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4211128516> ?p ?o ?g. }

• W4211128516 endingPage "537" @default.
• W4211128516 startingPage "475" @default.
• W4211128516 abstract "1. Acritarchs are a polyphyletic group of unicellular organisms, essentially marine and fossil, with a very resistant organic membrane; the majority probably represent the cysts of microscopic, extinct eukaryote algae. This review gives a general account for the non-specialist of their characteristics and affinities, but focuses, using selected examples, on their role as biostratigraphic tools for the specialist. 2. Invisible to the naked eye, up to several tens of thousands of acritarchs per gram of rock may be extracted and concentrated from a wide variety of sediments, especially argillaceous or even calcareous, but preferably fine-grained, unweathered and only slightly recrystallized or metamorphosed. 3. Always hollow and without unequivocal intracellular structures, acritarchs are extremely variable inoverall size, from a few to several hundred μm, with numerous divergent morphological modifications from a basic spherical form; the type and development of ornamentation; the number of cellular walls; and the method of opening, attributed to excystment. Acritarchs are classified according to criteria that are relatively simple compared with the modern demands of phycologists. For convenience they are treated under the International Code of Botanical Nomenclature, recognizing the existence of form genera of uncertain position. The lack of a comprehensive taxonomic framework is not surprising, given the number and variety of unclassifiable microorganisms resistant to HF that may be included in the acritarchs. 4. The sporopollenin-like wall of acritarchs, like the sporopollenin of modern plants, is chemically very inert except to oxidation, carbonization and bacterial or fungal activity. Of poorly-known composition but very probably including highly polymerized polyterpenes, it may form an abundant component of Palaeozoic kerogen, a potential source of hydrocarbons. The codification of colour changes and preservation in selected acritarchs may enable the optical evaluation of palaeotemperatures lower than about 120–150 °C and of the degree of maturity of possible oils. 5. The first known acritarchs sensu stricto, although discovered in 1862, were designated as such in 1963, after having been given a variety of names reflecting mainly assessments of their biological affinities. In spite of some attempts to abandon it, the name acritarch is still the most correct as it is the least ambiguous for designating the great majority of examples. 6. The reclassifying of acritarchs among microorganisms of known systematic position remains speculative or tentative. It is possible that many acritarchs represent cysts of extinct dinoflagellates, without archaeopyle or indication of a stable tabulation. Laboratory culture of Pterosperma has shown that Cymatiosphaera and Pterospermella have to be considered not as acritarchs but as phycoma of prasinophytes. The ultrastructure of the wall in Tasmanites is similar to that of Pachysphaera, another recent prasinophyte. Comparisons with euglenoids or spore-like bodies of the first terrestrial plants are indirect and that with eggs of recent crustaceans remains fortuitous. 7. The composition of live acritarch assemblages is most often heavily biased in taphocoenosis. In fact, because of their very small size and low density, these microfossils are frequently found reworked in strata younger than those in which they were originally deposited. If their distributions are sufficiently documented, they can be useful as provenance indicators in palaeogeographic reconstructions. 8. Acritarchs' mode of life is thought to be best compared with that of planktonic photosynthetic algae. General schemes seeking to explain variations in their abundance and distribution in deposits formed during the distant geological past are based especially on extrapolations from complex combinations of factors that govern the distribution of modern marine phytoplankton. 9. With a worldwide geographic distribution and a record only partly influenced by facies control, the acritarchs exhibit, geologically speaking, an extraordinarily long life span, from the Mesoproterozoic to the present day. In spite of the examples of reworking, rarely objectively verifiable, and the still relatively small number of detailed data with reliable independent age control, it is known that acritarchs, among a great number of ubiquitous forms, include time index taxa whose levels of appearance permit the calibration of very remote geological time and the establishment of regional or global correlations. These biostratigraphic indices, certainly present in the Neoproterozoic but still little known, are best demonstrated from around the beginning of the Cambrian to slightly before the end of the Upper Devonian, a time of maximum abundance and diversity for the group. At the beginning of the Early Cambrian in the East European Platform, and probably slightly above the international systemic boundary, drawn at the appearance of the ichnofossil Phycodes pedum in eastern Newfoundland, the acritarchs display a radiation of original diversity which occurs at three levels and contrasts with the worldwide impoverished sphaeromorph assemblages of the latest subjacent Neoproterozoic. The first level is marked especially by the appearance of Annulum squamaceum, the second by the diversification of Comasphaeridium, and the third, which is the clearest and most geographically widespread, by the appearance of Skiagia orbicularis, S. ornata and S. scottica, which coincides approximately with that of the trilobites. The Cambrian-Ordovician boundary is not yet agreed internationally but should be near the appearance of the Cordylodus lindstromi conodont Biozone, slightly below the first occurrence of nematophorous planktonic graptolites. Corollasphaeridium wilcoxianum is the index acritarch whose appearance is closest to, and slightly below, this boundary, in the upper part of the Cordylodus proavus Biozone. The species enters at this level in the north Sino-Korean Platform (Jilin province) and northern Laurentia (Alberta). It has not been recorded in Baltica, Avalonia and Gondwana, where the acritarch assemblages are better documented, more varied and different on the whole from those of northeastern China and western Canada. With reservations, it may be that in marine deposits associated with these three palaeocontinents, the lower limit of the range of Acanthodiacrodium angustum is located within the Cordylodus proavus Biozone. In the Late Devonian, the Frasnian—Famennian boundary is fixed internationally by means of conodonts, at the base of the Early Palmatolepis triangularis Biozone, which succeeds the Palmatolepis linguiformis Biozone. Regionally, in the Dinant Basin, Belgium, no index acritarch is known to appear at the base of the Lower Famennian. On the other hand, at Senzeilles the appearances of Visbysphaera?occulta and of Ephelopalla media occur successively at the end of the Frasnian in deposits undated by means of conodonts but attributable to the end of the late Palmatolepis zhenana Biozone and to the P. linguiformis Biozone. In the course of the upper Famennian, and from the end of the Late Devonian onwards, known assemblages are essentially sporadic, unvaried and of reduced or local stratigraphic value. The last species that is autochthonous, morphologically unmistakable and of worldwide distribution appears in the middle Neogene (Ypresian)." @default.
• W4211128516 created "2022-02-13" @default.
• W4211128516 creator A5072839031 @default.
• W4211128516 date "1993-11-01" @default.
• W4211128516 modified "2023-10-17" @default.
• W4211128516 title "ACRITARCHSA REVIEW" @default.
• W4211128516 cites W14521960 @default.
• W4211128516 cites W18077232 @default.
• W4211128516 cites W1965793309 @default.
• W4211128516 cites W1968875980 @default.
• W4211128516 cites W1972715118 @default.
• W4211128516 cites W1976128409 @default.
• W4211128516 cites W1981200260 @default.
• W4211128516 cites W1981240566 @default.
• W4211128516 cites W1983344657 @default.
• W4211128516 cites W1985285919 @default.
• W4211128516 cites W1985310787 @default.
• W4211128516 cites W1986425852 @default.
• W4211128516 cites W1988874351 @default.
• W4211128516 cites W1990830035 @default.
• W4211128516 cites W1994868202 @default.
• W4211128516 cites W1997252211 @default.
• W4211128516 cites W1997262853 @default.
• W4211128516 cites W1999221887 @default.
• W4211128516 cites W2000662387 @default.
• W4211128516 cites W2002865199 @default.
• W4211128516 cites W2006219584 @default.
• W4211128516 cites W2010729331 @default.
• W4211128516 cites W2014042058 @default.
• W4211128516 cites W2014138258 @default.
• W4211128516 cites W2017973591 @default.
• W4211128516 cites W2024442260 @default.
• W4211128516 cites W2024821723 @default.
• W4211128516 cites W2029252403 @default.
• W4211128516 cites W2029979255 @default.
• W4211128516 cites W2030581714 @default.
• W4211128516 cites W2030823545 @default.
• W4211128516 cites W2032473073 @default.
• W4211128516 cites W2033214688 @default.
• W4211128516 cites W2035008551 @default.
• W4211128516 cites W2038848276 @default.
• W4211128516 cites W2041487639 @default.
• W4211128516 cites W2043561742 @default.
• W4211128516 cites W2043721655 @default.
• W4211128516 cites W2044998296 @default.
• W4211128516 cites W2050504868 @default.
• W4211128516 cites W2056902227 @default.
• W4211128516 cites W2057191919 @default.
• W4211128516 cites W2057589450 @default.
• W4211128516 cites W2061537492 @default.
• W4211128516 cites W2061802047 @default.
• W4211128516 cites W2062227426 @default.
• W4211128516 cites W2063125599 @default.
• W4211128516 cites W2065487067 @default.
• W4211128516 cites W2067326465 @default.
• W4211128516 cites W2068844880 @default.
• W4211128516 cites W2074499636 @default.
• W4211128516 cites W2075463840 @default.
• W4211128516 cites W2076907994 @default.
• W4211128516 cites W2078978948 @default.
• W4211128516 cites W2083640591 @default.
• W4211128516 cites W2085366644 @default.
• W4211128516 cites W2094035219 @default.
• W4211128516 cites W2097540457 @default.
• W4211128516 cites W2099144811 @default.
• W4211128516 cites W2100361820 @default.
• W4211128516 cites W2108420161 @default.
• W4211128516 cites W2110509586 @default.
• W4211128516 cites W2110619496 @default.
• W4211128516 cites W2120085423 @default.
• W4211128516 cites W2123826511 @default.
• W4211128516 cites W2126883762 @default.
• W4211128516 cites W2128198623 @default.
• W4211128516 cites W2128500185 @default.
• W4211128516 cites W2129554927 @default.
• W4211128516 cites W2132249718 @default.
• W4211128516 cites W2139286067 @default.
• W4211128516 cites W2147455482 @default.
• W4211128516 cites W2152030224 @default.
• W4211128516 cites W2153058161 @default.
• W4211128516 cites W2161721158 @default.
• W4211128516 cites W2161913894 @default.
• W4211128516 cites W2163119100 @default.
• W4211128516 cites W2170411829 @default.
• W4211128516 cites W2171306646 @default.
• W4211128516 cites W2318508814 @default.
• W4211128516 cites W2322592704 @default.
• W4211128516 cites W2323216214 @default.
• W4211128516 cites W2324385965 @default.
• W4211128516 cites W2326221383 @default.
• W4211128516 cites W2329137631 @default.
• W4211128516 cites W2330241908 @default.
• W4211128516 cites W2344805785 @default.
• W4211128516 cites W2365753732 @default.
• W4211128516 cites W2394715991 @default.
• W4211128516 cites W2494841461 @default.
• W4211128516 cites W2502655013 @default.
• W4211128516 cites W2508814114 @default.

• next