Treatise Online, no. 38: Part E, Revised, Volume 4, Chapter 18: General features of the Archaeocyatha
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F. Debrenne | A. Yu Zhuravlev | P. D. Kruse | A. Zhuravlev | P. Kruse | F. Debrenne | A. Yu. Zhuravlev | P. D. Kruse | A. Yu. Zhuravlev | P. D. Kruse
[1] F. Debrenne. Lower Cambrian Archaeocyatha from the Ajax Mine, Beltana, South Australia , 1969 .
[2] C. F. Klappa,et al. Petrogenesis of Early Cambrian Reef Limestones, Labrador, Canada , 1983 .
[3] R. Bedford,et al. Further notes on archaeos (pleospongia) from the lower cambrian of South Australia , 1937 .
[4] G. J. Hinde. On Archæocyathus, Billings, and on other Genera, allied to or associated with it, from the Cambrian Strata of North America, Spain, Sardinia, and Scotland , 1889, Quarterly Journal of the Geological Society of London.
[5] A. Rozanov,et al. Upper Cambrian Archaeocyatha from Antarctica , 1984, Geological Magazine.
[6] D. Gravestock,et al. Archaeocyaths from Yorke Peninsula, South Australia and archaeocyathan Early Cambrian zonation , 1994 .
[7] L. Zonenshain,et al. Absolute reconstructions of the Paleozoic oceans , 1985 .
[8] C. Wilkinson,et al. Sponge distribution across Davies Reef, Great Barrier Reef, relative to location, depth, and water movement , 2004, Coral Reefs.
[9] R. Shapiro,et al. Reef Patterns and Environmental Influences in the Cambrian and Earliest Ordovician , 2002 .
[10] M. Savarese. Functional significance of regular archaeocyathan central cavity diameter: a biomechanical and paleoecological test , 1995, Paleobiology.
[11] E. Khain. The Palaeo-Asian ocean in the Neoproterozoic and early Palaeozoic: new geochronologic data and palaeotectonic reconstructions , 2003 .
[12] T. V. Pegel. EVOLUTION OF TRILOBITE BIOFACIES IN CAMBRIAN BASINS OF THE SIBERIAN PLATFORM , 2000 .
[13] H. Lowenstam,et al. Minerals formed by organisms. , 1981, Science.
[14] R. Bedford,et al. Development and classification of archaeos (pleospongia) , 1939 .
[15] E. Landing,et al. Oldest shelly fossils from the Taconic Allochthon and late Early Cambrian sea-levels in eastern Laurentia , 1996, Journal of Paleontology.
[16] P. Kruse,et al. Cambrian Antarctic archaeocyaths , 1989, Geological Society, London, Special Publications.
[17] E. Mayoral,et al. Lower–Middle Cambrian boundary in the Mediterranean subprovince , 2007 .
[18] S. Bengtson,et al. The integument of Cambrian chancelloriids , 2001 .
[19] A. Zhuravlev. Preliminary suggestions on the global Early Cambrian zonation , 1995 .
[20] B. Lieberman,et al. The Neoproterozoic assembly of Gondwana and its relationship to the Ediacaran–Cambrian radiation , 2008 .
[21] A. Gandin,et al. Lower Cambrian bioconstructions in Northwestern Mexico (Sonora). Depositional setting, paleoecology and systematics of Archaeocyaths , 1989 .
[22] C. Scotese,et al. Revised World maps and introduction , 1990, Geological Society, London, Memoirs.
[23] M. Hanna. Society of Economic Paleontologists and Mineralogists , 1927 .
[24] R. Bedford,et al. Further notes on Archaeocyathi (Cyathospongia) and other organisms from the lower Cambrian of Beltana, South Australia , 1936 .
[25] A. Zhuravlev,et al. New Irregular Archaeocyath taxa , 1990 .
[26] W. Hoppe. Reproductive patterns in three species of large coral reef sponges , 1988, Coral Reefs.
[27] R. Cowen. The role of algal symbiosis in reefs through time , 1988 .
[28] R. Robison,et al. The global boundary stratotype section and point (GSSP) of the drumian stage (Cambrian) in the drum mountains, Utah, USA , 2007 .
[29] S. Westrop. The Ecology of the Cambrian Radiation , 2001 .
[30] B. Lieberman. Early Cambrian paleogeography and tectonic history: A biogeographic approach , 1997 .
[31] M. H. Nitecki,et al. The nature of Radiocyathidsand their relationship to Receptaculitids and Archaeocyathids , 1979 .
[32] P. Layer,et al. New age constraints for a short pulse in Ross orogen deformation triggered by East–West Gondwana suturing , 2007 .
[33] J. Vacelet. Recent Calcarea with a Reinforced Skeleton (“Pharetronids”) , 1991 .
[34] A. Zhuravlev,et al. Faunal migrations of archaeocyaths and Early Cambrian plate dynamics , 1999 .
[35] T. Torsvik,et al. Siberia, the wandering northern terrane, and its changing geography through the Palaeozoic , 2007 .
[36] P. Ahlberg,et al. Uppermost Lower Cambrian biostratigraphy in Scania, Sweden , 1981 .
[37] W. Kiessling,et al. Patterns of Phanerozoic carbonate platform sedimentation , 2003 .
[38] Matthias Selg. Algen als Faziesindikatoren: Bioherme und Biostrome im Unter-Kambrium von SW-Sardinien , 1986 .
[39] F. Debrenne,et al. La formation de Gonnesa (Cambrien, SW Sardaigne); biostratigraphie, paleogeographie, paleoecologie des Archeocyathes , 1985 .
[40] R. Wood. Biology and revised systematics of some late Mesozoic stromatoporoids. , 1987 .
[41] P. Kruse,et al. Shackleton Limestone archaeocyaths , 1986 .
[42] U. Jux,et al. Early Cambrian Carbonate Platform of the Arabian Shield , 1984 .
[43] Y. Loya,et al. Ontogenetic Variation in Sponge Histocompatibility Responses. , 1990, The Biological bulletin.
[44] D. R. Kobluk,et al. Cavity-dwelling organisms in Lower Cambrian patch reefs from southern Labrador , 1979 .
[45] A. Zhuravlev,et al. Early Cambrian Appalachian archaeocyaths : Further age constraints from the fauna of New Jersey and Virginia, U.S.A. , 2000 .
[46] A. Zhuravlev,et al. The Cambrian System of the Foldbelts of Russia and Mongolia. Correlation Chart and Explanatory Notes , 1995 .
[47] F. Debrenne,et al. Cambrian food web: A brief review , 1997 .
[48] A. C. Haddon. The Genus Madrepora , 1894, Nature.
[49] M. Savarese. Functional analysis of archaeocyathan skeletal morphology and its paleobiological implications , 1992, Paleobiology.
[50] A. Zhuravlev. Evolution of archaeocyaths and palaeobiogeography of the Early Cambrian , 1986, Geological Magazine.
[51] J. J. Álvaro,et al. Palaeogeographical controls on the Cambrian trilobite immigration and evolutionary patterns reported in the western Gondwana margin , 2003 .
[52] R. Greggs. Archaeocyatha from the Colville and Salmo areas of Washington and British Columbia , 1957 .
[53] A. Zhuravlev,et al. The ecology of Lower Cambrian buildups from Zuune Arts, Mongolia: implications for early metazoan reef evolution , 1993 .
[54] J. Kirschvink. A Paleogeographic Model for Vendian and CambrianTime , 1992 .
[55] Joseph L. Kirschvink,et al. Evidence for a Large-Scale Reorganization of Early Cambrian Continental Masses by Inertial Interchange True Polar Wander , 1997 .
[56] S. Culver,et al. Early and Middle(?) Cambrian metazoan and protistan fossils from West Africa , 1996, Journal of Paleontology.
[57] C. Walcott. Descriptive notes of new genera and species from the Lower Cambrian or Olenellus zone of North America , 1890 .
[58] J. Dzik. Evolution of 'small shelly fossils' assemblages of the Early Paleozoic , 1994 .
[59] C. H. Holland. Cambrian of the British Isles, Norden, and Spitsbergen , 1974 .
[60] G. Geyer,et al. The quest for internationally recognized divisions of Cambrian time , 2000 .
[61] M. Gornova,et al. Dzhida island-arc system in the Paleoasian Ocean: structure and main stages of Vendian-Paleozoic geodynamic evolution , 2007 .
[62] F. Debrenne,et al. Calcaires à Archéocyathes du Cambrien inférieur du Nord de la Colombie britannique (Canada). Implications paléogéographiques et précisions sur l'extension du continent Américano-Koryakien , 1993 .
[63] C. H. Holland. Cambrian of the new world , 1971 .
[64] J. Kennard. Lower Cambrian archaeocyathan buildups, Todd River Dolomite, northeast Amadeus Basin, central Australia: Sedimentology and diagenesis , 1991 .
[65] E. Landing. Cambrian subdivisions and correlations: Introduction , 1998 .
[66] R. Bell. Geological Survey of Canada , 1885, Nature.
[67] E. Billings. New Species of Lower Silurian Fossils , 1862 .
[68] Matthew H. Nitecki,et al. Receptaculitids: A Phylogenetic Debate on a Problematic Fossil Taxon , 1999 .
[69] P. Kruse. Cyanobacterial–archaeocyathan–radiocyathan bioherms in the Wirrealpa Limestone of South Australia , 1991 .
[70] E. Landing,et al. First evidence for Cambrian glaciation provided by sections in Avalonian New Brunswick and Ireland: Additional data for Avalon-Gondwana separation by the earliest Palaeozoic , 2010 .
[71] J. Reitner,et al. Skeletal structures and habitats of Recent and fossil Acanthochaetetes (subclass Tetractinomorpha, Demospongiae, Porifera) , 1987, Coral reefs.
[72] E. Flügel,et al. Stromatoporoid-grade and other sponge fossils from the upper Krol Formation of the Lesser Himalaya (India) Implications for the biotic evolution around the Precambrian-Cambrian boundary interval , 2003 .
[73] N. Vavilov,et al. The law of homologous series in variation , 1922, Journal of Genetics.
[74] H. Reiswig. In situ pumping activities of tropical Demospongiae , 1971 .
[75] E. Meyrick. Descriptions of Australian Micro-Lepidoptera , 2011 .
[76] P. Courjault-Radé,et al. Palaeogeographic and geodynamic evolution of the Gondwana continental margins during the Cambrian , 1992 .
[77] B. Pratt,et al. Early Cambrian reefs, reef complexes, and associated lithofacies of the Shackleton Limestone, Transantarctic Mountains , 1989 .
[78] R. C. Handfield. Archaeocyatha from the Mackenzie and Cassiar Mountains, Northwest Territories, Yukon Territory and British Columbia , 1971 .
[79] R. Wood. Non-Spicular Biomineralization in Calcified Demosponges , 1991 .
[80] G. Vidal,et al. Constraints on the early Cambrian radiation and correlation of the Tommotian and Nemakit-Daldynian regional stages of eastern Siberia , 1995, Journal of the Geological Society.
[81] C. Walcott. Second contribution to the studies on the Cambrian faunas of North America , 2011 .
[82] M. Glaessner. Pseudofossils from the Precambrian, including ‘Buschmannia’ and ‘Praesolenopora’ , 1980, Geological Magazine.
[83] A. L. Ayling. PATTERNS OF SEXUALITY, ASEXUAL REPRODUCTION AND RECRUITMENT IN SOME SUBTIDAL MARINE DEMOSPONGIAE , 1980 .
[84] M. Mišík,et al. Oxford University Press , 1968, PMLA/Publications of the Modern Language Association of America.
[85] A. Rozanov. Homological variability of archaeocyathans , 1974, Geological Magazine.
[86] A. Didenko,et al. The Vendian-Early Paleozoic history of the continental margin of eastern Paleogondwana, Paleoasian Ocean, and Central Asian Foldbelt , 2003 .
[87] L. Babcock,et al. Continuing progress on chronostratigraphic subdivision of the Cambrian System , 2011 .
[88] D. R. Kobluk,et al. Lower Cambrian patch reefs and associated sediments: southern Labrador, Canada , 1978 .
[89] Zhang Sen-gui,et al. Lower Cambrian archaeocyathid assemblages of central and southwestern China , 1981 .
[90] A. Gandin,et al. Early Cambrian bioconstructions in the Zavkhan Basin of western Mongolia , 1996, Geological Magazine.
[91] B. senowbaRi-daRyan,et al. Upper permian segmented sponges from Djebel Tebaga, Tunisia , 1988 .
[92] J. Rigby,et al. Sponges from the Early Devonian Garra Formation, New South Wales , 1983 .
[93] Y. Lasemi,et al. Archaeocyathan buildups within an entirely siliciclastic succession: New discovery in the Toyonian Lalun Formation of northern Iran, the Proto-Paleotethys passive margin of northern Gondwana , 2007 .
[94] S. Rowland,et al. Structure and paleoecology of Lower Cambrian reefs , 1988 .
[95] J. Golonka. Plate-Tectonic Maps of the Phanerozoic , 2002 .
[96] S. Rowland. Were there framework reefs in the Cambrian , 1984 .
[97] G. Shi,et al. Palaeobiogeographic affinities of Australian Cambrian faunas , 2000 .
[98] S. W. Ford. Descriptions of two new species of Primordial fossils , 1872, American Journal of Science.
[99] E. Landing. No Late Cambrian shoreline ice in Laurentia:COMMENT , 2011 .
[100] S. Morris. The origins and relationships of lower invertebrates , 1983 .
[101] F. Debrenne,et al. Archaeocyathan fauna from the Lower Cambrian of Yunnan (China) , 1989 .
[102] A. Gandin,et al. Lower Cambrian bioconstructions in Southwestern Sardinia (Italy) , 1984 .
[103] A. Gandin,et al. Distribution of the archaeocyath-calcimicrobial bioconstructions on the Early Cambrian shelves , 2010 .
[104] Philippa Barry. The animal kingdom , 2002 .
[105] Peter A. Cawood,et al. Terra Australis Orogen: Rodinia breakup and development of the Pacific and Iapetus margins of Gondwana during the Neoproterozoic and Paleozoic , 2005 .
[106] Amos Salvador,et al. International Stratigraphic Guide: A Guide to Stratigraphic Classification, Terminology, and Procedure , 1996 .
[107] L. B. McCollum,et al. Cambrian stratigraphy of the Wendover area, Utah and Nevada , 1991 .
[108] J. Laurie,et al. The Cambrian system in Australia, Antarctica, and New Zealand , 1985 .
[109] R. Riding. Girvanella and other algae as depth indicators , 1975 .
[110] S. Rowland. ARCHAEOCYATHS—A HISTORY OF PHYLOGENETIC INTERPRETATION , 2001, Journal of Paleontology.
[111] P. Richter,et al. Buschmannia roeringi n. gen., n. sp. (Archaeocyatha) aus der Nama-Gruppe Südwestafrikas , 1976 .
[112] M. Santosh,et al. The Grenvillian and Pan-African orogens: World's largest orogenies through geologic time, and their implications on the origin of superplume , 2008 .
[113] M. Brasier,et al. Continental break-up and collision in the Neoproterozoic and Palaeozoic — A tale of Baltica and Laurentia , 1996 .
[114] A. Perejón,et al. Biostratigraphy and paleobiogeography of the archaeocyaths on the southwestern margin of Gondwana , 2006 .
[115] D. Phillips,et al. The Kalkarindji continental flood basalt province: A new Cambrian large igneous province in Australia with possible links to faunal extinctions , 2006 .
[116] L. Rietschel. Receptaculitids are Calcareous Algae but no Dasyclads , 1977 .
[117] J. Rigby,et al. Sphinctozoan sponges from the Permian reefs of South China , 1989, Journal of Paleontology.
[118] J. Rigby,et al. Ordovician Sphinctozoan Sponges from the Eastern Klamath Mountains, Northern California , 1986, Journal of Paleontology.
[119] A. Zhuravlev,et al. A new post-early Cambrian archaeocyath from Antarctica , 1992, Geological Magazine.
[120] R. Soest. Deficient Merlia normani Kirkpatrick, 1908, from the Curaçao reefs, with a discussion on the phylogenetic interpretation of sclerosponges , 1984 .
[121] Baba Senowbari-Daryan,et al. Sphinctozoen (Kalkschwämme) aus den norischen Riffen von Sizilien , 1986 .
[122] F. Debrenne. A REVISION OF AUSTRALIAN GENERA OF ARCHAECYATHA , 1970 .
[123] J. Reitner,et al. EARLY PALEOZOIC DIVERSIFICATION OF SPONGES : NEW DATA AND EVIDENCES , 2008 .
[124] A. Perejón. Bioestratigrafía de los arqueociatos en España , 1984 .
[125] P. Stone,et al. Archaeocyathan limestone blocks of likely Antarctic origin in Gondwanan tillite from the Falkland Islands , 2005, Geological Society, London, Special Publications.
[126] A. J. Rowell,et al. Early Cambrian Trilobites from the Shackleton Limestone of the Central Transantarctic Mountains , 1995, Journal of Paleontology.
[127] F. Debrenne. Anatomie et systématique des Archéocyathes réguliers sans plancher d'Ajax mine , 1974 .
[128] B. Storey. The changing face of late Precambrian and early Palaeozoic reconstructions , 1993, Journal of the Geological Society.
[129] V. J. Okulitch. Some changes in nomenclature of Archaeocyathi (Cyathospongia) , 1937 .
[130] H. Strauss,et al. A major sulphur isotope event at c. 510 Ma: a possible anoxia–extinction–volcanism connection during the Early–Middle Cambrian transition? , 2006 .
[131] A. Zhuravlev,et al. The Lower Cambrian Fossil Record of the Soviet Union , 1992 .
[132] C. W. Merriam. Middle Devonian rugose corals of the central Great Basin , 1973 .
[133] N. James,et al. Reef-associated archaeocyathans from the Lower Cambrian of Labrador and Newfoundland , 1981 .
[134] F. Debrenne,et al. Archaeocyatha from the Krol-Tal succession (Lesser Himalaya): an invalid record , 1990, Geological Magazine.
[135] M. Brasier,et al. Early Cambrian continental reconstructions , 1992, Journal of the Geological Society.
[136] D. Hill. THE PHYLUM ARCHAEOCYATHA , 1964 .
[137] R. Riding,et al. 2. Paleomagnetically and Tectonically Based Global Maps for Vendian to Mid-Ordovician Time , 2000 .
[138] A. R. Palmer,et al. Through a glass darkly: taxonomy, phylogeny, and biostratigraphy of the Olenellina , 1993 .
[139] Annals and Magazine of Natural History , 1952, Nature.
[140] S. Vogel,et al. Water movement in archaeocyathids; evidence and implications of passive flow in models , 1973 .
[141] A. Zhuravlev,et al. Functional biology and ecology of Archaeocyatha , 1992 .
[142] A. Zhuravlev. A functional morphological approach to the biology of the Archaeocyatha , 1993 .
[143] N. Morgan. The Montenegro Bioherms: Their Paleoecology, Relation to Other Archeocyathid Bioherms and to Early Cambrian Sedimentation in the White and Inyo Mountains, California , 1976 .
[144] R. Wood,et al. Eve of biomineralization: Controls on skeletal mineralogy , 2008 .
[145] A. Zhuravlev,et al. PRIMORDIAL METAZOAN-CALCIMICROBIAL REEFS : TOMMOTIAN (EARLY CAMBRIAN) OF THE SIBERIAN PLATFORM , 1995 .
[146] J. Reitner,et al. The Upper Cretaceous "chaetetid" demosponge Stromatoaxinella irregularis n. g. (Michelin) and its systematic implications , 1988 .
[147] P. Coney,et al. Cordilleran suspect terranes , 1980, Nature.
[148] W. Gordon. XXVII.—Scottish National Antarctic Expedition, 1902–1904: Cambrian Organic Remains from a Dredging in the Weddell Sea , 1921, Transactions of the Royal Society of Edinburgh.
[149] S. Rowland,et al. Early Cambrian microbial reefs, archaeocyathan inter-reef communities, and associated facies of the Yangtze Platform , 2009 .
[150] S. Damborenea,et al. Early Cambrian archaeocyathan limestone blocks in low-grade meta-conglomerate from El Jagüelito Formation (Sierra Grande, Río Negro, Argentina) , 2011 .
[151] E. Billings. On some new or little-known species of Lower Silurian fossils from the Potsdam Group (Primordial Zone) , 1865 .
[152] F. Debrenne. Morphogenèse et systématique des Archaeocyatha (Spongiaires, Cambrien inférieur) , 1991 .
[153] M. Walter. Adelaidean and Early Cambrian stratigraphy of the southwestern Georgina Basin: correlation chart and explanatory notes , 1980 .
[154] A. Rozanov,et al. The stage scale of the Cambrian System , 1986, Geological Magazine.
[155] A. Gandin,et al. Paleoecological and sedimentological remarks on some Lower Cambrian sediments of the Yangtse Platform (China) , 1991 .
[156] M. H. Nitecki,et al. An unusually well preserved heteractinid sponge from the Pennsylvanian of Illinois and a possible classification and evolutionary scheme for the Heteractinida , 1975 .
[157] E. Moores. Southwest U.S.-East Antarctic (SWEAT) connection: A hypothesis , 1991 .
[158] F. Debrenne,et al. Buschmannia roeringi (Kaever & Richter, 1976) a so-called archaeocyatha, and the problem of the Precambrian or Cambrian age of the Nama System (S.W. Africa) , 1979, Geological Magazine.
[159] A. Zhuravlev,et al. Alpha, beta, or gamma: Numerical view on the Early Cambrian world , 2005 .
[160] A. Zhuravlev,et al. Anoxia as the cause of the mid-Early Cambrian (Botomian) extinction event , 1996 .
[161] V. J. Okulitch,et al. The systematic position of Archaeocyatha (pleosponges) , 1953 .
[162] G. A. Cooper. Cambrian stratigraphy and paleontology near Caborca, northwestern Sonora, Mexico , 1952 .
[163] D. Mehl. Organization and microstructure of the chancelloriid skeleton : implications for the biomineralization of the Chancelloriidae , 1996 .
[164] R. Wood,et al. A new Cambrian sphinctozoan sponge from North America, its relationship to archaeocyaths and the nature of early sphinctozoans , 1990, Geological Magazine.
[165] J. Reitner. Phylogenetic Aspects and New Descriptions of Spicule-Bearing Hadromerid Sponges with a Secondary Calcareous Skeleton (Tetractinomorpha, Demospongiae) , 1991 .
[166] R. Riding,et al. Ecology and evolution of Cambrian reefs , 2001 .
[167] M. Brasier,et al. Multiple δ13C excursions spanning the Cambrian explosion to the Botomian crisis in Siberia , 1994 .
[168] M. Hart. Biotic Recovery from Mass Extinction Events , 1996 .
[169] V. J. Okulitch. North American Pleospongia , 1943 .
[170] J. Vacelet. Les eponges calcifiees et les recifs anciens , 1983 .
[171] G. Geyer,et al. The Subcommission on Cambrian Stratigraphy: the status quo , 2003 .
[172] R. Burne,et al. Microbialites; organosedimentary deposits of benthic microbial communities , 1987 .
[173] J. Mount,et al. Faunas and Facies-Fact and Artifact Paleoenvironmental Controls on the Distribution of Early Cambrian Faunas , 1992 .
[174] P. Copper. Evolution, Radiations, and Extinctions in Proterozoic to Mid-Paleozoic Reefs , 2001 .
[175] R. Wood. NUTRIENTS, PREDATION AND THE HISTORY OF REEF-BUILDING , 1993 .
[176] A. Zhuravlev,et al. Lower Cambrian reefal cryptic communities , 1995 .
[177] P. Kruse. New Archaeocyatha from the Early Cambrian of the Mt. Wright area, New South Wales , 1978 .
[178] George E. Boyajian,et al. Biomechanical analysis of passive flow of stromatoporoids — morphologic, paleoecologic, and systematic implications , 1987 .
[179] N. James,et al. Lower Cambrian shelf and shelf margin buildups, Flinders Ranges, South Australia1 , 1990 .
[180] A. Hoffman,et al. Problematic fossil taxa , 1986 .
[181] G. Narbonne,et al. Trace fossils, small shelly fossils and the Precambrian-Cambrian boundary , 1988 .
[182] Dmitriy V. Kotel'nikov,et al. Archaeocyathids from the Atdabanian (Lower Cambrian) of the Altay-Sayan Foldbelt, Russia , 1998 .
[183] F. Debrenne. Archaeocyatha from Mexico in the Smithsonian Institution.New data from recent collectings , 1987 .
[184] S. Beadle. Dasyclads, cyclocrinitids and receptaculitids: comparative morphology and paleoecology , 1988 .
[185] G. Stanley. The history and sedimentology of ancient reef systems , 2001 .
[186] A. Gandin,et al. Anatomy of the Early Cambrian ‘La Sentinella’ reef complex, Serra Scoris, SW Sardinia, Italy , 2007, Geological Society, London, Special Publications.