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The late Pliensbachian (Early Jurassic) ammonoid Amaltheus in Japan: systematics and biostratigraphic and paleobiogeographic significance

Published online by Cambridge University Press:  26 May 2021

Kentaro Nakada
Affiliation:
Fukui Prefectural Dinosaur Museum, 51–11 Terao, Muroko, Katsuyama, Fukui 911–8601, Japan ,
Michiharu Goto
Affiliation:
Fukui Prefectural Dinosaur Museum, 51–11 Terao, Muroko, Katsuyama, Fukui 911–8601, Japan ,
Christian Meister
Affiliation:
Department of Geology and Paleontology, Natural History Museum of the City of Geneva, 1 route de Malagnou, c.p. 6434, CH–1211, Geneva 6, Switzerland
Atsushi Matsuoka
Affiliation:
Department of Geology, Faculty of Science, Niigata University, Niigata 950–2181, Japan

Abstract

The genus Amaltheus, one of the representative late Pliensbachian ammonoids, has biostratigraphic and paleobiogeographic significance in Japan. Four species, Amaltheus stokesi (Sowerby, 1818), A. margaritatus de Montfort, 1808, A. repressus Dagis, 1976, and A. orientalis new species, have been found in the Kuruma Group in central Japan; A. stokesi and A. margaritatus are also from the Toyora Group in southwest Japan. On the basis of taxonomic analysis of the genus Amaltheus, we distinguish two successive ammonoid biozones in the lower part of the Teradani Formation of the Kuruma Group: the Amaltheus stokesiAmaltheus repressus and the Amaltheus margaritatus assemblage zones, in stratigraphic ascending order. This study also establishes the presence of the Amaltheus stokesi Assemblage Zone in the Higashinagano Formation of the Toyora Group. The stokesirepressus and the stokesi assemblage zones correspond biostratigraphically to the Amaltheus stokesi Standard Subzone of the margaritatus Zone. The margaritatus Assemblage Zone is correlated with the Amaltheus subnodosus and Amaltheus gibbosus standard subzones. The Japanese early–middle late Pliensbachian ammonoid faunas are composed almost entirely of pan-Boreal and Arctic species of the genus Amaltheus. This faunal composition has an affinity with that of the Northeast Russian region, and thus suggests a strong paleobiogeographic relationship between East Asian and Northeast Russian faunas throughout this time interval.

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Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of The Paleontological Society

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References

Bardin, J., Rouget, I., and Cecca, F., 2013, Late Pliensbachian (Early Jurassic) ammonites from Lac de Charmes (Haute-Marne, France): systematic, biostratigraphy and palaeobiogeography: Geodiversitas, v. 35, p. 309334.CrossRefGoogle Scholar
Bardin, J., Rouget, I., and Cecca, F., 2017, Ontogenetic data analyzed as such in phylogenies: Systematic Biology, v. 66, p. 2337.Google ScholarPubMed
Buckman, J., 1845, Outline of the Geology of the Neighbourhood of Cheltenham: London, John Murrey, 109 p.Google Scholar
Callomon, J.H., and Gradinaru, E., 2005, From the thesaurus of the museum collections I, Liassic ammonites from Munteana (Svinita Zone, Southern Carpathians, Romania): Acta Palaeontologica Romaniae, v. 5, p. 4965.Google Scholar
Cuvier, G., 1798, Tableau élémentaire de l'histoire naturelle des animaux: Paris, Baudouin, 710 p.Google Scholar
Dagis, A.A., 1976, Late Pliensbachian Ammonites (Amaltheidae) of the North Siberia: Academy of Sciences of the USSR, Siberian Branch, Transactions of the Institute of Geology and Geophysics, issue 309, 77 p. [in Russian]Google Scholar
Damborenea, S.E., 2002, Jurassic evolution of Southern Hemisphere marine palaeobiogeographic units based on benthonic bivalves: Geobios, v. 35, suppl. 1, p. 5171.CrossRefGoogle Scholar
Dean, W.T., Donovan, D.T., and Howarth, M.K., 1961, The Liassic ammonite zones and subzones of the North-West European Province: Bulletin of the British Museum (Natural History), Geology, v. 4, p. 435505.10.5962/p.313862CrossRefGoogle Scholar
de Montfort, D., 1808, Conchyliologie systématique et classification méthodique des coquilles: Paris, F. Schoell, 410 p.CrossRefGoogle Scholar
Dera, G., Pellenard, P., Neige, P., Deconinck, J.-F., Pucéat, E., and Dommergues, J.-L., 2009, Distribution of clay minerals in Early Jurassic Peritethyan seas: palaeoclimatic significance inferred from multiproxy comparisons: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 271, p. 3951.CrossRefGoogle Scholar
Dommergues, J.-L., 1987, L’évolution chez les Ammonitina du Lias moyen (Carixien, Domérien basal) en Europe occidentale: Documents des Laboratoires de Géologie de Lyon, v. 98, 297 p.Google Scholar
Dommergues, J.-L., 2002, Les premiers Lytoceratatoidea du Nord-Ouest de l'Europe (Ammonoidea, Sinémurien inférieur, France). Exemple de convergence évolutive vers les morphologies “capricornes”: Revue de Paléobiologie, v. 21, p. 257277.Google Scholar
Dommergues, J.-L., and Meister, C., 1999, Cladistic formalisation of relationships within a superfamily of Lower Jurassic Ammonitina: Eoderocerataceae: Revue de Paléobiologie, v. 18, p. 273286.Google Scholar
Dommergues, J.-L., and Meister, C., 2017, Ammonites du Jurassique inférieur (Hettangien, Sinémurien, Pliensbachien) d'Afrique du Nord (Algérie, Maroc et Tunisie), Atlas d'identification des espèces: Revue de Paléobiologie, v. 36, p. 189367.Google Scholar
Dommergues, J.-L., Meister, C., and Mouterde, R., 1997, Pliensbachian, in Cariou, E., and Hantzpergue, P., eds., Biostratigraphie du Jurassique oust-européen et méditerranéen: zonations parallèles et distribution des invertébrés et microfossiles: Groupe français du Jurassique, Bulletin des Centres de Recherches Elf Exploration–Production Elf-Aquitain, Mémoire 17, p. 1523, 114–119.Google Scholar
Dommergues, J.-L., Dugué, O., Gauthier, H., Meister, C., Neige, P., Raynaud, D., Savary, X., and Trevisan, M., 2008, Les ammonites du Pliensbachien et du Toarciuen basal dans la carrière de la Roche Blain (Fresnay-le-Puceux, Calvados, Basse-Normandie, France). Taxonomie, implications stratigraphiques et paléogéographiques: Revue de Paléobiologie, v. 27, p. 265329.Google Scholar
Elmi, S., Atrops, F., and Mangold, C., 1974, Les zones d'ammonites du Domérien–Callovien de l'Algeria occidentals 1: Domérien–Toarcien: Lyon, Documents des Laboratoires de Géologie de la Faculté des Science, v. 61, 84 p.Google Scholar
Fauré, P., 2002, Le Lias des Pyrénées: Strata, Série 2, v. 39, 761 p.Google Scholar
Fauré, P., 2006, Le Domérien (Pliensbachien supérieur) des Corbières (Aude, France) Biostratigraphie, évolution sédimentaire, paléogéographie: Bulletin de la Société d'Etudes scientifiques de l'Aude, v. 103, p. 2944.Google Scholar
Fauré, P., and Teodori, D, 2019, Les ammonites du Pliensbachien des Pyrénées ariégeoises (Zone nord-pyrénéenne, France): étude taxonomique et stratigraphique, implications paléogéographique: Revue de Paléobiologie, v. 38, p. 269361.Google Scholar
Frebold, H., 1964, Lower Jurassic and Bajocian Ammonoid faunas of Northwestern British Columbia and Southern Yukon: Geological Survey of Canada Bulletin, v. 116, 31 p.Google Scholar
Frebold, H., 1975, The Jurassic faunas of the Canadian Arctic—Lower Jurassic ammonites, biostratigraphy and correlations: Geological Survey of Canada Bulletin, v. 243, 24 p.Google Scholar
Frebold, H., Mountjoy, E.W., and Tempelman-Kluit, D.J., 1967, New occurrences of Jurassic rocks and fossils in Central and Northern Yukon Territory: Geological Survey of Canada Paper, no. 67-12, 35 p.CrossRefGoogle Scholar
Géczy, B., and Meister, C., 1998, Les ammonites du Domérien de la montagne du Bakony (Hongrie): Revue de Paléobiologie, v. 17, no. 1, p. 69161.Google Scholar
Giebel, C.G., 1852, Fauna der Vorwelt, Band 3, Die Cephalopoden: Leipzig, F.A. Brockhaus, 856 p.Google Scholar
Golonka, J., 2007, Late Triassic and Early Jurassic palaeogeography of the world: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 244, p. 297307.CrossRefGoogle Scholar
Goto, M., 1983, Some bivalves from the Lower Jurassic Kuruma Group of Central Japan: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, no. 130, p. 7984.Google Scholar
Goto, M., 1994, Discovery of Seirocrinus (an Early Jurassic crinoid) from the Kuruma Group, Toyama Prefecture, Central Japan: Bulletin of the Toyama Science Museum, no. 17, p. 9194.Google Scholar
Haas, O., 1913, Die Fauna des mittleren Lias von Ballino in Südtirol, pt. 2: Beiträge zur Paläontologie und Geologie Österreichs-Ungarn, v. 26, p. 1161.Google Scholar
Hayami, I., and Akahane, H., 1981, A new species of Plagiostoma from the Kuruma Group and Domerian transgression in the Inner Zone of southwest Japan: Bulletin of the Toyama Science Museum, no. 3, p. 16.Google Scholar
Hirano, H., 1971, Biostratigraphic study of the Jurassic Toyora Group, part 1: Memoirs of Faculty of Science, Kyushu University, Series D, v. 21, p. 93128.CrossRefGoogle Scholar
Hirano, H., 1973a, Biostratigraphic study of the Jurassic Toyora Group, part 2: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, no. 89, p. 114.Google Scholar
Hirano, H., 1973b, Biostratigraphic study of the Jurassic Toyora Group, part 3: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, no. 90, p. 4571.Google Scholar
Hirano, H., Mikami, T., and Miyagawa, H., 1978, Lower Jurassic ammonites from the Higuchi Group, southwest Japan: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, no. 112, p. 410416.Google Scholar
Housa, V., 1965, Sexual dimorphism and the system of Jurassic and Cretaceous Ammonoidea: Časopis Národniho Muzea, v. 134, no. 7, p. 3335.Google Scholar
Howarth, M.K., 1958, A Monograph of the Ammonites of the Liassic Family Amaltheidae in Britain: London, Palaeontographical Society, 53 p.Google Scholar
Hyatt, A., 1867, The fossil cephalopods of the Museum of Comparative Zoology: Bulletin of the Museum of Comparative Zoology, v. 3, p. 71102.Google Scholar
Iba, Y., Sano, S., and Goto, M., 2015, Large belemnites were already common in the Early Jurassic—new evidence from Central Japan: Paleontological Research, v. 19, p. 2125.CrossRefGoogle Scholar
Imlay, R.W., 1955, Characteristic Jurassic mollusks from northern Alaska: United States Geological Survey Professional Paper, 274-D, p. 6996.Google Scholar
Jakobs, G.K., and Pálfy, J., 1994, Upper Triassic to Middle Jurassic biostratigraphic and facies studies in the Iskut River map area, northwestern British Columbia: Current Research, Geological Survey of Canada, Ottawa, no. 1994-E, p. 1728.CrossRefGoogle Scholar
Johannson, G.G., Smith, P.L., and Gordey, S.P., 1997, Early Jurassic evolution of the northern Stikinian arc: evidence from Laberge Group, northwestern British Columbia: Canadian Journal of Earth Sciences, v. 34, p. 10301057.CrossRefGoogle Scholar
Kimura, T., and Tsujii, M., 1980–1984, Early Jurassic plants in Japan, part 1–6: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, Part 1, no. 119, p. 339358 (1980); Part 2, no. 120, p. 449–465 (1980); Part 3, no. 124, p. 187–207 (1981); Part 4, no. 125, p. 259–276 (1982); Part 5, no. 129, p. 35–57 (1983); Part 6, no. 133, p. 265–287 (1984).Google Scholar
Kimura, T., Ohana, T., and Tsujii, M., 1988, Early Jurassic plants in Japan, part 8, supplementary description and concluding remarks: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, no. 151, p. 501522.Google Scholar
Kobayashi, T., Konishi, K., Sato, T., Hayami, I., and Tokuyama, A., 1957, On the Lower Jurassic Kuruma Group: Journal of the Geological Society of Japan, v. 63, p. 182194. [in Japanese]CrossRefGoogle Scholar
Krymholts, G.Y., Mesezhnikov, M.S., and Westermann, G.E.G., 1988, The Jurassic ammonite zones of the Soviet Union: Geological Society of America Special Papers, v. 223, 116 p.CrossRefGoogle Scholar
Kumazaki, N., and Kojima, S., 1996, Depositional history and structural development of the Kuruma Group (Lower Jurassic) on the basis of clastic rock composition: Journal of the Geological Society of Japan, v. 102, p. 285302. [in Japanese]CrossRefGoogle Scholar
Matsumoto, T., and Ono, A., 1947, A biostratigraphic study of the Jurassic Toyora Group, with special reference to ammonites: Science Reports of the Faculty of Science, Kyushu University, Geology, v. 2, p. 2031. [in Japanese]Google Scholar
Meister, C., 1988, Ontogenèse et évolution des Amaltheidae (Ammonoidea): Eclogae Geologicae Helvetiae, v. 81, p. 763841.Google Scholar
Meister, C., and Friebe, J.G., 2003, Austroalpine Liassic ammonites from Vorarlberg (Austria, Northern Calcareous Alps): Beiträge zur Paläontologie, v. 28, p. 999.Google Scholar
Mouterde, R., Dommergues, J.-L., Meister, C., and Rocha, R.B., 2007, Atlas des fossiles caractéristiques du Lias portugais, IIIa) Domérien (Ammonites): Ciências da Terra, v. 16, p. 67111.Google Scholar
Nakada, K., 2008, The first Occurrence of Petraoceras, Harpoceratinae, Ammonoidea from the Lower Jurassic Toyora Group in Yamaguchi Prefecture, Southwest Japan: Bulletin of the Firefly Museum of Toyota Town, v. 1, p. 8591. [in Japanese with English abstract]Google Scholar
Nakada, K., and Matsuoka, A., 2009, On the Pliensbachian/Toarcian boundary in the Lower Jurassic Toyora Group in southwest Japan: Volumina Jurassica, v. 7, p. 4754.Google Scholar
Nakada, K., and Matsuoka, A., 2011, International correlation of the Pliensbachian/Toarcian (Lower Jurassic) ammonoid biostratigraphy of the Nishinakayama Formation in the Toyora Group, southwest Japan: Newsletters on Stratigraphy, v. 42, p. 89111.CrossRefGoogle Scholar
Neumayr, M., 1875, Die Ammoniten der Kreide und die Systematik der Ammonitiden: Zeitschrift der Deutschen geologischen Gesellschaft, v. 27, p. 854892.Google Scholar
Nützel, A., Schneider, S., Hülse, P., Kelly, S.R.A., Tilley, L., and Veit, R., 2016, A new Early Jurassic gastropod from Ellesmere Island, Canadian Artic—an ancient example of holoplanktonic gastropods: Bulletin of Geosciences, v. 91, no. 2, p. 114.Google Scholar
Page, K.N., 2003, The Lower Jurassic of Europe: its subdivision and correlation: Geological Survey of Denmark and Greenland Bulletin, v. 1, p. 2359.CrossRefGoogle Scholar
Pálfy, J., and Hart, C.J.R., 1994, Biostratigraphy of the Lower to Middle Jurassic Laberge Group Whitehorse map area (105D), Southern Yukon: Yukon Exploration and Geological Services Division, Yukon, Indian and Northern Affairs Canada, Part C, p. 7386.Google Scholar
Poulton, T.P., 1991, Hettangian through Aalenian (Jurassic) guide fossils and biostratigraphy, Northern Yukon and adjacent northwest territories: Geological Survey of Canada, v. 410, 95 p.Google Scholar
Pourmotamed, F., and Motamed, A., 1976, Sur l'existence du Domérien marin dans l'Elbourz central (Iran): Comptes rendus sommaires de la Société Géologique de France, v. 3, p. 105108.Google Scholar
Quenstedt, F.A., 1882–1885, Die Ammoniten des schwäbischen Jura I, Der Schwarze Jura (Lias): Stuttgart, Schweizerbart, 440 p.Google Scholar
Quenstedt, F.A., 1858, Der Jura: Tubingen, H. Laup, 842 p.Google Scholar
Rakus, M., and Guex, J., 2002, Les ammonites du Jurassique inférieur et moyen de la dorsale tunisienne: Mémoires de Géologie, v. 39, 217 p.Google Scholar
Repin, Y.S., 1968, Lower and Middle Jurassic ammonites, in Efimova, A.F., Kinasov, V.P., Paraketsov, K.V., Polubotko, I.V., Repin, Y.S., and Dagis, A.S., eds., Field Atlas of the Jurassic Flora and Fauna of North–East USSR: Magadan, Ministry of Geology, RSFSR, Severo Vostochmoye Ordena Trydovogo Krasnogo Znameni Geologicheskoe Vpravlenie, p. 518.Google Scholar
Repin, Y.S., 1974, Amaltheidae representatives from the upper Pliensbachian deposits in the north-eastern parts of the USSR and their stratigraphical significance, in Sachs, V.N., ed., Biostratigraphy of Boreal Mesozoic: Academy of Sciences of the USSR Siberian Branch, Transactions of the Institute of Geology and Geophysics, v. 136, p. 50174.Google Scholar
Repin, Y.S., 2009, The ammonite scale of the upper Pliensbachian of North-East Asia, in Zakharov, V.A., ed., Third All–Russian Meeting, “Jurassic System of Russia: Problems of Stratigraphy and Paleogeography”: Saratov, Saratov State University, p. 183186. [in Russian]Google Scholar
Repin, Y.S., 2016, Lower Jurassic ammonite geologic time scale of Northeast Asia: Neftegasovaya geologiya Teoriya i practika, v. 11, no. 4, p. 145. [in Russian]Google Scholar
Repin, Y.S., 2017, Late Pliensbachian Amaltheidae (Ammonoidea) of the North–East of Asia: Problems of Paleoecology and Historical Geoecology. Proceedings of the All-Russian Scientific Conference Dedicated to the Memory of Professor V.G. Ocheva, Saratov, p. 7380. [in Russian]Google Scholar
Rulleau, L., Guiffray, A., and Dommergues, J.-L., 2007, Biostratigraphie et paléontologie de la région lyonnaise, Tome II: du socle au Lias moyen: Lozanne, Géo–Paléo du Comité d'établissement des carrières Lafarge, 229 p.Google Scholar
Sato, T., 1955, Les ammonites recueillies dans le groupe de Kuruma, nord du Japon central: Transactions and Proceedings of the Palaeontological Society of Japan, New Series, no. 20, p. 111118.Google Scholar
Sato, T., 1956, Corrélation du Jurassique inférieur japonais en basant sur les Ammonites Fossiles: Journal of the Geological Society of Japan, v. 62, p. 490503. [in Japanese with French abstract]CrossRefGoogle Scholar
Sato, T., 1992, Southeast Asia and Japan, in Westermann, G.E.G., ed., The Jurassic of the Circum–Pacific: New York, Cambridge University Press, p. 194213.Google Scholar
Schubert, S., 2004, Das Pliensbachium im Grenzbereich Unteres/Oberes Pliensbachium (Carixium/Domerium) von Pödinghausen in der Herforder Liasmulde: Berichte des Naturwissenschaftlichen Verein für Bielefeld und Umgegend, v. 44, p. 739.Google Scholar
Sey, I.I., and Kalacheva, E.D., 1980, Biostratigraphy of Lower and Middle Jurassic deposits of the Far East: VSEGEI Transactions, New Series, v. 285, 151 p. [in Russian]Google Scholar
Seyed-Emami, K., Fürsich, F.T., Wilmsen, M., Majidifard, M.R., and Shekarifard, A., 2008, Lower and Middle Jurassic ammonoids of the Shemshak Group in Alborz, Iran and their palaeobiogeographical and biostratigraphical importance: Acta Palaeontologica Polonica, v. 53, p. 237260.CrossRefGoogle Scholar
Smith, A.G., and Briden, J.C., 1977, Mesozoic and Cenozoic Paleocontinental Maps: New York, Cambridge University Press, 63 p.Google Scholar
Smith, P.L., and Tipper, H.W., 1996, Pliensbachian (Lower Jurassic) Ammonites of the Queen Charlotte Islands, British Columbia: Bulletins of American Paleontology, v. 348, 122 p.Google Scholar
Smith, P.L., Tipper, H.W., and Ham, D.M., 2001, Lower Jurassic Amaltheidae (Ammonitina) in North America: paleobiogeography and tectonic implications: Canadian Journal of Earth Science, v. 38, p. 14391449.CrossRefGoogle Scholar
Sonoda, T., Goto, M., and Terada, K., 2015, Discovery of the Early Jurassic turtle from the Kuruma Group, Central Japan: Memoir of the Fukui Prefectural Dinosaur Museum, v. 14, p. 1924. [in Japanese with English abstract]Google Scholar
Sowerby, J., 1812–1822, The Mineral Conchology of Great Britain, Part 1–4: London, Meredith, 383 p.Google Scholar
Takeuchi, M., Tokiwa, T., Kumazaki, N., Yokota, H., and Yamamoto, K., 2017, Depositional age of the Lower Jurassic Kuruma Group based on zircon U–Pb age: The Journal of the Geological Society of Japan, v. 123, p. 335350. [in Japanese with English abstract]CrossRefGoogle Scholar
Takizawa, F., 1984, Upper boundary and veneer rock of the Kuruma Group, Hida–Gaien Belt: Abstracts of the 91st Annual Meeting of the Geological Society of Japan, p. 202. [in Japanese]Google Scholar
Tanabe, K., 1991, Early Jurassic macrofauna of the oxygen-depleted epicontinental marine basin in the Toyora Area, West Japan, in Kotaka, T., Dickins, J.M., Mckenzie, K.G., Mori, K., Ogasawara, K., and Stanley, G.D. Jr., eds., Shallow Tethys, v. 3: Proceedings of the International Symposium on Shallow Tethys, Sendai, p. 147157.Google Scholar
Topchishvili, M., Lominadze, T., Tsereteli, I., Todria, V., and Nadareishvili, G., 2006, Stratigraphy of the Jurassic of Georgia: Proceedings of the Georgian Academy of Sciences, new ser. 122, 455 p.Google Scholar
Tuchkov, I.I., 1954, Jurassic ammonites and belemnites north-east part of USSR: Data on the Geology and Natural Resources of Northeastern USSR, Magadan, v. 8, p. 98125. [in Russian]Google Scholar
van de Schootbrugge, B., et al. , 2018, The Schandelah Scientific Drilling Project: A 25–million year record of Early Jurassic palaeo-environmental change from northern Germany: Newsletters on Stratigraphy, v. 52, p. 249296.CrossRefGoogle Scholar
von Schlotheim, E.F., 1820, Die Petrefactenkunde auf ihrem jetzigen Standpunkte durch die Beschreibung seiner Sammlung versteinerter und fossiler Überreste des Thier- und Pflanzenreichs der Vorwelt: Gotha, Becker, 499 p.Google Scholar
von Zittel, K.A., 1884, Cephalopoda, in von Zittel, K.A., Handbuch der Paläontologie, Abteilung 1, Band 2: München und Leipzig, R. Oldenbourg, p. 329522.Google Scholar
Westermann, G.E.G., 1992, The Jurassic of the Circum–Pacific: New York, Cambridge University Press, 676 p.Google Scholar
Young, G.M., and Bird, J., 1828, A Geological Survey of the Yorkshire Coast: Describing the Strata and Fossils Occurring Between the Humber and the Tees, from the German Ocean to the Plain of York (second edition): Whitby, G. Clark, 332 p., 17 pls.Google Scholar