Haugia cf. variabilis (d'Orbigny) has been found in the upper part of the Idenohana Formation in the Uminoura area, Kumamoto Prefecture. This species is originally known from the Upper Toarcian H. variabilis Subzone of the Lytoceras jurense Zone in western Europe. This occurrence combined with our analyses of the lithofacies and sequence stratigraphy suggests that the Idenohana Formation is conformably overlain by the Kyodomari Formation.
Introduction
The stratigraphy and sedimentology of the late Paleozoic–Mesozoic clastic sequence in the Kurosegawa Terrane, Southwestern Japan, are relevant to understanding the structural history of this terrane and, by extension, the Japanese Islands. Stratigraphic sequences in the Uminoura area, Kumamoto Prefecture, western Kyushu, belonging to the Sakamoto Subbelt of the Kurosegawa Terrane, have been described previously (Tamura, 1959)a, 18b, 1960; Orita, 1962; Matsumoto and Kanmera, 1964; Tamura and Murakami, 1987, 1988), and have been assigned a middle Permian–early Cretaceous age, based on fossils from allochronous blocks, including an olistolith and pebbles in conglomerates (Tamura, 1959a; Orita, 1962; Tamura and Murakami, 1987). We recently discovered an early Jurassic ammonoid specimen from a well-stratified synchronous sequence in the Uminoura area (Ohta and Sakai, 2003), and in the present study we describe this specimen and discuss its relevance for the depositional age of the sequence. The specimen described and figured herein is in the National Science Museum, Tokyo, with the prefix NSM PM.
Note on stratigraphy
Mesozoic sequences in the Uminoura area, western Kyushu, are made up of the Idenohana, Kyodomari, and Sakamoto Formations, in ascending order (Figures 1, 2; Ohta and Sakai, 2003). These have conformable contacts with one another (Ohta and Sakai, 2003) and each formation exhibits a fining-upward sequence: The Idenohana Formation begins with conglomerate, passes through sandstone, and ends in silty shale (Figure 2). The Kyodomari Formation begins with limestone breccia, followed by turbiditic sandstone and shale towards the top of the sequence. The Sakamoto Formation is a sequence of slump beds, conglomerate, sandstone and shale towards the upward sequence.
The ammonoid specimen (NSM PM 16811) described herein was collected from the upper part of the Idenohana Formation (Figures 1, 2). These beds consist of silty shale that has been intensively bioturbated and is poorly sorted within a given bed, but the beds are well stratified and laterally traceable overall (Figure 2). Graded, fine sandstones (1–2 cm in thickness) with parallel or ripple laminae make up rhythmic intercalations. These lithological characteristics match those of an autochthonous distal turbidite deposited in a lower-slope environment (Ohta and Sakai, 2003).
Systematic paleontology
Superfamily Hildoceratoidea Hyatt, 1867
Family Hammatoceratidae Buckman, 1887
Subfamily Phymatoceratinae Hyatt, 1867
Genus Haugia Buckman, 1888
Haugia cf. variabilis (d'Orbigny, 1842)
Compared.— Ammonites variabilis d'Orbigny, 1842, p. 350, pl. 113, figs. 1–4.
Harpoceras variabilis (d'Orbigny). Wright, 1884, p. 455, pl. 67, figs. 1–6; pl. 68.
Haugia variabilis (d'Orbigny). Buckman, 1888, p. 146, pl. 25, fig. 2; Dean et al., 1961, p. 484, pl. 73, fig. 4; Guex, 1972, pl. 2, fig. 1.
Haugia variabilis variabilis (d'Orbigny). Gabilly, 1975, p. 82, pl. 10, figs. 7–8, pl. 12, figs. 1–2, pl. 13, figs. 1–2.
Haugia cf. variabilis (d'Orbigny). Ohta and Sakai, 2003, p. 680, fig. 9.
Type.—Type specimen (lectotype) was designated by Buckman (1887) as d'Orbigny's original type (1842, p. 350, pl. 113, figs. 1–2), from France (the exact location is ambiguous).
Material.—NSM PM 16811. Outer mold of secondarily distorted shell, moderately large, 115 mm in maximum preserved shell diameter.
Locality.—NSM PCL 15-56-1 (= Loc. 31 of Orita, 1962; Loc. A of Tamura and Murakami, 1988; Loc. 2 of Ohta and Sakai, 2003; NSM PCL: National Science Museum, Paleontological Collection Locality): a low cliff at Kyodomari Cape, the Uminoura area, Kumamoto Prefecture, western Kyushu (Figures 1, 2).
Description.—Right side of shell only is preserved. Whorl is compressed and moderately evolute, with moderately wide (width of umbilicus (U) = 44 mm at the maximum preserved diameter) and shallow umbilicus and rounded umbilical shoulder. Shell surface is ornamented with strong, regularly spaced ribs. Ribs are prorsiradiate at mid-flank, then become arcuate and directed somewhat backwards on ventro-lateral shell, and are strongly tuberculate at umbilical shoulder and weakly so at mid-flank and ventro-lateral shoulder (Figure 3A). Strength of tubercles on umbilical shoulder changes irregularly accompanied with growth. Some ribs are biplicate and fasciculate and are branching at umbilical tubercles, with secondaries being weaker than primaries. Intervals between ribs on inner whorls are slightly broader than those on outer whorls; however, strength of ribs and tubercles are the same as on outer whorls. Whorl cross-section is subfastigate on inner whorls and subelliptical with obtuse ventro-lateral shoulder on preserved outermost whorl (Figure 3B). Keel and suture are not observable.
Comparison.—Haugia includes many species (e.g., H. ogerieni, H. navis, H. malagma, H. illustris, H. jugosa, H. eseri, H. occidentalis, H. paupera, H. compressa). H. variabilis is distinguished from other species of the same genus by having arcuate ribs that are directed backwards, narrow whorls, a wide umbilicus, a small expansion rate of the whorl, and irregular ornamentation (Buckman, 1890).
The shell morphology of H. variabilis exhibits a wide intraspecific variation (Wright, 1884; Buckman, 1890). There are two distinct varieties: (1) a typical form (including the lectotype) with slightly convex shells having arcuate ribs with irregular ornamentation, and (2) a form with coarser and more irregular ornamentation, which has been termed “var. a” (Wright, 1884; Buckman, 1890). A representative of the latter is illustrated in Wright (1884, pl. 68). The earlier growth stage of this form (U < 45 mm; measured from Wright, 1884, pl. 68, fig. 1) has a coarser and more irregular ornamentation than does the later growth stage (45 < U < 55 mm). Ornamentation fades away on the final half-whorl (U > 55 mm). Thus, the specimen described here is comparable to the earlier growth stage of “var. a” in Wright (1884).
H. variabilis (Neumayr) is distinguished from H. japonica by its more irregular ornamentation, with the secondary ribs being weaker than the primary ribs. H. japonica was originally described and figured in Naumann and Neumayr (1890), and was illustrated in a photograph by Kobayashi (1935). The holotype of H. japonica was collected in the Mitoda, Sakawamachi, Takaoka-gun, Kochi Prefecture, but its exact stratigraphic placement is unknown (Hayami et al., 1963).
Referral to the genus Yokounia, which is endemic to western North America (Jacobs and Smith, 1996), is excluded based on rib morphology, because Yokounia has gently sinuous to rectiradiate ribs.
Occurrence.—Upper Toarcian, H. variabilis Subzone of the Lytoceras jurense Zone in the British Isles, Germany and France (Arkell, 1956; Dean et al., 1961; Mouterde et al., 1971; Gabilly, 1975).
Geological implications
Sequences assigned to the Idenohana and Kyodomari Formations (see Ohta and Sakai, 2003) have hitherto been correlated with middle Permian– upper Triassic strata, based on the fusuline foraminifers Verbeekina sphaera Ozawa, Neoschwagerina simplex Ozawa, Yangchienia compressa (Ozawa), Schubertella giraudi (Deprat) (Kanmera, 1961; Matsumoto and Kanmera, 1964) and the bivalve molluscs Tosapecten suzukii (Kobayashi), Halobia spp., and Pleuromya spp. (Tamura, 1959a, 1960; Orita, 1962; Matsumoto and Kanmera, 1964; Tamura and Murakami, 1988) (Figure 2). However, these fossils are of allochronous origin in submarine-channel facies or slope-margin megabreccias (Ohta and Sakai, 2003; Figure 2). In fact, Tamura and Murakami (1987) reported the cooccurrence of late Triassic and late Jurassic–earliest Cretaceous fossils in an allochronous slump conglomerate (Loc. 5 of Tamura and Murakami, 1987; Figure 2).
The specimen of Haugia cf. variabilis described here was collected from a synchronous distal turbidite facies in the upper part of the Idenohana Formation (Figure 2). This ammonoid is a representative of the Upper Toarcian fauna (H. variabilis Subzone of the Lytoceras jurense Zone) in Europe (Arkell, 1956; Dean et al., 1961; Mouterde et al., 1971; Gabilly, 1975) and implies that the depositional age of the upper part of the Idenohana Formation is Late Toarcian (Figure 2).
In addition, well-stratified black shale of the over-lying Kyodomari Formation contains the Bajocian– early Bathonian radiolarians Cyrtocapsa mastoidea Yao, Unuma typicus Ishikawa and Yao, Tricolocapsa plicarum Yao, and Zartus jurassicus Pessagno (Figure 2; Ohta and Sakai, 2003). These contemporaneous radiolarians and ammonite imply that the Kyodomari Formation conformably overlies the Idenohana Formation without a significant time gap. Lithofacies analysis and sequence stratigraphy (Ohta and Sakai, 2003) are concordant with these ages. These new age data are key to understanding the stratigraphy, geology and structural history of not only the Uminoura area but also the Sakamoto Subbelt of the Kurosegawa Terrane.
Furthermore, occurrences of Haugia variabilis have been hitherto recorded only in northwestern Europe (e.g., d'Orbigny, 1842; Wright, 1884; Buckman, 1888; Arkell, 1956; Dean et al., 1961; Mouterde et al., 1971; Guex, 1972; Gabilly, 1975). Our finding of this species from western Pacific suggests that its geographic distribution might extend to the western Pacific at least.
Acknowledgments
We sincerely thank Y. Shigeta (National Science Museum) and F. Kawabe (Institute of Natural History) for helpful discussion and critical reading of the manuscript. We also thank T. Sakai (Kyushu University) and A. Takahashi (Waseda University) for their kind assistance during field work. This paper has been improved by valuable comments from C. Meister (Muséum d'Histoire Naturelle, Geneva) and K. Tanabe (Tokyo University). This study was supported by grants from the Japan Society for the Promotion of Science (nos. 06365 and 15340178).