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Ryazanian (Berriasian) molluscs and biostratigraphy of the Dutch and Norwegian North Sea area (south of Viking Graben)

Published online by Cambridge University Press:  28 April 2022

N.M.M. Janssen*
Affiliation:
TNO – Geological Survey, Utrecht, The Netherlands
M.A. Rogov
Affiliation:
Geological Institute RAS Moscow, Moscow, Russia
V.A. Zakharov
Affiliation:
Geological Institute RAS Moscow, Moscow, Russia
*
Corresponding author: N.M.M. Janssen, Email: nico.janssen@tno.nl

Abstract

Herein, Ryazanian (Berriasian) macrofossils from three well cores in the Central Graben (wells B18-02, L06-02, The Netherlands) and on the Jæren High (well 7/7-2, Norway) in the southern North Sea region are described. Macrofossils are mainly represented by buchiid bivalves (Buchia volgensis) and ammonites (Surites, Lynnia and Praetollia?). The genus Lynnia is recorded for the first time outside its topotypical area, and its systematic position and stratigraphic ranges are discussed. Additionally, the studied core sections yielded coleoid remains and a single limid bivalve. Based on the stratigraphic ranges of key ammonite genera (Lynnia, Surites and Bojarkia), the zonation of the Ryazanian stage is reconsidered. Uppermost Volgian to Ryazanian ammonite faunas are quite consistent and diverse but showing a higher degree of similarity throughout the Panboreal Superrealm as compared to those from rest of the Upper Volgian and the Middle Volgian. Buchia volgensis is the only species known from the southern North Sea and East Anglia, which is in strong contrast to the high diversity of Buchia in East Greenland and the remainder of the Boreal Realm. We hypothesise that such differences in the distribution of ammonites and bivalves in general, and the absence of buchiid species other than Buchia volgensis south of East Greenland in particular, are the result of anoxic bottom water conditions in the southern Viking Strait. The unusually wide geographic range of B. volgensis, which is known from such distant areas as Mexico and the Crimea, suggests a potential higher tolerance of this species to adverse conditions.

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Type
Original Article
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of the Netherlands Journal of Geosciences Foundation
Figure 0

Image 1. Geographical situation. Deep, graben related basins are shaded in green. Red lines indicate faults. Blue lines indicate political sea boundaries. Orange dots indicate Dutch Jurassic volcanos. Black dots indicate the position of the outcrops and wells mentioned or studied herein, where (1) refers to Runcton North and King’s Lynn Bypass (UK) (Casey, 1973), (2) to well B18-02 (NAM, NL) (this work), (3) to well 7/7-2 (Statoil, N) (this work), (4) to wells L06-02 and L06-03 (NAM, NL; after Abbink et al., 2001b; this work) and (5) to well E-1 (DK) (Birkelund et al., 1983) (modified from Rawson et al., 1978, Duin et al., 2006 and Hopson et al., 2008). Abbreviations used: B = Belgium, D = Germany, DK = Denmark, F = France, NL = The Netherlands, NO = Norway, UK = United Kingdom. Abbreviations used for the paleo-domains: LSB = Lower Saxony Basin, MWH = Market Weighton High, SGH = Schill Grund High, TB = Terschelling Basin, TEG = Tail End Graben, and VB = Vlieland Basin.

Figure 1

Image 2. Schematic representation of macrofossil distribution of B18-02 and ammonite zonation based on occurrences of Lynnia (delicate ribbed Lynnia icenii with Buchia volgensis seen in upper right photograph from 2247.95 m). Lower right photograph (depth 2258.75–85 m) shows coprolite in organic-rich fissile mudrock. To the left conditional zonation as applied by Herngreen et al., 2000.

Figure 2

Plate 1. Fossils from well B18-02; all natural size, core diametre = 7 cm)Figs 1–2. Buchia volgensis (Lahusen, 1888), cast and left valve – 2243.60 mFig. 3. Buchia volgensis (Lahusen, 1888), left and right valves – 2244.35 mFig. 4. Buchia volgensis (Lahusen, 1888) – 2256.73 mFig. 5. Buchia volgensis (Lahusen, 1888) – 2258.40 mFig. 6. Buchia volgensis (Lahusen, 1888) – 2257.95 mFig. 7. Buchia volgensis (Lahusen, 1888) – 2258.42 mFig. 8. Fish-remain – 2245.63 mFig. 9. Apical part of Liobelus? sp. – 2249.10 mFig. 10. Juvenile belemnite (lateral) – 2250.18 mFig. 11. Ibid. ventral or dorsal viewFig. 12. Buchia volgensis (Lahusen, 1888) – 2259.83 mFig. 13. Fish-remain – 2256.50 mFig. 14. Pseudolimea cf. arctica (Zakharov, 1966) – 2249.37 m

Figure 3

Image 3. Schematic representation of lithology/lithostratigraphy versus biochronostratigraphy (UK), modified after Casey (1973), Gallois (1984) and Cope (2020). Left column: J74, J76, K10 and K15 are the maximum flooding surface of Partington et al. (1993). In the lithological column, thick black points indicate nodule-rich levels, small points indicate dominantly sandy lithology, while dashed stripes indicate dominantly clayey lithology. Note position of flooding surface K10 (Stenomphala) which is in our opinion characterised by abundant Bojarkia but does not represent the first occurrence of that genus. However, the index species Bojarkia stenomphala seems to occur from K10 on, but not below! In addition, the range of Bojarkia and Surites does not overlap, as erroneously indicated in Casey (1973), and thus omitted in this figure. These are factors complicating the actual extent of the preceding Icenii Zone (see text; indicated by red arrow and red box). Ranges of ammonites are indicated by thick black line (in blue additional data from cores mentioned herein), uncertain ranges are indicated by dashed lines, while reworked specimens are indicated by pink dot with encircled the letter ‘R’. Our interpretation of the correlation towards Speeton (UK) versus (Duxbury, 2018, fig. 2) is shown in the rightmost column.

Figure 4

Plate 2. Fossils from well B18-02; all natural size, unless stated otherwise, core diametre = 7 cm)Fig. 1. Surites sp. (cf. subanalogus Shul’gina, 1972) – 2244.56 mFig. 2. Surites sp. (cf. subanalogus Shul’gina, 1972) – 2248.22 mFig. 3. Surites sp. juvenile (and 2,5x enlarged) – 2249.54 mFig. 4. Surites cf. subanalogus Shul’gina, 1972 and B. volgensis (Lahusen, 1888) – 2256.40 mFig. 5. Surites sp. – 2255.90 mFig. 6. Surites sp. (ex gr. analogus (Bogoslowsky, 1896)) – 2256.08 mFig. 7. Surites sp. (cf. subanalogus Shul’gina, 1972) – 2252.90 m

Figure 5

Plate 3. Fossils from well B18-02; unless indicated otherwise) (all natural size, core diametre (cd) = 7 cm, unless indicated otherwise)Fig. 1. Lynnia icenii Casey, 1973 – 2256.91 mFig. 2. Surites sp. (ex gr. analogus (Bogoslowsky, 1896)), Praetollia? sp. juv. (2 specimens), and Buchia volgensis (Lahusen, 1888) – 2257.93 mFig. 3. Lynnia icenii Casey, 1973 – 2259.55 mFig. 4. Surites sp. (cf. subanalogus Shul’gina, 1972) – 2259.78 mFig. 5. Praetollia cf. contigua Spath, 1952 – 2242.40 m (L06-02; Kochi Zone)Fig. 6. Lynnia icenii Casey, 1973 and Buchia volgensis (Lahusen, 1888) – 2247.95 m (cd =75 mm)Fig. 7. Surites sp. (cf. subanalogus Shul’gina, 1972) – 2257.90 m

Figure 6

Plate 4. Fossils from well 7/7-2 Mandal Formation, 3242-3246.96 m (all natural size)Fig. 1. Surites subanalogus Shul’gina, 1972Fig. 2. Surites aff. poreckoensis Sazonov, 1951Fig. 3. Surites aff. poreckoensis Sazonov, 1951Fig. 4. Surites sp.Fig. 5. Surites sp.Fig. 6. Lynnia icenii Casey, 1973

Figure 7

Image 4. Correlation of ammonite zonation (modified after Rogov et al., 2011; Kiselev et al., 2018; Cope, 2020) and Buchia zonation (modified after Kelly, 1990; Rogov et al., 2020) for northern Siberia, Russian Platform (not represented, momentarily being revised), East Greenland and North Sea areas. Note: asterisk indicated pre-Rjasanensis beds containing a BuchiaShulginites association and possibly being the source of the ammonite Chetaites chetae.

Figure 8

Image 5. Extension of cores investigated and mentioned herein versus Panboreal correlation of late Volgian-Ryazanian (Jurassic-Cretaceous) ammonite zones. Modified after: Rogov et al., 2015, 2020; Kiselev et al., 2018. Note: asterisk indicated pre-Rjasanensis beds containing a BuchiaShulginites association and possibly being the source of the ammonite Chetaites chetae.

Figure 9

Image 6. Paleogeographic reconstruction of North Sea area modified after Abbink et al. (2001a, fig. 15). Left part early – early late Ryazanian, right figure latest Ryazanian (- earliest Valanginian?). Legenda: northern Viking Strait = Greenland Norwegian Seaway, IM = Irish Massif, RBM = Rhenisch-Bohemian Massif, RHB = Rockall-Hatton Bank, and SM = Scottish Massif. Red arrows indicate warm (Tethyan influenced) water currents, blue arrows indicate relative cold water currents; the thicker the arrow, the bigger the influence.