Hostname: page-component-77c89778f8-m42fx Total loading time: 0 Render date: 2024-07-20T06:01:04.007Z Has data issue: false hasContentIssue false

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
Rights & Permissions [Opens in a new window]

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.

Type
Original Article
Creative Commons
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

Introduction

Information regarding the temporal and spatial distribution of Ryazanian macrofossils is largely absent for the (southern) North Sea area. No outcrops exist, apart from temporary exposures and quarries in marginal settings (Casey, Reference Casey, Casey and Rawson1973; Kelly, Reference Kelly1984), and distal deposits occur only offshore. Although a large number of offshore wells have been drilled, continuously cored sections containing macrofossils are exceedingly rare. So far, Birkelund et al. (Reference Birkelund, Clausen, Hansen and Holm1983; Denmark) and Abbink et al. (Reference Abbink, Callomon, Riding, Williams and Wolfard2001b; The Netherlands) have figured ammonites from the latest Jurassic to earliest Cretaceous interval of the region. Herein, we report fossils from two additional wells, namely well B18-02 (The Netherlands) and well 7/7-2 (Norway) (Image 1). Apart from ammonites and a few belemnites, these wells have yielded a high number of bivalves (Buchiidae and one Limidae) exclusively comprising byssally attached suspension feeders. Furthermore, an additional ammonite from well L06-02 (The Netherlands) is described. These findings aid to further improve the record of macrofossils and the correlation of strata within the North Sea region. Throughout this work, ammonite zones (e.g. Icenii Zone) are used in the ‘Oppelian’ standard chronostratigraphical, hierarchical sense.

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, Reference Casey, Casey and Rawson1973), (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., Reference Abbink, Callomon, Riding, Williams and Wolfard2001b; this work) and (5) to well E-1 (DK) (Birkelund et al., Reference Birkelund, Clausen, Hansen and Holm1983) (modified from Rawson et al., Reference Rawson, Curry, Dilley, Hancock, Kennedy, Neale, Wood and Worssam1978, Duin et al., Reference Duin, Doornenbal, Rijkers, Verbeek and Wong2006 and Hopson et al., Reference Hopson, Wilkinson and Woods2008). 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.

Geological setting

During the Triassic and Jurassic, a rift system developed in the present-day North Sea area as a result of the break-up of Pangea (Ziegler, Reference Ziegler1982). The development of this rift system can be subdivided into a pre-, syn- and post-rift period (Nøttvedt et al., Reference Nøttvedt, Gabrielsen and Steel1995). Syn-rift conditions influenced the Jurassic sedimentary history up to the earliest Cretaceous. In the Late Jurassic, rifting reached its climax and ceased during the latest Jurassic-earliest Cretaceous transition, resulting in a failed rift (Verreussel et al., Reference Verreussel, Bouroullec, Munsterman, Dybkjær, Geel, Houben, Johannessen and Kerstholt-Boeghold2018, and references therein). The three branches that meet in a triple junction consist of the Viking Graben as the northern branch, the Witch Ground Graben as the western branch and the Central Graben and the Moray Firth Basin as the southern branch. This branch extends in a NW-SE direction from the triple junction to the Salt Dome Province in the Danish offshore. It terminates in the Tail End Graben, but it spreads further south into the German offshore region known as the ‘Entenschnabel’ and into the Dutch North Sea sector. Well 7/7-2 was drilled on the Jæren High, near the northern end of the East Central Graben. The southern extension of this rift basin, the Dutch Central Graben, where well B18-02 is situated, terminates against the Central Offshore Platform (Image 1). To the south, the Terschelling and Vlieland basins occur (Image 1).

The latest Jurassic to earliest Cretaceous sedimentary succession of the Dutch Central Graben is characterised by organic-rich rocks of the Lutine Formation, which in the past were referred to the Kimmeridge Clay Formation (Munsterman et al., Reference Munsterman, Verreussel, Mijnlief, Witmans, Kerstholt-Boegehold and Abbink2012; Verreussel et al., Reference Verreussel, Bouroullec, Munsterman, Dybkjær, Geel, Houben, Johannessen and Kerstholt-Boeghold2018). The Lutine Formation is widespread and in the more distal settings it is characterised by organic-rich, slightly calcareous, greyish-brown fissile mudrocks (Clay Deep Member), while in more proximal settings it has an overall lower organic content (<1%), is more siliciclastic (silts and fine sands) and less dark coloured (Schill Grund Member). A characteristic bundled high gamma ray pattern in the Clay Deep Member distinguishes it from the preceding mudrocks of the Kimmeridge Clay Formation while the overlying mudrocks of the Vlieland Claystone Formation show a low gamma ray pattern.

To the north, the lateral equivalents of the Lutine Formation are the ‘hot shales’ of the Bo Member (Farsund Formation; Danish sector of the North Sea; Feldthusen Jensen et al., Reference Feldthusen Jensen, Holm, Frandsen and Michelsen1986; Michelsen et al., Reference Michelsen, Nielsen, Johannessen, Andsbjerg and Surlyk2003), which have recently also been recorded from the German offshore (Arfai & Lutz, Reference Arfai, Lutz, Bowman and Levell2018), and the Mandal Formation (Norwegian sector of the North Sea; Hamar et al., Reference Hamar, Fjaeran and Hesjedal1983). Further north-eastwards lateral equivalents of these black shale formations are the Agardhfjellet Formation (Spitsbergen), Hekkingen Formation (Barents Sea shelf) and Bazhenovo Formation (Western Siberia) (Rogov et al., Reference Rogov, Shchepetova and Zakharov2020). The Lutine Formation is equivalent to these ‘hot-shale’ units, as demonstrated by dinoflagellate cyst stratigraphy (Dybkjær, Reference Dybkjær1998; Ineson et al., Reference Ineson, Bojesen-Koefoed, Dybkjær and Nielsen2003; Verreussel et al., Reference Verreussel, Bouroullec, Munsterman, Dybkjær, Geel, Houben, Johannessen and Kerstholt-Boeghold2018).

The depositional history of the Ryazanian sedimentary succession is influenced both by the intricacy of the basin and platform configuration and also by the presence and deformation of the Zechstein evaporitic series. The plasticity of the salts resulted in the movement and eventual accumulation of sediments, thus influencing both basin configuration, displacement and fault activity (Korstgård et al., Reference Korstgård, Lerche, Mogensen and Thomsen1993; Clark et al., Reference Clark, Cartwright and Stewart1999; Arfai et al., Reference Arfai, Jähne, Lutz, Franke, Gaedicke and Kley2014; Bouroullec et al., Reference Bouroullec, Verreussel, Geel, de Bruin, Zijp, Kőrösi, Munsterman, Janssen, Kerstholt-Boegehold, Kilhams, Kukla, Mazur, McKie, Mijnlieff and Ojik2018). Surfaced caprocks were eroded and subsequently led to additional erosion of the evaporitic series, locally exposing salts and Permian rocks. Non-deposition and subrosion (subterraneous erosion of salts potentially leading to cavities) could additionally have resulted in irregular distribution of and unconformities in the Ryazanian succession. For example, in the Danish well E-1 (= E-1X or Tyra, Tail End Graben; Birkelund et al., Reference Birkelund, Clausen, Hansen and Holm1983) the top of the ‘hot shale unit’ is placed in the Kochi Zone, based on the occurrence of the ammonite Hectoroceras cf. kochi, while the upper part of the Ryazanian is missing, and an erosional surface separates the uppermost lower Ryazanian deposits from lower Valanginian deposits (Andsbjerg & Dybkjær, Reference Andsbjerg and Dybkjær2003, p. 291).

The ‘end-Jurassic to earliest Cretaceous rifting phase’ was followed by what is known as ‘the Cretaceous transgression’, essentially indicating the base of the Valanginian post-rift sequence (tectono-stratigraphic mega-sequence TMS-4, see Verreussel et al., Reference Verreussel, Bouroullec, Munsterman, Dybkjær, Geel, Houben, Johannessen and Kerstholt-Boeghold2018), when subsidence was no longer limited towards the graben area but influenced the whole region (Jeremiah et al., Reference Jeremiah, Duxbury and Rawson2010; Verreussel et al., Reference Verreussel, Bouroullec, Munsterman, Dybkjær, Geel, Houben, Johannessen and Kerstholt-Boeghold2018, fig. 4). This resulted in contrasting lithologies, creating an important marker horizon in the North Sea area, which is often characterised by a significant unconformity variously termed the ‘base Cretaceous’, ‘late Cimmerian’ or ‘northern North Sea’ unconformity (see Kyrkjebø et al., Reference Kyrkjebø, Gabrielsen and Faleide2004 and references therein). Recently, new information regarding the ‘base Cretaceous unconformity’ (BCU) in the Danish Central Graben (North Jens-1 borehole) has been published by Ineson et al. (Reference Ineson, Sheldon, Dybkjær, Andersen, Alsen and Jakobsen2022). These authors dated the BCU as latest Ryazanian (Peregrinoceras albidum Zone), but the evidence provided seems controversial. Although the presence of a few ammonites below the unconformity is noted, only two incompletely preserved ammonites were figured. Apparently, these ammonites came from the lower part of the Albidum Zone but were referred to Praetollia (Ineson et al., Reference Ineson, Sheldon, Dybkjær, Andersen, Alsen and Jakobsen2022, figs 12A, B), an ammonite genus indicative for the Praetollia maynci – Hectoroceras kochi Zones (early Ryazanian). The authors resolved this conundrum by assuming reworking of the macrofossils. In our opinion, insufficient preservation prevents the precise identification of these specimens. The well-developed and forwards projected ribs of the specimen from their fig. 12B strongly resemble those of the ammonite genus Bojarkia, but we cannot prove this suggestion because the inner whorls are poorly visible. However, the latter genus is characteristic for the latest Ryazanian, broadly indicating the Stenomphala to early Albidum zones.

Studied wells

Well B18-02 (54° 05' 35.4'' N, 04° 47' 48.6'' E; Central Graben, Dutch offshore)

B18-02 is the type well of the Lutine Formation (Munsterman et al., Reference Munsterman, Verreussel, Mijnlief, Witmans, Kerstholt-Boegehold and Abbink2012), comprising the interval from 2225 to 2315 (± 0.2) m. The well was drilled at the northern limit of the Dutch offshore in the Central Graben (Image 1). The cored interval is approximately 18 m thick, from 2242 to 2259.9 m (90% recovery). Additionally, the description of the formation is based on wireline readings and side-wall-cores. Based on dinoflagellate cyst biostratigraphy, Herngreen et al. (Reference Herngreen, Kerstholt and Munsterman2000, p. 28) concluded that deposition took place during the Icenii/Stenomphala to Stenomphala/Albidum zones for the cored part (Image 2).

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., Reference Herngreen, Kerstholt and Munsterman2000.

Well L06-02 (53° 48' 53.70'' N, 04° 59' 20.00'' E; Terschelling Basin, Dutch offshore)

In L06-02, the cored interval is from 2227.00 to 2510.10 m with some minor non-recovered intervals. The upper Volgian to lower Ryazanian occurs between 2227.27 and 2263.40 m. Ammonites were first mentioned in an unpublished report (GAPS, 1991) indicating a late Ryazanian age for the interval from 2245.00 to 2263.40 m, based on the occurrence of abundant Tollia, Bojarkia, Peregrinoceras and indeterminable craspeditids. However, these ammonites turned out to be misidentified. Subsequently, based on determinations of the ammonites by Callomon, Abbink et al. (Reference Abbink, Callomon, Riding, Williams and Wolfard2001b) indicated a late Volgian to early Ryazanian age for the same interval. In addition, the upper part of the core yielded only a single ammonite specimen, herein figured and described as Praetollia cf. contigua Spath, Reference Spath1952 (Pl. 3, Fig. 5), indicating the Kochi Zone. The upper 15 m shows conspicuously few macrofossil remains. Occasionally, non-buchiid bivalves occur at 2228.65–66, 2251.45–47, 2255.23–24 and 2260.19–20 m. The studied interval consists mainly of heavily bioturbated glauconitic sandstone with sponge spicules (Scruff Formation), except for the upper part (2227.00–2227.27 m), which is a dark grey silty to very fine-grained micaceous sandstone without any apparent bioturbation or macrofossils. These are lowermost Valanginian deposits (based on dinoflagellate cysts biostratigraphy; pers. com. R. Verreussel, TNO), while the preceding glauconitic rocks can be dated as latest early Ryazanian (Kochi Chron). Hence, the upper Ryazanian appears to be absent in this borehole.

Well 7/7-2 (57° 29' 4.16'' N, 2° 18' 17.59'' E; Brynhild field, Jæren High, Norwegian offshore)

At the Jæren High, the combination of Jurassic uplift and rotation, and subsequent erosion resulted in the exposure of salt along elongated ridges. The dissolution of these salts due to exposure at the surface eventually created accommodation space for Upper Jurassic deposits (Høiland et al., Reference Høiland, Kristensen and Monsen1993).

In well 7/7-2, 4.5 m of dark coloured shales was cored (90% recovery of interval 3242–3246.96 m; see NPD Factpages) in a relatively thin development of the Mandal Formation, showing the typical ‘hot shale’ signature of this formation. The deposits consist of very dark brown, grey to black coloured mudrocks. Macrofossils are represented by ammonites of the genus Surites (Pl. 4, Figs 1–5) and the species Lynnia icenii (Pl. 4, Fig. 6). They are stored in the Ole Bruun Christensen collection (formerly known as Statoil collection). In addition, the studied interval yielded Buchia volgensis, belemnite remains of Acroteuthis sp. juv. and Onychites, and fish remains (J. Hurum pers. comm. 2019). Unfortunately, the whole collection is simply recorded as derived from the interval of 3201.0–3246.96 m (Åsgard Formation, as indicated by Nerdal et al., Reference Nerdal, Roche and Dombeck1992, tab. 2.1.1), without further detail regarding the position of the individual fossils in the core.

Macrofossils

Ammonites and buchiid bivalves are the most commonly encountered macrofaunal elements (Image 2). Sporadically, belemnites, other bivalves and isolated fish remains (scales, bones; Pl. 1, Figs 8, 13) occur (see also Koevoets et al., Reference Koevoets, Hurum and Hammer2018). Hitherto, only a few latest Jurassic to earliest Cretaceous ammonites from the North Sea have been reported (Casey, Reference Casey, Casey and Rawson1973; Birkelund et al., Reference Birkelund, Clausen, Hansen and Holm1983; Abbink et al., Reference Abbink, Callomon, Riding, Williams and Wolfard2001b; Jeremiah et al., Reference Jeremiah, Duxbury and Rawson2010; Ineson et al., Reference Ineson, Sheldon, Dybkjær, Andersen, Alsen and Jakobsen2022). Only five specimens of Buchia are recorded from the east Midlands Shelf (eastern England) (Kelly, Reference Kelly1983, p. 289) and a few more specimens from on- and offshore Denmark (Sorgenfrei & Buch, Reference Sorgenfrei and Buch1964). It should be noted that all the studied fossils except the belemnites are preserved as flattened moulds (in some cases with the remains of part of the shell). Therefore, the original size and outline are distorted by compaction.

Plate 1. Fossils from well B18-02; all natural size, core diametre = 7 cm)

Figs 1–2. Buchia volgensis (Lahusen, Reference Lahusen1888), cast and left valve – 2243.60 m

Fig. 3. Buchia volgensis (Lahusen, Reference Lahusen1888), left and right valves – 2244.35 m

Fig. 4. Buchia volgensis (Lahusen, Reference Lahusen1888) – 2256.73 m

Fig. 5. Buchia volgensis (Lahusen, Reference Lahusen1888) – 2258.40 m

Fig. 6. Buchia volgensis (Lahusen, Reference Lahusen1888) – 2257.95 m

Fig. 7. Buchia volgensis (Lahusen, Reference Lahusen1888) – 2258.42 m

Fig. 8. Fish-remain – 2245.63 m

Fig. 9. Apical part of Liobelus? sp. – 2249.10 m

Fig. 10. Juvenile belemnite (lateral) – 2250.18 m

Fig. 11. Ibid. ventral or dorsal view

Fig. 12. Buchia volgensis (Lahusen, Reference Lahusen1888) – 2259.83 m

Fig. 13. Fish-remain – 2256.50 m

Fig. 14. Pseudolimea cf. arctica (Zakharov, Reference Zakharov1966) – 2249.37 m

Ammonites

Casey (Reference Casey, Casey and Rawson1973) introduced seven new ammonite zones applied to the North Sea area, based on temporary outcrops, railway cuttings and quarries from the East Midlands in the Spilsby Sandstone and Sandringham Sands formations (Hopson et al., Reference Hopson, Wilkinson and Woods2008, and references therein). These lithologies show signs of intense winnowing and reworking. Typically, sets of clayey to sandy chamosite, glauconite and limonite rich sediments occur, separated by beds consisting of gravel and phosphatic nodules, including in situ and re-deposited macrofossils (Casey & Gallois, Reference Casey and Gallois1973; Casey, Reference Casey, Casey and Rawson1973; Gallois, Reference Gallois1984). Several of these levels yielded latest Jurassic to earliest Cretaceous ammonites (Image 3). Correlation of NW European Ryazanian ammonite zones with those of other Boreal areas, as proposed by Casey (Reference Casey, Casey and Rawson1973) and subsequently widely accepted (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1977, Reference Casey, Mesezhnikov and Shul’gina1987; Marek, Reference Marek1984; Shul’gina, Reference Shul’gina1985; Mesezhnikov, Reference Mesezhnikov, Mesezhnikov and Westermann1988, p. 55), was based on the constrained ranges of several genera, such as Hectoroceras, Surites, Bojarkia and Peregrinoceras. The succession of these genera can be traced throughout the Panboreal Superrealm (sensu Westermann, Reference Westermann2000, p. 52), despite a certain amount of provincialism at the species level. The most challenging problem regarding the zonal succession as proposed by Casey (Reference Casey, Casey and Rawson1973) relates to the apparent lack of expanded sequences and the overall rarity of macrofossils from boreholes (e.g. ammonites were figured and described only once so far by Abbink et al., Reference Abbink, Callomon, Riding, Williams and Wolfard2001b). Moreover, the sections in which the ammonite zones were established are no longer exposed, and after the initial publication of Casey (Reference Casey, Casey and Rawson1973) no additional Ryazanian ammonites were figured or described from East England.

Image 3. Schematic representation of lithology/lithostratigraphy versus biochronostratigraphy (UK), modified after Casey (Reference Casey, Casey and Rawson1973), Gallois (Reference Gallois1984) and Cope (Reference Cope2020). Left column: J74, J76, K10 and K15 are the maximum flooding surface of Partington et al. (Reference Partington, Copestake, Mitchener and Underhill1993). 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 (Reference Casey, Casey and Rawson1973), 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, Reference Duxbury2018, fig. 2) is shown in the rightmost column.

Class Cephalopoda Cuvier, 1795

Subclass Ammonoidea Zittel, 1884

Order Ammonitida Agassiz, 1847

Suborder Ammonitina Hyatt, 1889

Superfamily Perisphinctoidea Steinmann, 1890

Family Craspeditidae Spath, 1924

Subfamily Subcraspeditinae Rogov, 2014

Genus Praetollia Spath, Reference Spath1952

Praetollia cf. contigua Spath, Reference Spath1952

Pl. 3, Fig. 5

Material. One specimen from L06-02 (depth 2242.40 cm), from glauconitic sandstones of the Scruff Formation.

Description. The specimen is represented by a fragment of the outer whorl (body chamber?), with a relatively wide umbilicus. It shows the typical ribbing of Praetollia, which consists of slightly curved primary ribs accompanied in the upper flanks by intercalated secondaries. Primaries and secondaries are weakly connected, and the ribbing is unclear on the mid-flanks. High rib ratio (∼3.5) suggests proximity of this specimen to P. contigua, especially with specimens from the Kochi Zone of the lower reaches of the Lena River (Rogov et al., Reference Rogov, Zakharov and Ershova2011, pl. V, figs 1, 2, 8). When compared to P. contigua from the Maynci Zone of East Greenland (Spath, Reference Spath1952, pl. I, fig. 2; pl. II, fig. 1; pl. III, fig. 1; pl. IV, fig. 2), our specimen shows slightly more distant ribs.

Remarks. The figured specimen was not mentioned by Abbink et al. (Reference Abbink, Callomon, Riding, Williams and Wolfard2001b). The remaining core, which was not investigated by these authors, did not yield any ammonites. The specimen points to the Kochi Zone, as follows from its stratigraphic position above the first Hectoroceras occurrences and from its overall morphology, most closely resembling those Praetollia recorded from the Kochi Zone.

Praetollia? sp. juv.

Pl. 3, Fig. 2

Materials. Two specimens from core B18-02 (depth 2257.93 m).

Description. The small-sized (diametre approximately 28.6 and 19.7 mm) juvenile specimens show densely ribbed whorls with a narrow umbilicus. The very fine ribbing of these ammonites distinguishes them from other co-occurring craspeditids. Although the early whorls of Borealites and Lynnia are covered by relatively densely spaced ribs, their ribbing is more prominent and coarser when compared to that seen in Praetollia.

Remarks. Until recently, the youngest records of the ammonite genus Praetollia were reported from the Kochi Zone (cf. Abbink et al., Reference Abbink, Callomon, Riding, Williams and Wolfard2001b, p. 285; Rogov et al., Reference Rogov, Zakharov and Ershova2011; Igolnikov, Reference Igolnikov2019, p. 42–43, 121). However, the occurrence of Lynnia below and above our record of Praetollia suggests Praetollia to range into at least the lower part of the Icenii Zone.

Subfamily Craspeditinae Spath, 1924

Herein, the subfamily Suritinae Sazonova, Reference Sazonova1971 is considered a synonym of Craspeditinae. Suritinae is distinguished from the Tolliinae in the sense of Shul’gina (Reference Shul’gina1985), who emphasised differences in septal suture ontogeny between Tolliinae (Bojarkia, Tollia, Neotollia and Virgatoptychites) and the rest of the early craspeditids. All other Volgian and Ryazanian genera were ascribed to the Craspeditinae by Shul’gina; at present some of these genera are re-assigned to Subcraspeditinae and Garniericeratinae.

Genus Lynnia Casey, Reference Casey, Casey and Rawson1973

  • 1973 Surites (Lynnia) subgen. nov. – Casey, p. 254.

  • 1977 Lynnia Casey – Casey et al., p. 23.

  • 1983 Lynnia Casey – Gallois, p. 322.

  • 1985 Lynnia Casey – Shul’gina, p. 133, 156.

  • 1996 Surites (Lynnia) Casey – Callomon in Wright et al., p. 25.

Type species. Surites (Lynnia) icenii Casey, Reference Casey, Casey and Rawson1973 (by original designation).

Diagnosis. Craspeditid ammonites, characterised by very strong and widely spaced triplicate ribs covering the terminal body chamber and perhaps part of the phragmocone, a sculptural feature that is unique for the Ryazanian craspeditids.

Remarks. The genus Lynnia is an insufficiently known taxon. Its original diagnosis was published in a relatively short form along with the diagnosis as a new subgenus (Casey, Reference Casey, Casey and Rawson1973, p. 254), and only one species has been referred to Lynnia (L. icenii). A few years after erecting the (sub)genus Surites (Lynnia), its rank has been elevated to the genus level by Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1977), but without any explanation, which was subsequently followed by Gallois (Reference Gallois1983), Shul’gina (Reference Shul’gina1985, p. 156) and Klein (Reference Klein2006). Only Shul’gina (Reference Shul’gina1985, p. 156) noted that ‘Lynnia… is a separate genus, as by character of its sculptural development it differs from Surites’. Unfortunately, when describing Lynnia, Casey (Reference Casey, Casey and Rawson1973) did not provide any data about the development of its sculpture; however, in the figure of the holotype of L. icenii part of the inner whorls is visible; these are covered by relatively weak, dense and thin ribs (Casey, Reference Casey, Casey and Rawson1973, pl. 8, fig. 5). Perhaps Callomon (in Wright et al., Reference Wright, Callomon, Howarth, Moore and Kaesler1996) based his diagnosis of this (sub)genus on the aforementioned figure. He considered this taxon as microconch, but the provided diagnosis is very short: ‘ribs fine at first, later coarse and trifurcating high on side’ (Callomon in Wright et al., Reference Wright, Callomon, Howarth, Moore and Kaesler1996, p. 25).

Lynnia icenii is the only valid species ascribed to the genus Lynnia, although Casey (Reference Casey, Casey and Rawson1973, p. 254) wrote: ‘This subgenus is represented by a number of species in the interval between the kochi and stenomphalus Zones in England’. In this paper, Lynnia is considered a separate genus following Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1977 and subsequent contributions). However, an emended diagnosis of the genus Lynnia or the species L. icenii can only be given after re-studying of the collection of Casey, and for now all occurrences herein mentioned are ascribed to a single variable species, L. icenii. Outside NW Europe similar craspeditids are unknown. Only some coarsely ribbed Surites from the Russian platform sometimes show the presence of triplicate ribs (Sazonova, Reference Sazonova1971, pl. XX, fig. 3), and the same is true for some Siberian Surites (Rogov et al., Reference Rogov, Zakharov and Ershova2011, pl. V, fig. 6), but nevertheless biplicate ribs predominate in Surites, while in addition the ribs in Lynnia are more widely spaced. Herein, specimens of Lynnia are reported for the first time from outside their type area.

Lynnia icenii (Casey, Reference Casey, Casey and Rawson1973)

Text-Fig. 2; Pl. 3, Figs 1, 3, 6; Pl. 4, Fig. 6.

  • 1973 Surites (Lynnia) icenii sp. nov. – Casey, p. 254, pl. 8, figs 4–5; figs 6 l-m.

  • 1996 Surites (Lynnia) icenii Casey – Callomon in Wright et al., p. 25, figs 15.3a-c [= Casey, Reference Casey, Casey and Rawson1973].

  • 2006 Lynnia icenii Casey – Klein, p. 39.

Holotype. Surites (Lynnia) icenii Casey, Reference Casey, Casey and Rawson1973, p. 254, pl. 8, fig. 5 (holotype by original designation); coll. no. GSM Ce 5298, Mintlyn Beds, Icenii Zone, bed 12, North Sea gas pipe-line trench, Manor Farm, North Runcton, near King’s Lynn, Norfolk.

Materials. 3 specimens from well B18-02, Clay Deep member, Lutine Formation, depth 2247.95 to 2259.91 m; one specimen (coll. no. NHM 93S001/famm5020b) in Christensen collection, from Statoil well 7/7-2, Åsgard Formation, depth 3242.00–3246.96 m.

Description. Both B18-02 and 7/7-2 yielded small-sized (diametre 5.2–5.6 cm) craspeditid ammonites, characterised by very strong and widely spaced triplicate ribs (9–12 primaries per half of the whorl) covering the terminal body chamber and part of the phragmocone. The ribbing of the inner whorls is poorly visible and its character is unclear. The umbilicus is moderately wide. At least one specimen (Pl. 3, Fig. 6) shows some kind of widening of the umbilicus near the body chamber, giving evidence of the ‘eccentric umbilicus’ as mentioned by Casey (Reference Casey, Casey and Rawson1973). Although all our specimens are preserved as crushed moulds, their ribbing is very clear. Some of our specimens (Pl. 3, Fig. 6; Pl. 4, Fig. 7) show the typical Lynnia ribbing, while other (Pl. 3, Figs 1, 3) recorded below the typical specimen in the core B18-02 are characterised by a ribbing pattern intermediate between those of Lynnia and Surites. These poorly preserved ammonites with intermediate sculpture should possibly be referred to a new species of Lynnia, but for the moment we prefer to include them in L. icenii.

Genus Surites Sazonov, Reference Sazonov1951

Surites aff. poreckoensis Sazonov, Reference Sazonov1951

Pl. 4, Figs 2–3

Material. Two specimens from Statoil well 7/7-2.

Remarks. The studied ammonites are represented by partially preserved moulds (∼52 mm in maximum visible diametre), with badly preserved inner whorls. Both the outer whorl and the visible part of the inner whorl are covered by relatively dense, inclined forwards, triplicate ribs, with a little addition of single and biplicate ribs.

Remarks. This binomen is herein used for Surites specimen showing frequent triplicate ribs. Although the occurrence of triplicate ribs is known in the outer whorls of diverse Surites, these ammonites usually show the transition from mainly biplicate to mixed biplicate-triplicate ribbing additionally to a bigger diametre. Surites poreckoensis specimens from the Russian Platform (Sazonov, Reference Sazonov1951, pl. 1, fig. 2; Sazonova, Reference Sazonova1971, pl. V, figs 1–2) differ from the figured specimen by having coarser ribs in their inner whorls, and later appearance of the triplicate ribbing. The style of ribbing in S. aff. poreckoensis resembles those of the subcraspeditid genus Borealites, but the latter is characterised by weaker ribs with early appearance of branches and with a rib ratio of 3–4.

Surites ex gr. subanalogus Shul’gina, Reference Shul’gina1972

Pl. 2, Figs 1–7; Pl. 3, Figs 2, 4, 7

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, Reference Shul’gina1972) – 2244.56 m

Fig. 2. Surites sp. (cf. subanalogus Shul’gina, Reference Shul’gina1972) – 2248.22 m

Fig. 3. Surites sp. juvenile (and 2,5x enlarged) – 2249.54 m

Fig. 4. Surites cf. subanalogus Shul’gina, Reference Shul’gina1972 and B. volgensis (Lahusen, Reference Lahusen1888) – 2256.40 m

Fig. 5. Surites sp. – 2255.90 m

Fig. 6. Surites sp. (ex gr. analogus (Bogoslowsky, Reference Bogoslowsky1896)) – 2256.08 m

Fig. 7. Surites sp. (cf. subanalogus Shul’gina, Reference Shul’gina1972) – 2252.90 m

Materials. 14 specimens from well B18-02: 2244.56 m (Pl. 2, Fig. 1), 2248.22 m (Pl. 2, Fig. 2), 2248.70 m, 2249.90 m (Pl. 3, Fig. 7), 2252.88 m, 2252.90 m (Pl. 2, Fig. 7), 2253.60 m, 2255.40 m, 2256.08 m (Pl. 2, Fig. 6; S. ex gr. analogus), 2256.40 m (Pl. 2, Fig. 4), 2257.93 m (Pl. 3, Fig. 2; S. ex gr. analogus), 2258.40 m, 2259.40 m, 2259.78 m (Pl. 3, Fig. 4) and one specimen from well 7/7-2 (Pl. 4, Fig. 1).

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, Reference Casey, Casey and Rawson1973 – 2256.91 m

Fig. 2. Surites sp. (ex gr. analogus (Bogoslowsky, Reference Bogoslowsky1896)), Praetollia? sp. juv. (2 specimens), and Buchia volgensis (Lahusen, Reference Lahusen1888) – 2257.93 m

Fig. 3. Lynnia icenii Casey, Reference Casey, Casey and Rawson1973 – 2259.55 m

Fig. 4. Surites sp. (cf. subanalogus Shul’gina, Reference Shul’gina1972) – 2259.78 m

Fig. 5. Praetollia cf. contigua Spath, Reference Spath1952 – 2242.40 m (L06-02; Kochi Zone)

Fig. 6. Lynnia icenii Casey, Reference Casey, Casey and Rawson1973 and Buchia volgensis (Lahusen, Reference Lahusen1888) – 2247.95 m (cd =75 mm)

Fig. 7. Surites sp. (cf. subanalogus Shul’gina, Reference Shul’gina1972) – 2257.90 m

Diagnosis. Relatively small-sized ammonites (with a diametre mainly between 40 and 75 mm) with semi-evolute shells. The umbilicus varies from relatively narrow to relatively wide. The ribbing is represented by strong and relative frequent ribs (15–20 primaries per half of the whorl) inclined towards the aperture. In the inner whorls, all ribs are biplicate but on the body chamber and last part of the phragmocone, more or less commonly triplicate ribs appear.

Remarks. Species of Surites are predominantly known from the late Ryazanian but do occur from the latest early Ryazanian onward and disappear in the Stenomphala Zone. A less densely ribbed juvenile specimen (Pl. 2, Fig. 3) is relatively similar to Praetollia? sp. juv. (Pl. 3, Fig. 2). In addition, several indeterminable specimens are figured (Pl. 2, Fig. 5; Pl. 4, Figs 4–5). Both the type of ribbing and the size of these ammonites are in agreement with S. subanalogus of the type area (Igolnikov, Reference Igolnikov2006). However, these ammonites are determined in open nomenclature, due to their preservation (crushed moulds) besides the rare occurrence of outer whorls.

Plate 4. Fossils from well 7/7-2 Mandal Formation, 3242-3246.96 m (all natural size)

Fig. 1. Surites subanalogus Shul’gina, Reference Shul’gina1972

Fig. 2. Surites aff. poreckoensis Sazonov, Reference Sazonov1951

Fig. 3. Surites aff. poreckoensis Sazonov, Reference Sazonov1951

Fig. 4. Surites sp.

Fig. 5. Surites sp.

Fig. 6. Lynnia icenii Casey, Reference Casey, Casey and Rawson1973

Belemnites

The investigated cored rocks from the wells B18-02 and 7/7-2 yielded only a few belemnites. This seems in line with other records from the North Sea area, where belemnites findings seem mainly confined to shallow and condensed deposits (Pinckney & Rawson, Reference Pinckney and Rawson1974; Swinnerton & Kent, Reference Swinnerton and Kent1981, p. 60–63; Jeremiah et al., Reference Jeremiah, Duxbury and Rawson2010, p. 210). In addition, Sorgenfrei & Buch (Reference Sorgenfrei and Buch1964) mention specimens from northern Denmark (core E-1). The Norwegian core 2/1-9 (East Central Graben; Gyda Field, NPD Factpages), yielding Ryazanian rocks, shows relatively frequent cross-sections of cylindroteuthid species. Swientek (Reference Swientek2002) mentions relatively common belemnites and buchiids throughout the Volgian–Ryazanian succession from core 13/1-U-2 (southern Norway). However, few belemnite species have been identified hitherto from the latest Jurassic-earliest Cretaceous of the North Sea. Compared to the Russian Platform (e.g. Saks & Nal’nyaeva, Reference Saks and Nal’nyaeva1975; Sazonova, Reference Sazonova1977; Urman et al., Reference Urman, Shurygin and Dzyuba2019), belemnites appear almost absent in the North Sea area, which could be due to a lack of outcrops and limited availability of cored material. Additionally, their distribution appears to be controlled by their swimming capacity (Zakharov et al., Reference Zakharov, Rogov, Dzyuba, Žák, Martin Košt’ák, Pruner, Skupien, Chadima, Mazuch and Nikitenko2014; Mutterlose et al., Reference Mutterlose, Alsen, Iba and Schneider2020). In general, rostrum remains are more often concentrated in the more proximal (glauconitic) facies, for example, by winnowing, while in more distal mudrock facies belemnites are more isolated and arm hooks are more striking (e.g. Hammer et al., Reference Hammer, Hryniewicz, Hurum, Høyberget, Knutsen and Nakrem2013; Koevoets et al., Reference Koevoets, Hurum and Hammer2018).

Phylum Mollusca Cuvier, 1795

Subclass Coleoidea Bather, 1888

Order Belemnitida Zittel, 1895

Family Cylindroteuthididae Stolley, 1919

Genus Liobelus Dzyuba, Reference Dzyuba2004

Liobelus? sp. indet.

Pl. 1, Fig. 9

Material. An apical part of a belemnite rostrum occurs at 2249.10 m. In addition, two juvenile specimens (Pl. 1, Figs 10–11), most probably belonging to the same genus, were retrieved (see Fig. 2). Also few micro-Onychites or belemnite hooks occur in the core B18-02. The core 7/7-2 yielded belemnite hooks and a juvenile Acroteuthis (or Liobelus).

Remarks. Pickney & Rawson (Reference Pinckney and Rawson1974) mention belemnites from the Lincolnshire area. Their ‘Assemblage 2’ represents the early – early late Ryazanian, yielding rare Liobelus ex gr. lateralis (Phillips, Reference Phillips1835). The subsequent ‘Assemblage 3’ is most probably of latest Ryazanian age and younger.

Buchiids.

The genus Buchia is restricted to the northern hemisphere (Panboreal Superrealm), but sometimes migrated southwards into northern margins of the Tethyan and Pacific Realms, in which these bivalves cooccurred with Tethyan and Pacific ammonites respectively (cf. Zakharov & Rogov, Reference Zakharov and Rogov2003, Reference Zakharov and Rogov2020). Because of its ubiquitous presence and a high rate of evolution buchiids are relatively good guide fossils, but some differences in their assemblages can be observed in the distal to proximal trends within a basin (Zakharov, Reference Zakharov1987) and between the different paleogeographic subdivisions. Nonetheless, a rather uniform zonation can be established (Zakharov, Reference Zakharov1981, Reference Zakharov1987; Grey, Reference Grey2009; Zakharov & Rogov, Reference Zakharov and Rogov2020 and refs. therein; Image 4).

Image 4. Correlation of ammonite zonation (modified after Rogov et al., Reference Rogov, Zakharov and Ershova2011; Kiselev et al., Reference Kiselev, Rogov and Zakharov2018; Cope, Reference Cope2020) and Buchia zonation (modified after Kelly, Reference Kelly1990; Rogov et al., Reference Rogov, Shchepetova and Zakharov2020) 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.

Buchiids produced planktotrophic larvae, so-called veliger, and were thus feeding in the water column as part of the zooplankton. The planktotrophic larvae allowed buchiids to disperse over wide geographic areas. Furthermore, they were able to tolerate a variety of environments (eurybiontic). However, eventually during maturity they needed a (hard) substrate to settle, as they were byssally attached filter feeders. Yet, buchiid bivalves are known from nearly all sedimentary marine facies, from black shales and limestones to conglomerates and tuffites.

During the late Volgian, buchiid bivalves appear to have been absent from the North Sea area. All known Ryazanian Buchia records from NW Europe so far are represented by very few occurrences of a single species (Buchia volgensis), including those from the east coast of the UK (Casey, Reference Casey, Casey and Rawson1973; Kelly, Reference Kelly1983, Reference Kelly1984, Reference Kelly1990). Few B. volgensis were mentioned from the Upper Spilsby Sandstone in Donington (Lincolnshire), apparently from the Stenomphala Zone (Casey, Reference Casey, Casey and Rawson1973; Kelly, Reference Kelly1984, Reference Kelly1990). Additional specimens of B. volgensis were figured from a deep borehole drilled in northern Denmark (Sorgenfrei & Buch, Reference Sorgenfrei and Buch1964, figs. 72, 86 as Buchia fischeriana). Previously reported findings of B. cf. volgensis from northern Germany (Pavlow, Reference Pavlow1896; Harbort, Reference Harbort1905) were erroneously determined and represent Valanginian Buchia (Kelly, Reference Kelly1990).

Phylum Mollusca Cuvier, 1795

Class Bivalvia Linnaeus, 1758

Order Pectinida Gray, 1854

Family Buchiidae Cox, 1953

Genus Buchia Rouillier, Reference Rouillier1845

Buchia volgensis (Lahusen, Reference Lahusen1888)

Pl. 1, Figs 1–7, 12; Pl. 2, Figs 1, 4; Pl. 3, Figs 2, 6

  • *1888 Aucella volgensis – Lahusen, p. 16, pl. III, figs 1-17.

  • 1896 Aucella volgensis Lahusen – Pavlow, p. 549, pl. 27, fig. 1.

  • 1896 Aucella volgensis var. radiolata – Pavlow, p. 549, pl. 27, fig. 2.

  • 1905 Aucella volgensis Lahusen – Woods, p. 69–70, pl. X, figs 1–2 [= Pavlow, Reference Pavlow1896].

  • 1964 Buchia fischeri (d’Orbigny) – Sorgenfrei & Buch, p. 131, pl. 7, fig. 72; pl. 8, fig.86.

  • 1978 Buchia volgensis (Lahusen) – Birkelund et al., p. 56, pl. 4, figs 1–2; pl. 5, figs 4–6.

  • 1978 Buchia volgensis (Lahusen) – Surlyk, pl. 4, fig. 8; pl. 6, figs 1–5.

  • 1981 Buchia volgensis (Lahusen) – Håkansson et al., p. 26, pl. 5, figs 4–5.

  • 1981 Buchia volgensis (Lahusen) – Zakharov, p. 125, pl. XXXVII, figs 5–7; pl. XXXVIII, figs 1–3; pl. XXXIX, figs 1–4; pl. XL, figs 1–2 (cum syn.).

  • 1981 Buchia volgensis (Lahusen) – Zakharov et al., p. 264, pl. I, fig. 5.

  • 1982 Buchia volgensis (Lahusen) – Surlyk & Zakharov, p. 740, pl. 75, fig. 2 (cum syn.).

  • 1984 Buchia (Buchia) volgensis (Lahusen) – Kelly, p. 58, pl. 10, figs 1,3,4,7,8 (cum syn).

  • 1986 Buchia cf. volgensis (Lahusen) – Århus et al., p. 23 (cum syn).

  • 1986 Buchia volgensis (Lahusen) – Braduchan et al., p. 119, pl. XXXIX, figs 7–10.

  • 1987 Buchia volgensis (Lahusen) – Zakharov, p. 146.

  • 1989 Buchia volgensis (Lahusen) – Paraketsov & Paraketsova, p. 22, pl. XI, figs 1–3.

  • 1990 Buchia cf. volgensis (Lahusen) – Århus et al., p. 177, fig. 7D (cum syn).

  • 1990 Buchia volgensis (Lahusen) – Kelly, p. 138, pl. II, figs 2a-c.

  • 1990 Buchia volgensis (Lahusen) – Vyachkileva et al., p. 66, pl. 27, figs. 1–3, 5, 13–14; pl. 28, figs 1,3,5,9.

  • 1993 Buchia volgensis (Lahusen) – Sha & Fürsich, p. 536, figs 3n-o.

  • 2009 Buchia cf. volgensis (Lahusen) – Marinov et al., pl. II, fig. 17.

  • 2011 Buchia volgensis (Lahusen) – Rogov et al., pl. 2, fig. 7, pl. 3, fig. 1.

  • 2014 Buchia volgensis (Lahusen) – Urman et al., pl. 3, figs 1–3.

  • 2017 Buchia volgensis (Lahusen) – Rogov et al., figs 6.2–3, 10.

  • 2019 Buchia volgensis (Lahusen) – Kosenko et al., p. 555.

  • 2019 Buchia volgensis (Lahusen) – Urman et al., pl. I, fig. 10–11

  • 2020 Buchia volgensis (Lahusen) – Schneider et al., p. 12, figs 11G-H (cum syn.).

Syntypes. 17 specimens, some of which were figured by Lahusen, Reference Lahusen1888, pl. III, fig. 1–17; Lectotype: Lahusen, Reference Lahusen1888, pl. III, figs 3–5, indicated by Glazunova (Reference Glazunova1973, p. 35), re-figured in Zakharov, Reference Zakharov1981, pl. XL, fig. 1.

Materials. At least 40 specimens from well B18-02, Clay Deep Member, Lutine Formation, Central Graben, Dutch offshore, mainly represented by right valves. All from the late Ryazanian (Icenii Zone).

Description. The shells are uncommonly large (length up to 62 mm, see Pl. 1, Figs 1, 3, 4, 7), high, slightly oblique, moderately convex and slightly inequilateral. Right valves are characterised by inversion of the ontogeny (well visible in Pl. 1, Figs 1, 3, 7). In outline, the right valves are close to an isosceles triangle, elongated in height (Pl. 1, Figs 1, 5, 7). The apical angle is close to 90º. The sculpture on the shell is commonly represented by thick lamellar concentric ribs (Pl. 1, Figs 2. 7). Small concentric smoothed folds are clearly visible on the nuclei (Pl. 1, Figs 1, 3, 4, 5, 12).

Results and discussion

Ammonite stratigraphy

Based on the occurrence of ammonites (Lynnia and common Surites), and Buchia volgensis, a Ryazanian age can be assigned to the studied core sections. A more specific age is based on the occurrence of Lynnia icenii indicating the Icenii Zone, and thus marking the base of the late Ryazanian. The Icenii Zone was introduced by Casey (Reference Casey, Casey and Rawson1973) based on ammonite findings in temporary outcrops near ‘The Wash’, an inlet at the border between Norfolk and Lincolnshire at the east coast of the UK (Image 1). The Icenii Zone is best known from exposures in the vicinity of North Runcton and King’s Lynn (Casey & Gallois, Reference Casey and Gallois1973; Casey, Reference Casey, Casey and Rawson1973), where it consists of only a few decimetres of glauconitic sands and clay with clay ironstone and seams of phosphatic nodules (Image 3).

Lynnia is the characteristic ammonite genus of this zone. Surites and Bojarkia were also reported but were not figured and are generally less common (Casey, Reference Casey, Casey and Rawson1973, p. 210). The co-occurrence of Lynnia and Bojarkia has been reported from a condensed 5 cm thick nodule bed only (Casey, Reference Casey, Casey and Rawson1973, p. 200). Subsequently, Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1987, Reference Casey, Mesezhnikov and Shul’gina1988) indicated the co-occurrence of Lynnia, Surites and Bojarkia throughout the Icenii Zone. However, in the remainder of the Panboreal Superrealm Surites and Bojarkia do not co-occur and are only known from different, succeeding ammonite zones (Shul’gina, Reference Shul’gina1985, p. 21–22; Baraboshkin, Reference Baraboshkin2004, p. 53). Hence, the ammonite assemblage of the Icenii Zone in its type area remains controversial. There are three options, regarding the range and occurrence of Lynnia: (1) Lynnia is restricted to the Icenii Zone. (2) Lynnia occurs in the Icenii Zone and also at the base of the Stenomphala Zone. (3) Lynnia is represented as reworked phosphatic casts at the base of the succeeding Stenomphala Zone. Casey (Reference Casey, Casey and Rawson1973, p. 200, 210) mentions Bojarkia sp. from a 5 cm thick level (bed 6 at King’s Lynn Bypass) with black rolled phosphatic nodules, resting on an irregular surface of the bed below, a condensed bed (bed 5) of 10 cm with pale, sandy, clay ironstones with semi-phosphatised knobs on the upper surface yielding Lynnia sp. nov. From this, it is clear that these Bojarkia co-occurred with Lynnia in the condensed level. It is well possible that bed 6 yields taxa characteristic for both the Icenii Zone and the succeeding Stenomphala Zone, which would explain the presence of Bojarkia in this bed. Actually, Casey (Reference Casey, Casey and Rawson1973, p. 200) mentions almost 5 m of strata above bed 6 without ammonites. The two condensed beds are part of the Upper Spilsby Sandstone (Mid-Spilsby Nodule Bed) (see Casey, Reference Casey, Casey and Rawson1973, p. 201). Casey (Reference Casey, Casey and Rawson1973, p. 254) further noted that ‘This subgenus is represented by a number of species in the interval between the Kochi and Stenomphala Zones in England’. However, to date only the type species Surites (Lynnia) icenii is figured and described.

Casey, Reference Casey, Casey and Rawson1973 and Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1987, fig. 4; Reference Casey, Mesezhnikov and Shul’gina1988, p. 81) correlate the Icenii Zone with the Analogus Zone, taking into account its stratigraphic position (above the Kochi Zone, which is widely traced throughout the Boreal regions) and findings of unfigured Surites in this zone, and we follow the same correlation.

In summary, well B18-02 yielded an exceptionally rich but monospecific buchiid fauna (B. volgensis), combined with frequent Boreal ammonites, mainly Surites, possibly Praetollia, and few endemic Lynnia, but very few belemnites. In northern Siberia, similar abundances of B. volgensis occur above the Kochi Zone, at the base of the Analogus Zone (Zakharov, Reference Zakharov1981, fig. 79; Zakharov, Reference Zakharov1990, figs 2–3). Surites occurs in abundance in northern and western Siberia (e.g. Shul’gina, Reference Shul’gina1975, Reference Shul’gina1985; Vyachkileva et al., Reference Vyachkileva, Klimova, Turbina, Braduchan, Zakharov, Meledina and Aleinikov1990; Igolnikov, Reference Igolnikov2019), the Russian Platform (e.g. Sazonova, Reference Sazonova1977; Mitta, Reference Mitta2017), East Greenland (Alsen, Reference Alsen2006), Spitsbergen (Ershova, Reference Ershova1983) and Franz-Josef Land (Dibner & Shulgina, Reference Dibner and Shulgina1998).

Recapitulation of the ammonite zonal succession of the Volgian/Ryazanian boundary and the Ryazanian of NW Europe and its Panboreal correlation

Some comments should be provided concerning ammonite zonal succession applied in this paper for the Ryazanian, and its correlation with other Boreal key successions yielding ammonites (Image 5), primarily with those of European Russia, which is the type area of the Ryazanian stage, and of Northern Siberia, where a continuous succession of Boreal ammonite stages occurs. The Ryazanian Stage was initially proposed by Sazonov (Reference Sazonov1951) without detailed characterisation, but a few years later Sazonov (Reference Sazonov1953) provided details concerning the faunal composition and geographic distribution including the type region, the Pericaspian area and the Northern Caucasus. Outside Russia this stage name was first applied by Casey (Reference Casey1962) as ‘Riasan Beds’ and by Casey (Reference Casey1963) as Ryazanian for a sedimentary succession in Norfolk and Lincolnshire (UK). Casey considered the Ryazanian as the first stage of the Cretaceous, and, in Lincolnshire, drew its base at the top of Lower Spilsby Sandstone. The Ryazanian Stage became widely used for Boreal regions after the publication of the seminal paper by Casey (Reference Casey, Casey and Rawson1973) comprising the description of ammonites and zonal succession of the upper Volgian and Ryazanian deposits of eastern England, as well as its correlation with other Boreal successions. Unfortunately, several important ammonite taxa mentioned by Casey remain unfigured, and later only minor additions concerning the English succession were published in cooperation with Soviet scientists (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1977, Reference Casey, Mesezhnikov and Shul’gina1987, Reference Casey, Mesezhnikov and Shul’gina1988).

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., Reference Rogov, Baraboshkin, Guzhikov, Efimov, Kiselev, Morov and Gusev2015, Reference Rogov, Shchepetova and Zakharov2020; Kiselev et al., Reference Kiselev, Rogov and Zakharov2018. Note: asterisk indicated pre-Rjasanensis beds containing a BuchiaShulginites association and possibly being the source of the ammonite Chetaites chetae.

The Lamplughi Zone is the uppermost unit of the Volgian Stage (Images 35) introduced by Casey (Reference Casey, Casey and Rawson1973) and is characterised by a very specific ammonite assemblage that consists of Volgidiscus and Subcraspedites, genera that disappear at the Volgian/Ryazanian boundary. The genus Volgidiscus occurs in coeval strata of the Russian Platform, Subpolar Urals and Northern Siberia (Kiselev et al., Reference Kiselev, Rogov and Zakharov2018; Rogov, Reference Rogov2020, Reference Rogov2021). Furthermore, on the Russian Platform and in the Subpolar Urals other Boreal taxa, such as Shulginites and Chetaites chetae (especially common east of the Subpolar Urals) occur, providing direct correlation of the English Lamplughi Zone with the Russian Singularis and Chetae zones.

Subsequently, Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1987, Reference Casey, Mesezhnikov and Shul’gina1988) and Hoedemaeker & Herngreen (Reference Hoedemaeker and Herngreen2003) introduced one more unit above the Lamplughi Zone but below the base of the Ryazanian in NW Europe. The first authors proposed the ‘beds with Subcraspedites claxbiensis’ on the base of the occurrence of their index species in re-deposited pebbles from the basal Albian. However, Casey (Reference Casey, Casey and Rawson1973) and later Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1988) also mentioned this species from the Preplicomphalus Zone and a younger age (occurrence in the Lamplughi Zone) of this taxon cannot be negated. Hoedemaeker & Herngreen (Reference Hoedemaeker and Herngreen2003) indicated an assemblage with ‘Subcraspedites spp.’ above the Lamplughi Zone in the North Sea region, following Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1987) and additionally based on the ammonite data published by Abbink et al. (Reference Abbink, Callomon, Riding, Williams and Wolfard2001b; but see reinterpretation of several species by Kiselev et al., Reference Kiselev, Rogov and Zakharov2018, p. 220).

The base of the Ryazanian was defined by Casey (Reference Casey, Casey and Rawson1973) as to coincide with the transition from beds with Volgidiscus to Praetollia (Runctonia), that is, at the boundary of the Lamplughi and Runctoni zones. Casey regarded these genera as members of a single lineage SwinnertoniaSubcraspeditesVolgidiscusRunctoniaHectoroceras, providing a solid background for both the subdivision and the correlation of the late Volgian and early Ryazanian throughout the Boreal areas. At first, Casey designated Runctonia as a separate genus, but later, based on the opinion of Shul’gina, considered it a subgenus of Praetollia (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1977), and additionally figured Praetollia (Runctonia) from the Subpolar Urals (loc. cit., pl. II, fig. 3). Here, P. (Runctonia) co-occurs with Chetaites sibiricus, a typical lowermost Ryazanian species. The ammonite assemblage of the Runctoni Zone of NW Europe also includes Praesurites (considered a junior synonym of Praetollia by Igolnikov, Reference Igolnikov2019), an ammonite genus whose first occurrence marks the base of the Ryazanian in the Subpolar Urals (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1988). The lower and upper boundaries of the Runctoni Zone can be traced throughout the Boreal areas, defined by first and last occurrences of distinct common and short-ranging ammonite genera. In addition to the last occurrences of Volgidiscus and Subcraspedites, the lower boundary of this zone is marked by the first occurrence of Praetollia, while the upper boundary coincides with the appearance of Hectoroceras.

The genus Shulginites first appears in the latest Volgian and typically occurs in the lowermost zone of the Ryazanian in Western Siberia, in the Subpolar Urals and on the Russian Platform (cf. Mitta, Reference Mitta2017, p. 143–144; the upper part, bed 5b, of section A along the Unzha river were it yields Shulginites and Praesurites, herein considered as a typical earliest Ryazanian taxa). However, in the Subpolar Urals, the uppermost occurrence of this genus is in the lower part of the overlying Kochi Zone (Mesezhnikov et al., Reference Mesezhnikov, Alekseev, Klimova, Shul’gina, Gyul’khadzhan, Zakharov and Nal’nyaeva1983). Shulginites appears to be restricted to the uppermost upper Volgian, lower part of the Rjasanensis Zone and the Kochi Zone, while Hectoroceras seems to be confined to the Kochi and the Transfigurabilis zones (sensu Baraboshkin, Reference Baraboshkin2004). Mesezhnikov et al. (Reference Mesezhnikov, Alekseev, Klimova, Shul’gina, Gyul’khadzhan, Zakharov and Nal’nyaeva1983, pl. VI, fig. 4) figured a typical Shulginites characterised by weak ribbing from the lower (but not basal) part of the Ryazanian. The underlying bed contains Riasanites and Garniericeras. However, this bed is thought to contain a reworked and re-deposited assemblage (Sasonova & Sasonov, Reference Sasonova and Sasonov1984). Based on this record and the re-interpretation of Hectoroceras from the Subpolar Urals figured in Mesezhnikov et al. (Reference Mesezhnikov, Alekseev, Klimova, Shul’gina, Gyul’khadzhan, Zakharov and Nal’nyaeva1983, pl. V, fig. 3) as Shulginites (see Mitta, Reference Mitta2019), Mitta considers Shulginites as synonym of Hectoroceras. At present, we consider Shulginites and Hectoroceras as separate genera, but transitional morphologies from one genus to another as well as a potential co-occurrence of the two genera should be further investigated. Both on the Russian Platform and in the Subpolar Urals, the range of Shulginites seems to be similar. The oldest findings of this genus co-occur with Volgidiscus (Kiselev et al., Reference Kiselev, Rogov and Zakharov2018, pl. II, fig. 7). Above Shulginites is recorded from the lowermost Ryazanian pre-Rjasanensis beds (Kiselev et al., Reference Kiselev, Rogov and Zakharov2018, pl. VI, fig. 8), as well as from the Rjasanensis Zone in association with Hectoroceras (Mesezhnikov et al., Reference Mesezhnikov, Gol’bert, Zakharov, Klimova, Kravets, Saks, Shul’gina, Alekseev, Bulynnikova, Kuzina and Yakovleva1979, pl. I, fig. 5).

The Kochi Zone is defined as the range zone of the genus Hectoroceras s.str. and is among the best correlated intervals within the Ryazanian. Hectoroceras is characterised by a wide geographical range and its remarkable morphologic features permit to determine even fragmentary and/or crushed specimens. The additional components of the ammonite assemblages in this zone vary and include Borealites in NW Europe, Surites, Pseudocraspedites and Runctonia in Northern Siberia, and Submediterranean taxa in the corresponding interval on the Russian Platform, which is traditionally referred to as the Rjasanensis Zone (Mitta, Reference Mitta2019, Reference Mitta2021).

The index species of the overlying Icenii Zone in NW Europe is an endemic species, which previously was only known from its type locality and a few adjacent sections, and L. icenii is the only ammonite species figured from this zone. As a result, the correlation of this zone with other regions was mainly based on the positions of the underlying and overlying units. Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1977, Reference Casey, Mesezhnikov and Shul’gina1987, Reference Casey, Mesezhnikov and Shul’gina1988) mentioned also ‘Surites ex gr. spasskensis’ and Bojarkia from this zone. However, as has been emphasised above, Bojarkia was only mentioned from a condensed level at the boundary with the overlying zone from Lincolnshire, and the in situ co-existence of Surites and Bojarkia still cannot be confirmed. By its relative position, this zone corresponds to the ‘Analogus’ Zone of Northern Siberia as well as the Spasskensis and the lower part of Tzikwinianus zones of the Russian Platform.

The Siberian ‘Analogus Zone’ is mentioned in quotes, as the index species is taxonomically instable and needs revision. At least some ammonites referred by Shul’gina to S. analogus were later described as the new species S. subanalogus (Shul’gina, Reference Shul’gina1972), and few specimens were figured as ‘S. ex gr. analogus’. Also, it should be noted that S. analogus is an insufficiently known species as after its first description by Bogoslowsky (Reference Bogoslowsky1896) it was not figured again from the type region. Moreover each specimen figured by him was proposed as lectotype subsequently by Sazonova (Reference Sazonova1971, p. 45 – Bogoslowsky, Reference Bogoslowsky1896, pl. III, fig. 6, indicated as a variety loc. cit. p. 67) and Shul’gina (Reference Shul’gina1972, p. 153 – Bogoslowsky, Reference Bogoslowsky1896, pl. III, fig. 5), while another specimen figured by Bogoslowsky was referred to S. subanalogus.

The ‘Analogus Zone’ of northern Siberia is at its base defined by the highest appearance datum of Hectoroceras and in its top by the first appearance datum of Bojarkia and disappearance of Surites (Alekseev, Reference Alekseev1984; Baraboshkin, Reference Baraboshkin2004). It is well-traceable throughout the Panboreal Superrealm. This zone has been introduced by Shul’gina (in Sachs & Shul’gina, Reference Saks and Shul’gina1962) as ‘Paracraspedites analogus subzone’. Subsequently, she provided some information about the ammonite assemblage of this unit (in Saks and Shul’gina Reference Saks and Shul’gina1962), which included various ‘Paracraspedites’ (i.e. Surites), among others P. analogus subsp. nov. Subsequently, this taxon was described as Surites subanalogus sp. nov. (Shul’gina, Reference Shul’gina1972), while S. analogus was mentioned and described in open nomenclature only (i.e. Surites ex gr. analogus, loc. cit., pl. XIII, figs 1–2; Igolnikov, Reference Igolnikov2019, pl. XIII, fig. 2) and any evidence for the presence of S. analogus outside the Russian Platform is still missing. Moreover, to emphasise the difference between S. analogus from the Russian Platform and S. ex gr. analogus we added ‘Shul’gina, Reference Shul’gina1972’ as an author of the latter binomen, though strictly speaking it was not introduced as a new species (group).

The Stenomphala Zone of Casey (Reference Casey, Casey and Rawson1973) is characterised by a mix of ammonites which includes both Bojarkia and Surites (at least in the lower part). Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1977, p. 23) re-assigned ‘Bojarkiatealli (Casey) to the genus Surites (Casey, Reference Casey, Casey and Rawson1973 considered Bojarkia as a subgenus of Surites) and additionally mentioned a finding of an unfigured Surites aff. caseyi (Sazonova) close to the top of this zone (bed 12, Stenomphala Zone of Mintlyn Wood section). Later, the same authors (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1988) restricted the ranges of Surites s.str. and Lynnia to the Icenii Zone, while only Bojarkia was shown from the Stenomphala Zone. Thus, the co-existence of Surites and Bojarkia still should be further clarified and cannot be proven. Roughly, this interval corresponds at least partially to the Tzikwinianus Zone of the Russian Platform (a condensed sequence). As a result, the precise ranges of the ammonites are unclear in this zone, but it yields Surites, Bojarkia and Peregrinoceras (in its upper part only). Because it is based on the range of the genus Bojarkia, this zone corresponds to the lower part of the expanded Mesezhnikowi Zone of Northern Siberia.

The assemblage of the Albidum Zone, also defined by Casey (Reference Casey, Casey and Rawson1973), contains Peregrinoceras spp. with the addition of Bojarkia in the lower part of this zone. This can be concluded from data presented in Casey, Reference Casey, Casey and Rawson1973, although later Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1987, Reference Casey, Mesezhnikov and Shul’gina1988) show the range of Bojarkia covering the whole of that zone. Such co-occurrence of Peregrinoceras and Bojarkia was also mentioned from the Tzikwinianus Zone of the Russian Platform. Eventually, the occurrence of P. aff. albidum (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1977, p. 32, pl. I, fig. 1) in the latter region leads to the establishment of the ‘P. albidum beds’ (Casey et al., Reference Casey, Mesezhnikov and Shul’gina1988) and P. albidum Zone (Baraboshkin in Rogov et al., Reference Rogov, Baraboshkin, Guzhikov, Efimov, Kiselev, Morov and Gusev2015). However, although the Peregrinoceras-bearing interval can be recognised in the topmost part of the Russian Platform, its direct comparison with the Albidum Zone of England remains doubtful and needs further clarification. Apparently, the total range of the genus Peregrinoceras in the Russian Platform exceeds its range in NW Europe. On the Russian Platform, the oldest findings of Peregrinoceras co-occur with Surites and Riasanites (Mesezhnikov, Reference Mesezhnikov and Menner1984; Casey et al., Reference Casey, Mesezhnikov and Shul’gina1988). Currently, the occurrence of an assemblage consisting of Peregrinoceras or of Peregrinoceras with additionally Bojarkia is confirmed for condensed sections of the Middle Volga area only (Rogov et al., Reference Rogov, Baraboshkin, Guzhikov, Efimov, Kiselev, Morov and Gusev2015). But information concerning the ammonite ranges in the uppermost Ryazanian is limited. Hence, correlation of the Albidum Zone with other Boreal successions is only possible through indirect evidence based on finding of Bojarkia in its lower part.

The overlying part of the Lower Cretaceous succession in England was referred by Casey to the Paratollia beds or Paratollia horizon (Casey, Reference Casey, Casey and Rawson1973; Casey et al., Reference Casey, Mesezhnikov and Shul’gina1987, Reference Casey, Mesezhnikov and Shul’gina1988) but is separated by a minor fault in the Lincolnshire area. This unit is characterised by the occurrence of Paratollia, Delphinites (= Pseudogarnieria (‘Proleopoldia’) of Casey, Reference Casey, Casey and Rawson1973), Propolyptychites and Menjaites (Casey, Reference Casey, Casey and Rawson1973; Casey et al., Reference Casey, Mesezhnikov and Shul’gina1977). The presence of Peregrinoceras in this zone has been shown by Casey et al. (Reference Casey, Mesezhnikov and Shul’gina1988, fig. 4) but was not mentioned elsewhere, and there is no evidence to corroborate. Approximately this unit corresponds to the Undulatoplicatilis Zone of the Russian Platform, which also yields a Delphinites – Menjaites assemblage. In Siberia, it can be correlated with the Tolli Zone, as a rich assemblage with Tollia has been found in the Undulatoplicatilis Zone of the Russian Platform (Bogomolov et al., Reference Bogomolov, Mitta and Starodubtseva2011). However, the age of the top of the Paratollia unit and its correlation with other Boreal succession is unclear.

Depositional setting

The bituminous mudrocks (Clay Deep Member) of the Lutine Formation were likely deposited under the influence of ‘temporarily stagnated circulation, at least in the deeper parts of the graben, which resulted in partially dysaerobic basin-floor conditions. In the relatively shallower settings, mixing prevailed with normal basin-floor ventilation (Schill Grund Member)’ (Munsterman et al., Reference Munsterman, Verreussel, Mijnlief, Witmans, Kerstholt-Boegehold and Abbink2012, p. 585–586).

The core B18-02 yields benthic-nektonic cephalopods, fish remains and their waste products (pyritised coprolite; Image 2). Buchia bivalves occur throughout the core (Image 2), sometimes in abundance. Buchiids lived as epifauna, byssally attached suspension feeders (Zakharov, Reference Zakharov1981, fig. 78; Fürsich, Reference Fürsich1984, fig. 26; Hryniewicz et al., Reference Hryniewicz, Little and Nakrem2014). The single limid bivalve recorded, Pseudolimea cf. arctica (Zakharov, Reference Zakharov1966) (Pl. 1, Fig. 14) was also a byssally attached suspension feeder. All these fossils indicate oxic-marine waters, eventually above an ephemeral oxygen-restricted zone just above the water/sediment interface but never in or reaching the photic zone as vegetative cysts of prasinophytes are very few only. Buchiids, like all non-chemosymbiotic bivalve taxa, required some oxygen to thrive, thus their (abundant) occurrence excludes anoxic conditions. However, anoxic or dysoxic conditions prevailed in the sediment as the presence of infauna, indicated by bioturbation, appears to be absent but for some minor perpendicular structures between 2248.20 and 2250.18 m (Image 2).

Paleo(bio)geography

The investigated and cited boreholes were all located in an area south of 40°N paleo-latitude (Mutterlose et al., Reference Mutterlose, Brumsack, Flögel, Hay, Klein, Langrock, Lipinski, Ricken, Söding, Stein and Swientek2003). The North Sea area was connected through the southern Viking Graben to the Greenland-Norwegian seaway (Image 6). From the middle Volgian towards the late Ryazanian, alternating dysoxic to anoxic bottom conditions prevailed in the southern Viking Graben as suggested by trace element concentrations and foraminiferal assemblages (Mutterlose et al., Reference Mutterlose, Brumsack, Flögel, Hay, Klein, Langrock, Lipinski, Ricken, Söding, Stein and Swientek2003). North of the southern Viking Graben and certainly in the basins bordering the Arctic Ocean buchiids were diverse and abundant, but they were apparently rare in the North Sea area and totally absent during the late Volgian (Image 4). Very few Ryazanian occurrences of Buchia are recorded in NW Europe. More common and diverse, buchiid faunas are encountered along the Norwegian coast (Lofoten Islands, Birkelund et al., Reference Birkelund, Thusu and Vigran1978; Zakharov et al., Reference Zakharov, Surlyk and Dalland1981; Århus et al., Reference Århus, Kelly, Collins and Sandy1990), the Barents Sea (Smelror et al., Reference Smelror, Kelly, Dypvik, Mørk, Nagy and Tsikalas2001, fig. 5), the east coast of Greenland (Håkansson et al., Reference Håkansson, Birkelund, Piasecki and Zakharov1981; Surlyk & Zakharov, Reference Surlyk and Zakharov1982), Svalbard (Frebold, Reference Frebold1930; Sokolov & Bodylevski, Reference Sokolov and Bodylevski1931; Ershova, Reference Ershova1983) and on the Russian Platform (part of the East European Province) (Sazonova, Reference Sazonova1975; Zakharov, Reference Zakharov1987; Urman et al., Reference Urman, Shurygin and Dzyuba2019; Fig. 4). Only in the uppermost Volgian Singularis Zone buchiids are missing on the Russian Platform (Kiselev et al., Reference Kiselev, Rogov and Zakharov2018, p. 231), as well as in contemporary strata of the Subpolar Urals (Dzyuba et al., Reference Dzyuba, Pestchevitskaya, Urman, Shurygin, Alifirov, Igolnikov and Kosenko2018). All in all, compared to the before mentioned areas and especially northern Siberia and Canada (see Zakharov, Reference Zakharov1987, p. 144–145; Grey, Reference Grey2009, fig. 5.2), the West European Province or Boreal-Atlantic Province appears to lack any or any diversified buchiid fauna.

Image 6. Paleogeographic reconstruction of North Sea area modified after Abbink et al. (Reference Abbink, Targarona, Brinkhuis and Visscher2001a, 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.

The absence of a diverse buchiid fauna in this region is in contrast with the similarity between the ammonite faunas of West European Province and those of other Boreal areas. Since the latest late Volgian and throughout the Ryazanian, Boreal ammonites were mainly represented by the same genera and closely allied species throughout the Panboreal Superrealm. Although in the West European Province some endemic ammonite taxa are known (e.g. Lynnia), the other ammonites here are belonging to genera and species which occur in other Boreal regions (e.g. Hectoroceras kochi, Peregrinoceras spp., Surites spp., and Bojarkia spp.). This faunal homogeneity appears at least since the latest Volgian, when Volgidiscus lamplughi and V. pulcher dispersed through this huge area, from NW Europe to the Barents Sea shelf, the Russian Platform, the Subpolar Urals and Northern Siberia (Rogov, Reference Rogov2020).

The low diversity of buchiid bivalves and their overall rarity in the West European Province during the Ryazanian cannot be explained by paleogeographic restrictions alone. In contrast to ammonites, bivalves strongly depend on the configuration of the paleo-currents and the presence of a proper substrate for juvenile settling. Taking into account the common presence of TOC-enriched oxygen-depleted bottom settings throughout the Greenland-Norwegian seaway (northern Viking Graben; Image 6) during the Volgian and Ryazanian (Mutterlose et al., Reference Mutterlose, Brumsack, Flögel, Hay, Klein, Langrock, Lipinski, Ricken, Söding, Stein and Swientek2003), southward migrations of bivalves were recurrently hampered, in the southern Viking Graben. Especially during the late(st) Volgian, when oxygen depletion was highest.

The abundant occurrence of B. volgensis in the late Ryazanian of the region under discussion points to higher tolerance of this species to normally unfavourable environments, an opportunistic taxon, which is further evidenced by its wide geographic range outside the Panboreal Superrealm, as it is known from Submediterranean regions, like the Crimea, Mangyshlak and Mexico (see Zakharov, Reference Zakharov2015).

During the latest Jurassic-earliest Cretaceous, the (low)lands bordering the mid-latitudinal West European Province (marine realm) were characterised by a warm and arid climate (Hallam et al., Reference Hallam, Grose and Ruffell1991; Abbink, Reference Abbink1998; Turner, Reference Turner2018). The relatively shallow basins that occurred at high to mid northern latitudes were all connected to the Arctic area while some east-west connections, having been closed during latest Volgian to early Ryazanian at mid-latitudes, started to open in the late(st) Ryazanian (Image 6). These basins share the accumulation of organic-rich mudstones, for example, the hot and warm shales of the North Sea area, the Bazhenov facies of the Siberian Basin, with onset of deposition in the Kimmeridgian, accumulating rapidly in the Volgian and waning in the Ryazanian (Rogov et al., Reference Rogov, Shchepetova and Zakharov2020, fig. 2).

According to Sinclair (Reference Sinclair1994, p. 195), the approximate top (at least Icenii age) of the highly organic, condensed shales of the ‘hot shale’ facies can be considered the uppermost maximum flooding surface which developed prior to a subsequent increase in clastic input. This level is based on the last occurrence of abundant amorphous organic matter (Stenomphala Zone, according to Fraser et al., Reference Fraser, Robinson, Johnson, Underhill, Kadolsky, Connel, Johannessen, Ravnås, Evans, Graham, Armour and Bathorst2003, p. 165), but more recently placed in the Albidum Zone (Verreussel et al., Reference Verreussel, Bouroullec, Munsterman, Dybkjær, Geel, Houben, Johannessen and Kerstholt-Boeghold2018, figs 2, 15), that is, latest Ryazanian and possibly into the earliest Valanginian. It is regarded as the first indication of the occurrence of micro-fossils with Cretaceous (i.e. Valanginian) affinity, hence ‘Cretaceous flooding’.

It coincides with the influx of Tethyan taxa at high latitudes, indicated in the latest Ryazanian and earliest Valanginian (Möller et al., Reference Möller, Mutterlose and Alsen2015). Previously, this event was believed to have happened earlier in the Ryazanian (Mutterlose et al., Reference Mutterlose, Brumsack, Flögel, Hay, Klein, Langrock, Lipinski, Ricken, Söding, Stein and Swientek2003; Alsen & Mutterlose, Reference Alsen and Mutterlose2009; Pauly et al., Reference Pauly, Mutterlose and Alsen2012, Reference Pauly, Mutterlose and Alsen2013). From that time on, more calcareous, low organic, sediments occur temporarily.

In the late Ryazanian, the North Sea area was bordered to the south, stretching into parts of France, Belgium, the Netherlands, Germany and Poland, by continental to very shallow marine Wealden facies, restricting eventual connections to the south, south-west and east (Image 6). Marine influence on the continental Wealden facies increased and became dominant in the latest Ryazanian to earliest Valanginian, as large parts of the Wealden deposits were overlain by fully marine sediments, especially in the Lower Saxony Basin to the south-east and the Vomb Trough, the western most extension of the Polish Strait, to the east. Farther to the east, fully marine conditions were already established in Kochi Zone-time or slightly earlier, when Tethyan ammonites occur on the Russian Platform (Mitta, Reference Mitta2017; Grabowski et al., Reference Grabowski, Chmielewski, Ploch, Rogov, Smoleń, Wójcik-Tabol, Leszczyński and Maj-Szeliga2021). Contemporaneous sediments were then still marginally marine to continental towards the North West European Province, with only occasional flooding surfaces evidencing marine influence (Schneider et al., Reference Schneider, Heimhofer, Heunisch and Mutterlose2018, fig. 2).

Connections to the southeast along the Polish Strait, lows superimposed on the Sorgenfrei-Tornquist Zone (see e.g. maps envisaged by Kelly, Reference Kelly1990, p. 144), connecting either the Russian Plain and/or the Tethys with the West European province, were established around the transition from the early to the late Valanginian, perhaps as early as the latest Ryazanian-earliest Valanginian. A further possible connection towards the south is south of the Market Weighton High (Image 1) during the earliest Ryazanian (see Abbink, Reference Abbink1998, p. 136; Abbink et al., Reference Abbink, Targarona, Brinkhuis and Visscher2001a, fig. 15) but was definitely closed during the late Ryazanian when Wealden facies was deposited.

Marginal or proximal marine facies often include abundant continentally derived organic matter, in part as pollen and spores. A climate shift was postulated based on a sudden decline in the abundance of Classopollis (Abbink, Reference Abbink1998; Abbink et al., Reference Abbink, Targarona, Brinkhuis and Visscher2001a, Reference Abbink, Mijnlieff, Munsterman and Verreussel2006, fig. 6). This so-called Kochi climate shift occurs in the Kochi Zone just below J76. It is also called the Kochi flooding of Partington et al. (Reference Partington, Copestake, Mitchener and Underhill1993) and marks the transition from a warm and arid climate (cf. Hallam et al., Reference Hallam, Grose and Ruffell1991; Turner, Reference Turner2018) to a tropical wet climate. The sudden decrease in Classopollis in favour of Gleicheniaceae is well recorded on the Russian Platform (Fedorova & Gryazeva, Reference Fedorova and Gryazeva1984, tab. 1, p. 154) as well as in the Laptev Sea (northern Siberia) (Kashirtsev et al., Reference Kashirtsev, Nikitenko, Peshchevitskaya and Fursenko2018, fig. 2; approximately between their members 12 and 13). In the Ryazanian sediments of the Laptev Sea, though Classopollis is overall sparsely represented, but fern spores indicating tropical wet conditions increase in abundance. Nevertheless, Lindström & Ekström (Reference Lindström and Ekström2011) and Schneider et al. (Reference Schneider, Heimhofer, Heunisch and Mutterlose2018, fig. 2) indicate Classopollis to diminish already in the top of the Lamplughi Zone in the Cherty Freshwater Beds. Hoedemaeker (Reference Hoedemaker1999) and Hoedemaeker & Herngreen (Reference Hoedemaeker and Herngreen2003, Reference Hoedemaker and Herngreen2004) date these Purbeckian cherty beds between the Lamplughi and Runctoni flooding surfaces though.

Based on paleogeographic reconstructions, a marine passage has been inferred between the Shetland area and the south of Greenland (Laughton, Reference Laughton1975, p. 179, fig. 3; Ziegler, Reference Ziegler1988; Roberts et al., Reference Roberts, Thompson, Mitchener, Hossack, Carmichael and Bjørnseth1999, figs 14–15). However, recent research does not provide strong evidence for this NE Atlantic rift system, at least not before the Early Cretaceous (Stoker et al., Reference Stoker, Stewart, Shannon, Bjerager, Nielsen, Blischke, Hjelstuen, Gaina, McDermott and Ólavsdóttir2017, p. 57–58). The latter age is demonstrated, as throughout the Viking Graben, up to the Norwegian-Greenland seaway Tethyan calcareous microfossils (Nannoconus) have been observed. They occur regularly in the late(st) Ryazanian to the earliest Valanginian at high latitudes, 55ºN palaeolatitude (Århus et al., Reference Århus, Verdenius and Birkelund1986; Jeremiah, Reference Jeremiah2001; Pauly et al., Reference Pauly, Mutterlose and Alsen2013; Möller et al., Reference Möller, Mutterlose and Alsen2015) but probably not before the Albidum Chron (Jeremiah, Reference Jeremiah2001; Möller et al., Reference Möller, Mutterlose and Alsen2015, fig. 3).

In the latter context, it should be noted that for instance in North-East Greenland the underlying organic-rich mudstones of the Bernbjerg Formation are generally indicated to be Volgian or older (Alsgaard et al., Reference Alsgaard, Felt, Vosgerau and Surlyk2003; Piasecki et al., Reference Piasecki, Callomon and Stemmerik2004). However, these beds were considered to be of Late Jurassic-earliest Cretaceous age by Pauly et al. (Reference Pauly, Mutterlose and Alsen2012, Reference Pauly, Mutterlose and Alsen2013) and are coeval to the Upper Jurassic source rock of the mid-Norwegian shelf and the Barents Sea (Alsgaard et al., Reference Alsgaard, Felt, Vosgerau and Surlyk2003). Apparently, the top of the Bernbjerg Formation can be strongly diachronous partially being as young as the Ryazanian. Recent biostratigraphical research (Piasecki et al., Reference Piasecki, Bojesen-Koefoed and Alsen2020) revealed two different formations, that is, the Bernbjerg Formation of Oxfordian-Kimmeridgian age and the Stratumbjerg Formation of latest Hauterivian-Albian age, which are virtually impossible to separate from a lithological point of view. However, the latter formation is much younger as compared to the strata dealt with herein.

Thus, either there is a significant hiatus, or Nannoconus are not preserved in the organic-rich facies, or indeed not present. If so, it is likely to assume that the (sudden) Nannoconus influx arrived with what is commonly referred to as the ‘Stenomphala flooding’ (K10 of Partington et al. (Reference Partington, Copestake, Mitchener and Underhill1993) and or ‘Paratollia flooding’ (K15 of Partington et al. (Reference Partington, Copestake, Mitchener and Underhill1993), that is, that is after the Icenii Chron. Along the northeast coast of Greenland, the Ryazanian-Valanginian deposits yield additionally Tethyan cephalopods (belemnites like Pseudobelus and Duvalia; Alsen & Mutterlose, Reference Alsen and Mutterlose2009; Mutterlose et al., Reference Mutterlose, Alsen, Iba and Schneider2020) and brachiopods (e.g. Pygope; Ager & Walley, Reference Ager and Walley1977; Sandy, Reference Sandy1991; Harper et al., Reference Harper, Alsen, Owen and Sandy2005), along with relatively frequent ammonites of oceanic type, such as Lytoceras and Ptychophylloceras (Alsen, Reference Alsen2006), which invaded this area from the south (Mutterlose et al., Reference Mutterlose, Alsen, Iba and Schneider2020). All in all, the arrival of these typical Tethyan micro- and macrofossils can only be explained by a connection between the Tethys and the Boreal via the so-called Atlantic route (Image 6).

Swientek (Reference Swientek2002), Mutterlose et al. (Reference Mutterlose, Brumsack, Flögel, Hay, Klein, Langrock, Lipinski, Ricken, Söding, Stein and Swientek2003), Alsen (Reference Alsen2006), Pauly et al. (Reference Pauly, Mutterlose and Alsen2012, Reference Pauly, Mutterlose and Alsen2013) and Möller et al. (Reference Möller, Mutterlose and Alsen2015) argued that high meridional temperature gradients and cool-cold climatic conditions in high latitudes caused the formation of (cold) deep water in the South Anyui Gulf (Arctic) in the late Ryazanian-Valanginian and palaeoceanographic changes, reflected in a counter-balanced ocean current system in the Greenland-Norwegian Seaway and allowed Tethyan biota to spread as far north as North-East Greenland during the late Ryazanian and early Valanginian. Simultaneously, with incoming Tethyan waters, the accumulation of calcareous sediments at high latitudes relates to an important influx of calcareous nannofossils into the Greenland-Norwegian Seaway, exhibiting an influx of Tethyan and low-to-mid latitudinal taxa, synchronous with observed influxes of Tethyan ammonite and belemnite species (Pauly et al., Reference Pauly, Mutterlose and Alsen2013). However, the northward extension of this warm-water fauna was mainly restricted to East Greenland and adjacent areas of the Greenland-Norwegian seaway. North of this area only a single record of Lytoceras is known to date from the Valanginian of Spitsbergen (Frebold & Stoll, Reference Frebold and Stoll1937, p. 52). During the (late) Valanginian, the Tethyan influence became stronger and caused the occurrence of a specific ‘warm-water foraminiferal assemblage’ in the Russian part of the Barents Sea shelf (Basov & Vasilenko, Reference Basov and Vasilenko1999).

These influxes suggest the occurrence of northward flowing warmer, less saline surface currents in the Norwegian-Greenland seaway (northern Viking Graben), which allowed Tethyan nekton and plankton to spread even as far north as North-East Greenland at 55°N palaeolatitude (Pauly et al., Reference Pauly, Mutterlose and Alsen2013; Möller et al., Reference Möller, Mutterlose and Alsen2015; Mutterlose et al., Reference Mutterlose, Alsen, Iba and Schneider2020) and further north-east, but also suggest these surface currents to flow south-ward through the (southern extension of the) Viking Graben, to approximately 35–40°N, ‘piggy backing’ the normal colder north-south currents, enabled – to some extent – the exchange of cephalopods and bivalves (Image 6). Perhaps connections with a strong north-south component (Image 6) existed already temporarily, because of the general similarity between some ammonite assemblages described from the West European Province and other Boreal provinces. However, during these times, the southern connections, as envisaged by Kelly (Reference Kelly1990, p. 144), were seriously hampered.

Conclusions

This work contributes to the stratigraphy of the Ryazanian (Berriasian) in general, and to the early and late Ryazanian Kochi and Icenii zones in particular. Key macrofossils, especially ammonites (Lynnia, Surites) and buchiids (Buchia volgensis), are for the first time mentioned from the offshore of the Netherlands (cores B18-02 and L06-02) and Norway (core 7/7-2). Their abundances, paleo(bio)geography and depositional context are further discussed. This work is summarised as follows.

  1. 1. The monospecific abundance of Buchia volgensis is explained by higher tolerance of this species to fluctuating oxygen levels, but probably to a lesser degree temperature. In all probably it is an opportunistic taxon.

  2. 2. Ammonite assemblages have typical Boreal composition with common Surites and few Lynnia. Lynnia is for the first time reported outside its type locality. The finding of a potentially juvenile Praetollia indicates the last occurrence of this taxon in the lower part of the Icenii Zone.

  3. 3. Dispersal of the herein mentioned Boreal macrofossils strongly favours arrival through the Viking Graben. Nonetheless, the provincial character is a pristine feature, based on the low diversity and relative abundance of endemic taxa, and is thought to relate to the oxygen-depletion in the relative shallow and narrow Viking Graben, apart from southern restrictions due to low sea-levels.

  4. 4. During the latest Volgian-earliest Ryazanian (pre-Kochi time) isolation of the North Sea Basin towards the south was at its peak. Therefore, the presence of Volgidiscus (indicating the Lamplughi Zone) in the North Sea area on the one hand, and on the other on the Russian Platform, in the Subpolar Urals and northern Siberia, must indicate a connection between these areas via the southern Viking Strait.

  5. 5. No buchiids are known from the Late Volgian to Ryazanian in the Lower Saxony Basin and Polish Strait, further strengthening the arrival of Boreal macrofossils through the southern Viking Strait. In the latest Ryazanian, only a shallow water connection existed in the south-eastern part of the West-European Province.

  6. 6. The initial Tethyan influx of nannoplankton (from literature data) postdates the Icenii Zone and is related to the Stenomphala flooding (K10) that includes latest Ryazanian (Stenomphala-Albidum zones) but possibly also earliest Valanginian sediments.

Acknowledgements

The authors thank Richard Porter (NAM; Nederlandse Aardolie Maatschappij) for giving access to the core and permission of publication of the fossils from B18-02. We are indebted to Jorn Hurum (Natural History Museum, Oslo) for providing access to the Christensen collection and for further information concerning specimens from Statoil well 7/7-2. Mikhail Rogov and Viktor Zakharov acknowledge the support of the Geological Institute of RAS to this work. We greatly acknowledge the constructive reviews of Simon Schneider and Peter Alsen. Their kind efforts significantly improved both the language and the original structure of this manuscript. Most of the papers mentioned herein can be accessed through www.jurassic.ru

References

References

Århus, N., Verdenius, J. & Birkelund, T., 1986. Biostratigraphy of a Lower Cretaceous section from Sklinnabanken, Norway, with some comments on the Andøy exposure. Norsk Geologisk Tidsskrift 66: 1743.Google Scholar
Århus, N., Kelly, S.R.A., Collins, J.S.H. & Sandy, M.R., 1990. Systematic palaeontology and biostratigraphy of two Early Cretaceous condensed sections from the Barents Sea. Polar Research 8: 165194.CrossRefGoogle Scholar
Abbink, O., 1998. Palynological investigations in the Jurassic of the North Sea region. LPP Contribution Series 8: 392.Google Scholar
Abbink, O., Targarona, J., Brinkhuis, H. & Visscher, H., 2001a. Late Jurassic to earliest Cretaceous palaeoclimatic evolution of the southern North Sea. Global and Planetary Change 30: 231256.CrossRefGoogle Scholar
Abbink, O.A., Callomon, J.H., Riding, J.B., Williams, P.D.B. & Wolfard, A., 2001b. Biostratigraphy of Jurassic-Cretaceous boundary strata in the Terschelling Basin, The Netherlands. Proceedings of the Yorkshire Geological Society 53: 275302.CrossRefGoogle Scholar
Abbink, O.A., Mijnlieff, H.F., Munsterman, D.K. & Verreussel, R.M.C.H., 2006. New stratigraphic insights in the ‘Late Jurassic’ of the Southern Central North Sea Graben and Terschelling Basin (Dutch Offshore) and related exploration potential. Netherlands Journal of Geosciences 85: 221238.Google Scholar
Ager, D.V. & Walley, C.D., 1977. Mesozoic brachiopod migrations and the opening of the North Atlantic. Palaeogeography, Palaeoclimatology, Palaeoecology 21: 8599.CrossRefGoogle Scholar
Alekseev, S.N., 1984. New data on the zonal subdivision of the Berriasian Stage in the north of Siberia. Transactions of the Institute of Geology and Geophysics 644: 1827 [in Russian].Google Scholar
Alsen, P., 2006. The Early Cretaceous (Late Ryazanian – Early Hauterivian) ammonite fauna of North-East Greenland: taxonomy, biostratigraphy, and biogeography. Fossils and Strata 53: 1229.Google Scholar
Alsen, P. & Mutterlose, J., 2009. The Early Cretaceous of North-east Greenland: A crossroads of belemnite migration. Palaeogeography, Palaeoclimatology, Palaeoecology 280: 168182.CrossRefGoogle Scholar
Alsgaard, P.C., Felt, V.C, Vosgerau, H. & Surlyk, F., 2003. The Jurassic of Kuhn Ø, North-East Greenland. Geological Survey of Denmark and Greenland Bulletin 1: 865892.CrossRefGoogle Scholar
Andsbjerg, J. & Dybkjær, K., 2003. Sequence stratigraphy of the Jurassic of the Danish Central Graben. Geological Survey of Denmark and Greenland Bulletin 1: 265300.Google Scholar
Arfai, J., Jähne, F., Lutz, R., Franke, D., Gaedicke, Ch. & Kley, J., 2014. Late Palaeozoic to Early Cenozoic geological evolution of the northwestern German North Sea (Entenschnabel): New results and insights. Netherlands Journal of Geosciences 93: 147174.CrossRefGoogle Scholar
Arfai, J. & Lutz, R., 2018. 3D basin and petroleum system modelling of the NW German North Sea (Entenschnabel). In: Bowman, M. & Levell, B. (eds): Petroleum Geology of NW Europe: 50 Years of Learning. Proceedings of the 8th Petroleum Geology Conference: 67–86.CrossRefGoogle Scholar
Baraboshkin, E.J., 2004. The Lower Cretaceous ammonite zonal standard of the Boreal Realm. Bulletin of the Society of Naturalists of Moscow (geology) 79: 4468 (in Russian).Google Scholar
Basov, V.A. & Vasilenko, L.V., 1999. Horizon with thermophilic foraminifers in sections of the Lower Cretaceous of the Barents shelf. In: Problems of the Mesozoic stratigraphy and palaeontology. Lecturing in memory of M.S. Mesezhnikov. (VNIGRI) Saint-Petersburg: 131–150 (in Russian).Google Scholar
Birkelund, T., Thusu, B. & Vigran, J., 1978. Jurassic-Cretaceous biostratigraphy of Norway, with comments on the British Rasenia cymodoce Zone. Palaeontology 21: 3163.Google Scholar
Birkelund, T., Clausen, C.K., Hansen, H.N. & Holm, L., 1983. The Hectoroceras kochi Zone (Ryazanian) in the North Sea Central Graben and remarks on the Late Cimmerian Unconformity. Danmarks Geologiske Undersøgelse Årbog 1982: 5372.Google Scholar
Bogomolov, Y.I., Mitta, V.V. & Starodubtseva, I.A., 2011. Ammonite genus Tollia in the Valanginian of Russian Platform. Paleontology, stratigraphy and paleogeography of the Mesozoic and Cenozoic of the Boreal regions, Vol. 1. Novosibirsk (IPGG SB RAS): 39–42 (in Russian).Google Scholar
Bogoslowsky, N.A., 1896. Der Rjasan-Horizont, seine Fauna, seine stratigraphischen Beziehungen und sein wahrscheinliches Alter. Materials for the Geology of Russia XVIII (for 1895): 1–136, 6 pls. (in Russian)Google Scholar
Bouroullec, R., Verreussel, R.M.C.H., Geel, C.R., de Bruin, G., Zijp, M.H.A.A., Kőrösi, D., Munsterman, D.K., Janssen, N.M.M. & Kerstholt-Boegehold, S.J., 2018. Tectonostratigraphy of a rift basin affected by salt tectonics: synrift Middle Jurassic-Lower Cretaceous Dutch Central Graben, Terschelling Basin and neighbouring platforms, Dutch offshore. In: Kilhams, B., Kukla, P.A., Mazur, S., McKie, T., Mijnlieff, H.F. & Ojik, K. van (eds.), Mesozoic Resource Potential in the Southern Permian Basin. Geological Society, London, Special Publications 469: 269–303.CrossRefGoogle Scholar
Braduchan, Y.V., Gol’bert, A.V., Gurari, F.G., Zakharov, V.A., Bulynnikova, S.P., Klimova, I.G., Mesezhnikov, M.S., Vyachkileva, N.P., Kozlova, G.E., Lebedev, A.I., Nal’nyaeva, T.I. & Turbina, A.S., 1986. Bazhenov Horizon. Western Siberia. Stratigraphy, paleogeography, ecology, oil content. Novosibirsk (Nauka Siberian Branch): 217 pp (in Russian).Google Scholar
Casey, R., 1962. The ammonites of the Spilsby Sandstone, and the Jurassic-Cretaceous boundary. Proceedings of the Geological Society of London 1962: 95100.Google Scholar
Casey, R., 1963. The dawn of the Cretaceous period in Britain. South-Eastern Union of Scientific Societies CXVII: 115.Google Scholar
Casey, R., 1973. The ammonite succession at the Jurassic-Cretaceous boundary in eastern England. In: Casey, R. & Rawson, P.F. (eds): The Boreal Lower Cretaceous. Seel House (Liverpool): 194–266.Google Scholar
Casey, R. & Gallois, R. W., 1973. The Sandringham Sands of Norfolk. Proceedings of the Yorkshire Geological Society 40: 122.CrossRefGoogle Scholar
Casey, R., Mesezhnikov, M.S. & Shul’gina, N.I., 1977. Comparison of the Jurassic and Cretaceous boundary sediments of England and the Russian Platform, Circumpolar Urals and Siberia. Geological Series 1977(7): 1433 (in Russian).Google Scholar
Casey, R., Mesezhnikov, M.S. & Shul’gina, N.I., 1987. Ammonite Zones from the Jurassic/Cretaceous boundary deposits in the Boreal Realm. Working Group on the Jurassic-Cretaceous boundary, Newsletter 8: 24+6 pp.Google Scholar
Casey, R, Mesezhnikov, M.S. & Shul’gina, N.I., 1988. Ammonite Zones from the Jurassic-Cretaceous boundary in the Boreal Realm. Geological Series 1988(10): 7184 (in Russian).Google Scholar
Clark, J.A., Cartwright, J.A. & Stewart, S.A., 1999. Mesozoic dissolution tectonics on the West Central Shelf, UK Central North Sea. Marine and Petroleum Geology 16: 283300.CrossRefGoogle Scholar
Cope, J.C.W., 2020. A review of Raymond Casey’s contribution to Jurassic stratigraphy. Proceedings of the Geologist’s Association 131: 242251.CrossRefGoogle Scholar
Dibner, V.D. & Shulgina, N.I., 1998. Cretaceous. Meddelelser Norsk Polarinstitutt 146: 6480.Google Scholar
Duin, E.J.T., Doornenbal, J.C., Rijkers, R.H.B., Verbeek, J.W. & Wong, T.E., 2006. Subsurface structure of the Netherlands – results of recent onshore and offshore mapping. Netherlands Journal of Geosciences 85: 245276.CrossRefGoogle Scholar
Duxbury, S., 2018. Berriasian to lower Hauterivian palynostratigraphy, U.K. onshore and Outer Moray Firth. Micropaleontology 64: 171252.CrossRefGoogle Scholar
Dybkjær, K., 1998. Palynological dating of the Mandal Formation (uppermost Jurassic-lowermost Cretaceous, Norwegian Central Graben) and correlation to organic-rich shales in the Danish sector. Marine and Petroleum Geology 15: 495503.CrossRefGoogle Scholar
Dzyuba, O.S., 2004. Belemnites (Cylindroteuthidae) and biostratigraphy of the Middle and Upper Jurassic of Siberia. Novosibirsk: 204 pp (in Russian).Google Scholar
Dzyuba, O.S., Pestchevitskaya, E.B., Urman, O.S., Shurygin, B.N., Alifirov, A.S., Igolnikov, A.E. & Kosenko, I.N., 2018. The Maurynya section, West Siberia: a key section of the Jurassic-Cretaceous boundary deposits of shallow marine genesis. Russian Geology and Geophysics 59: 864890.CrossRefGoogle Scholar
Ershova, E.S., 1983. Explanatory note to the biostratigraphic scheme of the Jurassic and Cretaceous deposits of the Spitsbergen archipelago. PGO Sevmorgeologiya (Leningrad): 88 pp (in Russian).Google Scholar
Fedorova, V.A. & Gryazeva, A.S., 1984. Palynostratigraphy of the boundary deposits of the Jurassic and Cretaceous at the Oka River. Akademiya nauk SSSR, Siberian branch, Geological and Geophysical Institute 644: 150160 (in Russian).Google Scholar
Feldthusen Jensen, T., Holm, L., Frandsen, N. & Michelsen, O., 1986. Jurassic – Lower Cretaceous lithostratigraphic nomenclature for the Danish Central Trough. Danmarks Geologiske Undersøgelse (A) 12: 165.CrossRefGoogle Scholar
Fraser, S.I., Robinson, A.M., Johnson, H.D., Underhill, J.R., Kadolsky, D.G.A., Connel, R., Johannessen, P. & Ravnås, R., 2003. Upper Jurassic. In: Evans, D., Graham, C., Armour, A. & Bathorst, P. (eds): The Millennium Atlas: petroleum geology of the central and northern North Sea. The Geological Society (London): 157–189.Google Scholar
Frebold, H., 1930. Verbreitung und Ausbildung des Mesozoikums in Spitsbergen. Skrifter om Svalbard og Ishavet 31: 127 pp.Google Scholar
Frebold, H. & Stoll, E., 1937. Das Festungsprofil auf Spitzbergen. III. Stratigraphie und Fauna des Jura und der Unterkreide. Skrifter om Svalbard og Ishavet 68: 185.Google Scholar
Fürsich, F.T., 1984. Benthic macroinvertebrate associations from the Boreal Upper Jurassic of Milne Land, central East Greenland. Grønlands geologiske Undersøgelse Bulletin 149: 172.CrossRefGoogle Scholar
Gallois, R.W., 1983. The stratigraphy and sedimentology of the Upper Jurassic and Lower Cretaceous rocks of Norfolk. Thesis University of London: 519 pp.Google Scholar
Gallois, R.W., 1984. The Late Jurassic to mid Cretaceous rocks of Norfolk. Bulletin of the Geological Society of Norfolk 34: 364.Google Scholar
GAPS, 1991. Sedimentology, Petrology and Reservoir Properties of Cores X and Y from Well XYZA [= L06-02]. Report G16-2: 87 pp. (unpublished NAM report)Google Scholar
Glazunova, A.E., 1973. Palaeontological substantiation of the stratigraphic subdivision of the Cretaceous deposits of the Volga area. Lower Cretaceous. Nedra (Moscow): 324 p. (in Russian)Google Scholar
Grabowski, J., Chmielewski, A., Ploch, I., Rogov, M., Smoleń, J., Wójcik-Tabol, P., Leszczyński, K. & Maj-Szeliga, K., 2021. Palaeoclimate changes and inter-regional correlations in the Jurassic/Cretaceous boundary interval of the Polish Basin: portable XRF and magnetic susceptibility study. Newsletters on Stratigraphy 54: 123158.CrossRefGoogle Scholar
Grey, M., 2009. Exploring evolutionary patterns and processes. A case study using the Mesozoic bivalve Buchia. Thesis University of British Columbia (Vancouver): xviii + 147 pp.Google Scholar
Håkansson, E., Birkelund, T., Piasecki, S. & Zakharov, V., 1981. Jurassic - Cretaceous boundary strata of the extreme Artic (Peary Land, North Greenland). Bulletin of the geological Society of Denmark 30: 1142.CrossRefGoogle Scholar
Hallam, A., Grose, J.A. & Ruffell, A.H., 1991. Palaeoclimatic significance of changes in clay mineralogy across the Jurassic-Cretaceous boundary in England and France. Palaeogeography, Palaeoclimatology, Palaeoecology 81: 173187.CrossRefGoogle Scholar
Hamar, G.P., Fjaeran, T. & Hesjedal, A., 1983. Jurassic stratigraphy and tectonics of the south-southeastern Norwegian offshore. Geologie & Mijnbouw 62: 103114.Google Scholar
Hammer, O., Hryniewicz, K., Hurum, J.H., Høyberget, M., Knutsen, E.M. & Nakrem, H.A., 2013. Large onychites (cephalopod hooks) from the Upper Jurassic of the Boreal Realm. Acta Palaeontologica Polonica 58: 827835.Google Scholar
Harbort, E., 1905. Die Fauna der Schaumburg-Lippe’schen Kreidemulde. Abhandlungen der königlich preussischen geologischen Landesanstalt und Bergakademie 45: 1122.Google Scholar
Harper, D.A.T., Alsen, P., Owen, E.F. & Sandy, M.R., 2005. Early Cretaceous brachiopods from North-East Greenland: Biofacies and biogeography. Bulletin of the Geological Society of Denmark 52: 213225.CrossRefGoogle Scholar
Herngreen, G.F.W., Kerstholt, S.J. & Munsterman, D.K., 2000. Callovian-Ryazanian (‘Upper Jurassic’) palynostratigraphy of the Central North Sea Graben and Vlieland Basin, the Netherlands. Mededelingen Nederlands Instituut voor Toegepaste Geowetenschappen TNO 63: 399.Google Scholar
Hoedemaker, P.J., 1999. A Tethyan-Boreal correlation of pre-Aptian Cretaceous strata: correlating the uncorrelatable. Geologica Carpathica 50: 101124.Google Scholar
Hoedemaeker, P. J. & Herngreen, G. W., 2003. Correlation of Tethyan and Boreal Berriasian–Barremian strata with emphasis on strata in the subsurface of the Netherlands. Cretaceous Research 24: 253275.CrossRefGoogle Scholar
Hoedemaker, P.J. & Herngreen, G.F.W., 2004. Correlation of the Boreal and Tethyan Neocomian with emphasis on the main producing strata of the Netherlands. Erratum. Cretaceous Research 25: 137150.Google Scholar
Høiland, O., Kristensen, J. & Monsen, T., 1993. Mesozoic evolution of the Jæren High area, Norwegian Central North Sea. In: Structural styles and their evolution in the North Sea area. Petroleum Geology of Northwest Europe: Proceedings of the 4th Conference on Petroleum Geology of NW Europe. Geological Society, London, Petroleum Geology Conference series 4: 1189–1195.CrossRefGoogle Scholar
Hopson, P.M, Wilkinson, I.P. & Woods, M.A., 2008. A stratigraphic framework for the Lower Cretaceous of England. British Geological Survey Research Report RR/08/03: vi + 77 pp.Google Scholar
Hryniewicz, K., Little, C.T.S. & Nakrem, H.A., 2014. Bivalves from the latest Jurassic-earliest Cretaceous hydrocarbon seep carbonates from central Spitsbergen, Svalbard. Zootaxa 3859(1): 166.CrossRefGoogle ScholarPubMed
Igolnikov, A.E., 2006. Revision of Surites (Caseyiceras) subanalogus Schulgina, 1972 and stratigraphic implications. News of Paleontology and Stratigraphy 9: 97103 (in Russian with English abstract).Google Scholar
Igolnikov, A.E., 2019. Berriasian (Ryazanian) ammonites (Craspeditids and Phylloceratids) of north-eastern Siberia: morphological, systematic and biostratigraphical conclusions. Thesis (Novosibirsk): 217 pp. (in Russian)Google Scholar
Ineson, J.R., Bojesen-Koefoed, J.A., Dybkjær, K. & Nielsen, L.H., 2003. Volgian–Ryazanian ‘hot shales’ of the Bo Member (Farsund Formation) in the Danish Central Graben, North Sea: stratigraphy, facies and geochemistry. Geological Survey of Denmark and Greenland Bulletin 1: 403436.CrossRefGoogle Scholar
Ineson, J.R., Sheldon, E., Dybkjær, K., Andersen, C., Alsen, P. & Jakobsen, F., 2022. The ‘Base Cretaceous Unconformity’ in a basin-centre setting, Danish Central Graben, North Sea: A cored record of resedimentation and condensation accompanying transgression and basinal overturn. Marine and Petroleum Geology 137: 105489.CrossRefGoogle Scholar
Jeremiah, J., 2001. A Lower Cretaceous nannofossil zonation for the North Sea Basin. Journal of Micropalaeontology 20: 4580.CrossRefGoogle Scholar
Jeremiah, J., Duxbury, S. & Rawson, P., 2010. Lower Cretaceous of the southern North Sea Basins: reservoir distribution within a sequence stratigraphic framework. Netherlands Journal of Geosciences 89: 203237.CrossRefGoogle Scholar
Kashirtsev, V.A., Nikitenko, B.L., Peshchevitskaya, E.B. & Fursenko, E.A., 2018. Biogeochemistry and microfossils of the Upper Jurassic and Lower Cretaceous, Anabar Bay, Laptev Sea. Russian Geology and Geophysics 59: 386404.CrossRefGoogle Scholar
Kelly, S.R.A., 1983. Boreal influence on English Ryazanian bivalves. Zitteliana 10: 285292.Google Scholar
Kelly, S.R.A., 1984. Bivalvia of the Spilsby Sandstone and Sandringham Sands (Late Jurassic-Early Cretaceous) of eastern England. Part 1. Palaeontographical Society, London, Monograph no. 566 (issued as part of Vol. 137 for 1983): 194, 20 pls.Google Scholar
Kelly, S.R.A., 1990. Biostratigraphy of the bivalve Buchia in the Upper Jurassic and Lower Cretaceous sediments of Europe. Transactions Institute of Geology and Geophysics Siberian Branch Academy of Sciences of the USSR 699: 129–151. (in Russian with English abstract)Google Scholar
Kiselev, D.N., Rogov, M.A. & Zakharov, V.A., 2018. The Volgidiscus singularis Zone of the terminal horizon of the Volgian Stage of European Russia and its significance for interregional correlation and paleogeography. Stratigraphy and Geological Correlation 26: 206233.CrossRefGoogle Scholar
Klein, J., 2006. Lower Cretaceous Ammonites II. Perisphinctaceae 2 - Polyptychitidae. Fossilium Catalogus I: Animalia 141: 1186.Google Scholar
Koevoets, M.J., Hurum, H.H. & Hammer, O., 2018. New Late Jurassic teleost remains from the Agardhfjellet Formation, Spitsbergen, Svalbard. Norwegian Journal of Geology 98: 289299.Google Scholar
Korstgård, J.A., Lerche, I., Mogensen, T.E. & Thomsen, R.O., 1993. Salt and fault interactions in the northeastern Danish Central Graben: observations and inferences. Bulletin of the Geological Society of Denmark 40: 197255.CrossRefGoogle Scholar
Kosenko, I.N., Urman, O.S., Metelkin, E.K., Shurygin, B.N. & Igolnikov, A.E., 2019. New data on the litho- and biostratigraphy of the J/K Boundary Interval of the lower reaches of the Lena River (eastern Siberia). Open Journal of Geology 9: 554557.CrossRefGoogle Scholar
Kyrkjebø, R., Gabrielsen, R.H. & Faleide, J.I., 2004. Unconformities related to the Jurassic-Cretaceous synrift-post-rift transition of the northern North Sea. Journal of the Geological Society 161: 117.CrossRefGoogle Scholar
Lahusen, I.I, 1888. Ueber die russischen Aucellen. Mémoires du Comité Géologique, VIII(1): 1–46, 5 pls.Google Scholar
Laughton, A.S., 1975. Tectonic evolution of the Northeast Atlantic Ocean: a review. Norges geologiske Undersøgelse 316: 169193.Google Scholar
Lindström, S. & Ekström, M., 2011. The Jurassic-Cretaceous transition of the Fårarp-1 core, southern Sweden: sedimentological and phytological indications of climate change. Palaeogeography, Palaeoclimatology, Palaeoecology 308: 445475.CrossRefGoogle Scholar
Marek, S., 1984. The question of the Jurassic – Cretaceous boundary in marginal zone of the East-European Platform. Przegląd Geologiczny 32: 248–252.Google Scholar
Marinov, V.A., Meledina, S.V., Dzyuba, O.S. & Urman, O.S., 2009. Upper Jurassic and Lower Cretaceous biostraptigraphy of the central part of western Siberia. News on Paleontology and Stratigraphy 12: 119–142 (in Russian with English abstract).Google Scholar
Mesezhnikov, M.S., 1984. Zonal subdivision of the Ryazanian horizon. In: Menner, V.V. (ed.), The Jurassic and Cretaceous boundary stages. Transactions of the Academy of Sciences of the USSR, Siberian branch, Institute of Geology and Geophysics 644: 54–66 (in Russian).Google Scholar
Mesezhnikov, M.S., 1988. Tithonian (Volgian). In: Krymholts, G.Ya., Mesezhnikov, M.S. & Westermann, G.E.G. (eds.), The Jurassic Ammonite Zones of the Soviet Union. Geological Society of America, Special Paper 223: 50–62.CrossRefGoogle Scholar
Mesezhnikov, M.S., Gol’bert, A.V., Zakharov, V.A., Klimova, I.G., Kravets, V.C., Saks, V.N., Shul’gina, N.I., Alekseev, S.N., Bulynnikova, I.G., Kuzina, V.I. & Yakovleva, S.P., 1979. New stratigraphy for the Jurassic Cretaceous layers in the Pechora River Basin. In: Saks, V.N. (ed.), Upper Jurassic and its boundary with the Cretaceous System. Institute of Geology and Geophysics Siberian Branch Academy of Sciences of the USSR (Nauka) Novosibirsk: 66–71 (in Russian).Google Scholar
Mesezhnikov, M.S., Alekseev, S.N., Klimova, I.G., Shul’gina, N.I. & Gyul’khadzhan, L.V., 1983. About the development of some Craspeditidae at the Jurassic-Cretaceous boundary. In: Zakharov, V.A. & Nal’nyaeva, T.I. (eds), The Cretaceous of the Sovjet Arctic. Institute of Geology and Geophysics Siberian Branch Academy of Sciences of the USSR (Nauka) Novosibirsk: 103–125 (in Russian).Google Scholar
Michelsen, O., Nielsen, L.H., Johannessen, P.N., Andsbjerg, J. & Surlyk, F., 2003. Jurassic lithostratigraphy and stratigraphic development onshore and offshore Denmark. Geological Survey of Denmark and Greenland Bulletin 1: 147216.Google Scholar
Mitta, V.V., 2017. The Ryazanian (basal Lower Cretaceous) standard zonation: state of knowledge and potential for correlation with the Berriasian primary standard. Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 286(2): 141–157.CrossRefGoogle Scholar
Mitta, V.V., 2019. Craspeditidae (Ammonoidea) of the Russian Platform at the Jurassic-Cretaceous boundary. II. Genus Hectoroceras Spath. Paleontological Journal 53: 598610.CrossRefGoogle Scholar
Mitta, V.V., 2021. О видах-индексах зон стандартной шкалы рязанского яруса Русской платформы. [On the Zonal Index-Species of the Ryazanian Stage Standard Scale of the Russian Platform]. Paleontological Journal 2021(3): 4048 (in Russian).Google Scholar
Möller, C., Mutterlose, J. & Alsen, P., 2015. Integrated stratigraphy of Lower Cretaceous sediments (Ryazanian-Hauterivian) from North-East Greenland. Palaeogeography, Palaeoclimatology, Palaeoecology 437: 8597.CrossRefGoogle Scholar
Munsterman, D.K., Verreussel, R.M.C.H., Mijnlief, H.F., Witmans, N., Kerstholt-Boegehold, S. & Abbink, O.A., 2012. Revision and update of the Callovian-Ryazanian Stratigraphic Nomenclature in the northern Dutch offshore, i.e. Central Graben Subgroup and Scruff Group. Netherlands Journal of Geosciences 91: 555590.CrossRefGoogle Scholar
Mutterlose, J., Alsen, P., Iba, Y. & Schneider, S., 2020. Palaeobiogeography and palaeoecology of Early Cretaceous belemnites from the northern high latitudes. Proceedings of the Geologists’ Association 131: 278286.CrossRefGoogle Scholar
Mutterlose, J., Brumsack, H., Flögel, S., Hay, W., Klein, C., Langrock, U., Lipinski, M., Ricken, W., Söding, E., Stein, R. & Swientek, O., 2003. The Greenland–Norwegian Seaway: A key area for understanding Late Jurassic to Early Cretaceous paleoenvironments. Paleoceanography 18: 126.CrossRefGoogle Scholar
Nerdal, B., Roche, J. & Dombeck, P., 1992. Completion report well 7/7-2. Statoil/Amoco/Amerada Hess/Total: 185 pp.Google Scholar
Nøttvedt, A., Gabrielsen, R.H. & Steel, R.J., 1995. Tectonostratigraphy and sedimentary architecture of rift basins, with reference to the northern North Sea. Marine and Petroleum Geology 12: 881890.CrossRefGoogle Scholar
Paraketsov, K.V. & Paraketsova, G.V., 1989. Stratigraphy and fauna of the Upper Jurassic and Lower Cretaceous deposits of North-East of the USSR. Moscow (Nedra): 298 pp. (in Russian)Google Scholar
Partington, M.A., Copestake, P., Mitchener, B.C. & Underhill, J.R., 1993. Biostratigraphic calibration of genetic stratigraphic sequences in the Jurassic–lowermost Cretaceous (Hettangian to Ryazanian) of the North Sea and adjacent areas. Geological Society, London, Petroleum Geology Conference Series 4: 371386.CrossRefGoogle Scholar
Pauly, S., Mutterlose, J. & Alsen, P., 2012. Early Cretaceous palaeoceanography of the Greenland-Norwegian Seaway evidenced by calcareous nannofossils. Marine Micropaleontology 90–91: 7285.CrossRefGoogle Scholar
Pauly, S., Mutterlose, J. & Alsen, P., 2013. Depositional environments of Lower Cretaceous (Ryazanian – Barremian) sediments from Wollaston Forland and Kuhn Ø, North-East Greenland. Bulletin of the Geological Society of Denmark 61: 19–36.CrossRefGoogle Scholar
Pavlow, A. P., 1896. On the classification of the strata between the Kimmeridgian and Aptian. Quarterly Journal of the geological Society London 52: 542–555.CrossRefGoogle Scholar
Phillips, J., 1835. Illustrations of the geology of Yorkshire; or, a description of the strata and organic remains accompanied by a geological map, sections, and plates of the fossil plants and animals. Part 1. The Yorkshire coast. (J. Murray) London: xii + 184 pp., 14 pls, 1 map [2nd edition].CrossRefGoogle Scholar
Piasecki, S., Callomon, J.H. & Stemmerik, L., 2004. Jurassic dinoflagellate cysts stratigraphy of Store Koldewey, North-East Greenland. Geological Survey of Denmark and Greenland Bulletin 5: 99112.Google Scholar
Piasecki, S., Bojesen-Koefoed, J.A. & Alsen, P., 2020. Geology of the Lower Cretaceous in the Falkebjerg area, Wollaston Forland, northern East Greenland. Bulletin of the Geological Society of Denmark 68: 155–169.CrossRefGoogle Scholar
Pinckney, G. & Rawson, P.F., 1974. Acroteuthis assemblages in the Upper Jurassic and Lower Cretaceous of northwest Europe. Newsletters on Stratigraphy 3: 193204.CrossRefGoogle Scholar
Rawson, P. F., Curry, D., Dilley, F. C., Hancock, J. M., Kennedy, W. J., Neale, J. W., Wood, C. J. & Worssam, B. C. 1978. A correlation of Cretaceous rocks in the British Isles. Geological Society London, Special Report No. 9: 1–70.Google Scholar
Roberts, D.G., Thompson, M., Mitchener, B., Hossack, J., Carmichael, S. & Bjørnseth, H.-M., 1999. Palaeozoic to Tertiary rift and basin dynamics: mid-Norway to the Bay of Biscay – a new context for hydrocarbon prospectivity in the deep water frontier. Geological Society, London, Petroleum Geological Conference series 5: 740.CrossRefGoogle Scholar
Rogov, M.A., 2020. Infrazonal ammonite biostratigraphy, paleobiogeography and evolution of Volgian craspeditid ammonites. Paleontological Journal 54: 11891219.CrossRefGoogle Scholar
Rogov, M.A., 2021. Ammonites and infrazonal stratigraphy of the Kimmeridgian and Volgian stages of the Panboreal Superrealm. Transactions of the Geological Institute 627: 1–732 (in Russian).Google Scholar
Rogov, M.A., Zakharov, V.A. & Ershova, V.B., 2011. Detailed stratigraphy of the Jurassic–Cretaceous boundary beds of the Lena River lower reaches based on ammonites and buchiids. Stratigraphy and Geological Correlation 19: 641662.CrossRefGoogle Scholar
Rogov, M.A., Baraboshkin, E.Y., Guzhikov, A.Y., Efimov, V.M., Kiselev, D.N., Morov, V.P. & Gusev, V.V., 2015. The Jurassic-Cretaceous boundary in the Middle Volga region. Field guide to the international meeting on the Jurassic/Cretaceous boundary. September 7–13, 2015, Samara (Russia). Samara (SSTU): 130 pp.Google Scholar
Rogov, M.A., Ershova, V.B., Shchepetova, E.V., Zakharov, V.A., Pokrovsky, B.G. & Khudoley, A.K., 2017. Earliest Cretaceous (late Berriasian) glendonites from Northeast Siberia revise the timing of initiation of transient Early Cretaceous cooling in the high latitudes. Cretaceous Research 71: 102112.CrossRefGoogle Scholar
Rogov, M., Shchepetova, E.V. & Zakharov, V.A., 2020. Late Jurassic – earliest Cretaceous prolonged shelf dysoxic-anoxic event and possible causes. Geological Magazine 157: 16221642.CrossRefGoogle Scholar
Rouillier, K.F., 1845. Nouveau genre Buchia. Bulletin de la Société Impériale des naturalistes de Moscou 18: 289.Google Scholar
Saks, V.N. & Shul’gina, N.I., 1962. Cretaceous System in Siberia: suggestions concerning its subdivision into stages and zones. Geology and Geophysics 1962(10): 2840 (in Russian).Google Scholar
Saks, V.N. & Nal’nyaeva, T.I., 1975. Belemnites. In: Saks, V.N. (ed.): The Jurassic-Cretaceous boundary and the Berriasian stage in the Boreal Realm. (IPST) Jerusalem: 216–229.Google Scholar
Sandy, M.R., 1991. Aspects of Middle-Late Jurassic-Cretaceous Tethyan brachiopod biogeography in relation to tectonic and paleoceanographic developments. Palaeogeography, Palaeoclimatology, Palaeoecology 87: 137154.CrossRefGoogle Scholar
Sazonov, N.T., 1951. About some little-known early Cretaceous ammonites. Bulletin of the Society of Naturalists of Moscow (geology) 26: 57–63 (in Russian).Google Scholar
Sazonov, N.T., 1953. Stratigraphy of the Jurassic and lower Cretaceous sediments of the Russian Platform, Dneprovsko-Donets and Pre-Caspian basins. Bulletin of the Society of Naturalists of Moscow (geology) 28: 71–100 (in Russian).Google Scholar
Sazonova, I.G., 1971. Berriasian and lower Valanginian ammonites from the Russian Platform. Transactions of the All-Union Research Geological Oil Industry (VNIGNI) 110: 3–100 (in Russian).Google Scholar
Sazonova, I.G., 1975. Russian Plain. In: Saks, V.N. (ed.): The Jurassic-Cretaceous boundary and the Berriasian stage in the Boreal Realm. (IPST) Jerusalem: 89–94.Google Scholar
Sazonova, I.G., 1977. Ammonites from the Jurassic-Cretaceous boundary strata of the Russian Plain. Trudy VNIGNI 185: 128 p. (in Russian)Google Scholar
Sasonova, I.G. & Sasonov, N.T. (1984). Berriasian of the Boreal provinces of Europe. Bulletin of the Society of Naturalists of Moscow (geology) 59: 8697.Google Scholar
Schneider, A.C., Heimhofer, U., Heunisch, C. & Mutterlose, J., 2018. The Jurassic-Cretaceous boundary interval in non-marine strata of northwest Europe – New light on an old problem. Cretaceous Research 87: 4254.CrossRefGoogle Scholar
Schneider, S., Kelly, S.R.A., Mutterlose, J., Herrle, J.O., Hülse, P., Jolley, D.W., Schröder-Adams, C.J. & Lopez-Mir, B., 2020. Macrofauna and biostratigraphy of the Rollrock Section, northern Ellesmere Island, Canadian Arctic Islands - a comprehensive high latitude archive of the Jurassic-Cretaceous transition. Cretaceous Research 114: 104508.CrossRefGoogle Scholar
Sha, J. & Fürsich, F.T., 1993. Biostratigraphy of the Upper Jurassic–Lower Cretaceous bivalves Buchia and Aucellina of eastern Heilongjiang, northeastern China. Geological Magazine 130: 533542.CrossRefGoogle Scholar
Shul’gina, N.I., 1972. Ammonites from the north of Middle Siberia. In: Jurassic-Cretaceous boundary and Berriasian Stage in Boreal Realm. Novosibirsk (Nauka Siberian Branch): 137–175 (in Russian).Google Scholar
Shul’gina, N.I., 1975. Ammonites of the north of Middle Siberia. In: Saks, V.N. (ed.), The Jurassic-Cretaceous boundary and the Berriasian Stage in the Boreal Realm. (IPST) Jerusalem: 145–186 (translation of 1972).Google Scholar
Shul’gina, N.I., 1985. Boreal Basins on the Jurassic/Cretaceous boundary. Transactions of the VNII Okeangeologiya 193: 1163 (in Russian).Google Scholar
Sinclair, I.K., 1994. Tectonism and sedimentation in the Jeanne d’Arc Basin, Grand Banks of Newfoundland. Thesis University of Aberdeen: x + 249 pp.Google Scholar
Smelror, M., Kelly, S.R.A., Dypvik, H., Mørk, A., Nagy, J. & Tsikalas, F., 2001. Mjølnir (Barents Sea) meteorite impact ejecta offers a Volgian-Ryazanian boundary marker. Newsletters on Stratigraphy 28: 129140.CrossRefGoogle Scholar
Sokolov, D. & Bodylevski, W. (1931). Jura- und Kreideformationen von Spitzbergen. Skrifter om Svalbard og Ishavet 35: 1–151.Google Scholar
Sorgenfrei, Th. & Buch, A., 1964. Deep Tests in Denmark 1935–1959. Danmarks Geologiske Undersøgelse (III) 36: 1–146.CrossRefGoogle Scholar
Spath, L.F., 1952. Additional observations on the invertebrates (chiefly ammonites) of the Jurassic and Cretaceous of East Greenland. II. Some infra-Valanginian ammonites from Lindemans Fjord, Wollaston Forland; with a note on the base of the Cretaceous. Medelelser om Grønland 133 (4): 5–40, 4 pls.Google Scholar
Stoker, M.S., Stewart, M.A., Shannon, P.M., Bjerager, M., Nielsen, T., Blischke, A., Hjelstuen, B.O., Gaina, C., McDermott, K. & Ólavsdóttir, J., 2017. An overview of the Upper Palaeozoic-Mesozoic stratigraphy of the NE Atlantic region. In: Péron-Pinvidic, G., Hopper, J.R., Stoker, M.S., Gaina, C., Doornenbal, J.C., Funck, T. & Árting, U.E. (eds): The NE Atlantic Region: a reappraisal of crustal structure, tectonostratigraphy and magmatic evolution. Geological Society, London, Special Publications 447: 1168.CrossRefGoogle Scholar
Surlyk, F., 1978. Submarine fan sedimentation along fault scarps on tilted fault blocks (Jurassic-Cretaceous boundary, East Greenland). Grønlands Geologiske Undersøgelse, Bulletin 128: 1136.Google Scholar
Surlyk, F. & Zakharov, V.A., 1982. Buchiid bivalves from the Upper Jurassic and Lower Cretaceous of east Greenland. Palaeontology 25: 727753.Google Scholar
Swientek, O., 2002. The Greenland Norwegian Seaway: climatic and cyclic evolution of Late Jurassic-Early Cretaceous sediments. PhD Thesis, University of Cologne, Germany: 148 pp.Google Scholar
Swinnerton, H.H. & Kent, P.E., 1981. The geology of Lincolnshire (second edition): From the Humber to the Wash. Lincolnshire Natural History Brochure 7: xi + 130 pp.Google Scholar
Turner, H.E., 2018. Integrated correlation of the Kimmeridge Clay Formation (Late Jurassic-Early Cretaceous): a Boreal-Tethyan transect. Thesis University of Portsmouth: 212 pp.Google Scholar
Urman, O.S., Dzyuba, O.S., Kirillova, G.L. & Shurygin, B.N., 2014. Buchia faunas and stratigraphy of the Jurassic-Cretaceous Boundary deposits in the Komsomolsk Section (Russian Far East). Russian Journal of Pacific Geology 8: 346359.CrossRefGoogle Scholar
Urman, O.S., Shurygin, B.N. & Dzyuba, O.S., 2019. New Paleontological and Stratigraphic Data on the Ryazanian Regiostage in the Oka River Sections (Central Russia). Communications of the Saratov University (N.S.), Earth Sciences 19: 279290 (in Russian).Google Scholar
Verreussel, R.M.C.H., Bouroullec, R, Munsterman, D.K., Dybkjær, K., Geel, C.R., Houben, A.J.P., Johannessen, P.N. & Kerstholt-Boeghold, S.J., 2018. Stepwise basin evolution of the Middle Jurassic–Early Cretaceous rift phase in the Central Graben area of Denmark, Germany and The Netherlands. In: Kilhams, B., Kukla, P.A., Mazur, S., McKie, T., Mijnlieff, H.F. & Ojik, K. van (eds.), Mesozoic Resource Potential in the Southern Permian Basin. Geological Society, London, Special Publications 469: 305–340.CrossRefGoogle Scholar
Vyachkileva, N.P., Klimova, N.P., Turbina, A.S., Braduchan, Y.V., Zakharov, V.A., Meledina, S.V. & Aleinikov, A.N., 1990. Atlas of molluscs and foraminifers from the marine deposits of the Upper Jurassic and Neocomian of the West Siberian oil and gas area. I. Stratigraphical review. Molluscs. Moscow (Nedra): 286 pp (in Russian). http://mmtk.ginras.ru/pdf/Atlas_WSiberia_J3-K1_mollusks.pdf Google Scholar
Westermann, G.E.G., 2000. Marine faunal realms of the Mesozoic: review and revision under the new guidelines for biogeographic classification and nomenclature. Palaeogeography, Palaeoclimatology, Palaeoecology 163: 4968.CrossRefGoogle Scholar
Wierzbowski, A., Hryniewicz, K., Hammer, Ø., Nakrem, H.A. & Little, C.T.S., 2011. Ammonites from hydrocarbon seep carbonate bodies from the uppermost Jurassic – lowermost Cretaceous of Spitsbergen and their biostratigraphical importance. Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 262: 267288.CrossRefGoogle Scholar
Woods, H., 1905. A monograph of the Cretaceous lamellibranchia of England. Palaeontological Society, London, II (II): 57–96, pl. VIII–XI.CrossRefGoogle Scholar
Wright, C.W., Callomon, J.H. & Howarth, M.K., 1996. Cretaceous Ammonoidea. In: Moore, R.C. & Kaesler, R.L. (eds.), Treatise on Invertebrate Paleontology. Part L. Mollusca 4 (Revised) Volume 4: xx + 362 p.Google Scholar
Zakharov, V.A., 1966. Late Jurassic and Early Cretaceous bivalve molluscs of northern Siberia and their living conditions (order Anisomyaria). Transactions Institute of Geology and Geophysics Siberian Branch Academy of Sciences of the USSR 1966: 1–189 (in Russian).Google Scholar
Zakharov, V.A., 1981. Buchiidae and biostratigraphy of the Boreal Upper Jurassic and Neocomian. Trudy Institut Geologii i Geofizki 458: 271+5 pp (in Russian).Google Scholar
Zakharov, V.A., 1987. The bivalve Buchia and the Jurassic-Cretaceous Boundary in the Boreal Province. Cretaceous Research 8: 141153.CrossRefGoogle Scholar
Zakharov, V.A., 1990. Definition of the Jurassic-Cretaceous boundary on buchias. Transactions Institute of Geology and Geophysics Siberian Branch Academy of Sciences of the USSR 699: 115128 (in Russian).Google Scholar
Zakharov, V.A., 2015. Performance capabilities of the Boreal-Peritethyan correlation of the Upper Jurassic and Lower Cretaceous successions by buchiids. In: Jurassic System of Russia: Problems of stratigraphy and paleogeography. Fifth All-Russian meeting. September 15-20, 2015, Makhachkala. Scientific materials: 124–130 (in Russian).Google Scholar
Zakharov, V.A. & Rogov, M.A., 2003. Boreal-Tethyan mollusk migrations at the Jurassic-Cretaceous boundary time and biogeographic ecotone position in the Northern Hemisphere. Stratigraphy and Geological Correlation 11: 152171.Google Scholar
Zakharov, V.A. & Rogov, M.A., 2020. High-resolution stratigraphy of buchiid bivalves and ammonites from the Jurassic-Cretaceous boundary beds in the Paskenta area (California). Cretaceous Research 110: 104422.CrossRefGoogle Scholar
Zakharov, V.A., Surlyk, F. & Dalland, A., 1981. Upper Jurassic-Lower Cretaceous Buchia from Andøy, northern Norway. Norsk Geologisk Tidsskrift 61: 261269.Google Scholar
Zakharov, V.A., Rogov, M.A., Dzyuba, O.S., Žák, K., Martin Košt’ák, M., Pruner, P., Skupien, P., Chadima, M., Mazuch, M. & Nikitenko, B.L., 2014. Palaeoenvironments and palaeoceanography changes across the Jurassic/Cretaceous boundary in the Arctic realm: case study of the Nordvik section (north Siberia, Russia). Polar Research 33: 19714.CrossRefGoogle Scholar
Ziegler, P.A., 1982. Geological Atlas of Western and Central Europe. Den Haag (Shell Internationale Petroleum Maatschappij): 130 pp.Google Scholar
Ziegler, P.A., 1988. Evolution of the Arctic-North Atlantic and the Western Tethys. AAPG Memoir 43: 164–196.CrossRefGoogle Scholar

Additional readings

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.