Hostname: page-component-76fb5796d-vvkck Total loading time: 0 Render date: 2024-04-29T04:01:48.655Z Has data issue: false hasContentIssue false
  • English
  • Français

The brachiopod assemblage from the Maastrichtian white chalk at Chełm, eastern Poland: stratigraphical and palaeoecological implications

Published online by Cambridge University Press:  06 February 2024

Marcin Machalski Open the ORCID record for Marcin Machalski [Opens in a new window]  and
Maria Aleksandra Bitner Open the ORCID record for Maria Aleksandra Bitner [Opens in a new window]
Marcin Machalski*
Affiliation:
Institute of Paleobiology, Polish Academy of Sciences, Warszawa, Poland
Maria Aleksandra Bitner
Affiliation:
Institute of Paleobiology, Polish Academy of Sciences, Warszawa, Poland
*
Corresponding author: Marcin Machalski; Email: mach@twarda.pan.pl
Rights & Permissions [Opens in a new window]

Abstract

Brachiopods from the lower upper Maastrichtian (Upper Cretaceous) white chalk succession exposed at Chełm (eastern Poland) comprise Lingula cretacea, Isocrania costata, Cryptoporella antiqua, Cretirhynchia sp., Neoliothyrina sp., Carneithyris sp., Terebratulina chrysalis, T. faujasi, T. longicollis, Terebratulina spp., Gisilina sp., Bronnothyris bronni, Magas chitoniformis, Leptothyrellopsis polonicus and ?Aemula sp. This assemblage is relatively poor in terms of taxonomic diversity and specimen abundance and is dominated by stratigraphically long-ranging species. It is best comparable to that from the micromorphic brachiopod Rugia tenuicostataMeonia semiglobularis Zone as distinguished in the white chalk successions of Denmark and northern Germany, although this zone is usually placed in the upper lower Maastrichtian. The Chełm succession represents a relatively deep-water and ‘benthos-poor’ variety of white chalk deposited in the Boreal Chalk Sea of Europe. The brachiopod assemblage studied is typical of such a habitat, having been controlled largely by the low availability of minute skeletal substrates suitable for brachiopod settlement.

Keywords

BrachiopodaMaastrichtianCretaceouschalkstratigraphypalaeoecology
Type
Original Article
Information
Netherlands Journal of Geosciences , Volume 103 , 2024 , e3
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), 2024. Published by Cambridge University Press on behalf of the Netherlands Journal of Geosciences Foundation

Introduction

Brachiopods are an important component of white chalk macrofossil assemblages that thrived in the Boreal Chalk Sea of Europe during the Campanian and Maastrichtian (Late Cretaceous). They have been widely used for stratigraphical and palaeoecological inferences (e.g., Steinich, Reference Steinich1965; Surlyk, Reference Surlyk1970, Reference Surlyk1972, Reference Surlyk1982; Bitner & Pisera, Reference Bitner and Pisera1979; Ernst, Reference Ernst1984; Johansen, Reference Johansen1987a, b; Johansen & Surlyk, Reference Johansen and Surlyk1990; MacKinnon et al., Reference MacKinnon, Simon and Bitner1998; Jelby et al., Reference Jelby, Thibault, Surlyk, Ullmann, Harlou and Korte2014; Schrøder & Surlyk, Reference Schrøder and Surlyk2020). As far as stratigraphy is concerned, Surlyk (Reference Surlyk1972, Reference Surlyk1984) proposed a biostratigraphical scheme for the upper Campanian and Maastrichtian in northwest Europe, comprising several zones based on micromorphic brachiopod assemblages recovered mainly from sections in Denmark (several localities in Jylland and Sjælland; Johansen, Reference Johansen1987a) and northwest (Kronsmoor and Hemmoor sections, Surlyk, Reference Surlyk1982; Johansen, Reference Johansen1987b) and northeast Germany (Isle of Rügen, Steinich, Reference Steinich1965).

In Poland, brachiopods from the Upper Cretaceous white chalk facies have been described to date only from the Campanian succession at Mielnik on the River Bug (Bitner & Pisera, Reference Bitner and Pisera1979; see Bojanowski et al., Reference Bojanowski, Dubicka, Minoletti, Olszewska-Nejbert and Surowski2017 for an updated stratigraphy). The aim of the present paper is to describe, for the first time, a brachiopod assemblage from the lower upper Maastrichtian chalk at Chełm, eastern Poland (Fig. 1A, B), and to discuss its stratigraphical and palaeoecological significance within the context of previous work on Late Cretaceous brachiopod assemblages from the European white chalk.

Figure 1. A. Location of the Chełm site in Poland (modified from Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021, Fig. 1). B. Satellite view of the Chełm chalk pit (Google Maps, https://www.google.com/maps/place/Chełm).

Geological setting

The studied brachiopod-bearing chalk succession crops out in an active chalk quarry run by the cement company Cemex Polska (Fig. 1B), situated in the eastern part of the town of Chełm. Currently, the chalk is accessible along four exploitation levels that are referred to, from the top to the bottom, as II, III, IV and V. Level I has now been completely excavated. A portion of the section below level V temporarily exposed in a dewatering trench was referred to as level VI by Dubicka & Peryt (Reference Dubicka and Peryt2011). The total thickness of the chalk currently exposed at Chełm is c. 40 m, with the top of working level II located at 203 m a.s.l. (above sea level), and the bottom of level VI at 164 m a.s.l. (Dubicka & Peryt, Reference Dubicka and Peryt2011; Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021).

The white chalk exposed at Chełm (Fig. 2) is a fine-grained carbonate deposit composed almost exclusively of coccoliths. Flint layers, burrowed omission surfaces, bored and/or mineralised hardgrounds and other marker beds, which are characteristic of many white chalk successions in Europe, are absent. The only indication that the chalk strata at Chełm lie almost horizontally is provided by the orientation of some fossils, for instance, tests of irregular echinoids (Echinocorys sp.) preserved in life position (Dubicka & Peryt, Reference Dubicka and Peryt2011). In view of this, the exploration levels are the only reference for sampling (Dubicka & Peryt, Reference Dubicka and Peryt2011; Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021). See the ‘Supplementary Information’ in Machalski et al. (Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021) for a full description of the section and its fossil assemblages.

Figure 2. Distribution of brachiopod species recognised in the lower upper Maastrichtian section exposed at Chełm along the section log and macrofossil biostratigraphy; vertical bars mark the occurrence of identified brachiopod taxa: thick – common, thin – rare (see text for further details).

Macrofossil assemblages at Chełm are rather poor in diversity and number of specimens, being dominated by small- to medium-sized bivalves, echinoids and ammonites (Dubicka & Peryt, Reference Dubicka and Peryt2011; Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021). In terms of macrofossil biostratigraphy (Fig. 2), the chalk succession at Chełm has been assigned by Machalski (Reference Machalski2005) and Dubicka & Peryt (Reference Dubicka and Peryt2011) to the lower upper Maastrichtian Belemnitella junior Zone and the Spyridoceramus tegulatusBelemnitella junior Zone in the conventional subdivisions of the Boreal Maastrichtian in Europe (see, e.g., Błaszkiewicz, Reference Błaszkiewicz1980; Schulz & Schmid, Reference Schulz and Schmid1983; Christensen et al., Reference Christensen, Schmid and Schulz2005). According to Walaszczyk et al. (Reference Walaszczyk, Dubicka, Olszewska-Nejbert and Remin2016), the Chełm succession represented the uppermost ‘true’ (non-tegulated) inoceramid ‘Inoceramusianjonaensis Zone also put in the lower upper Maastrichtian, as based on data from the Vijlen Member in northeast Belgium and the Aachen area in western Germany (see Walaszczyk et al., Reference Walaszczyk, Jagt and Keutgen2010). It is worth mentioning in this context that no ‘true’ inoceramids are known to date from Chełm, Spyridoceramus tegulatus (von Hagenow, Reference Hagenow1842) being the sole representative of the ‘tegulated inoceramids’ throughout the section. Belemnites at Chełm are represented by very rare individuals of Belemnitella junior Nowak, Reference Nowak1913 and B. lwowensis Naidin, Reference Naidin1952 (see Dubicka & Peryt, Reference Dubicka and Peryt2011). Both species are present in the lower part of the upper Maastrichtian of the Hemmoor section, northwest Germany and in the Haccourt-Lixhe area of northeast Belgium (Christensen et al., Reference Christensen, Schmid and Schulz2005). In ammonite terms, levels V and IV belong to the lower upper Maastrichtian scaphitid ammonite Hoploscaphites constrictus lvivensis Zone (Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021; Fig. 2 herein).

Dubicka & Peryt (Reference Dubicka and Peryt2012) assigned the Chełm section to their local foraminiferal zones VIII (lowest part), IX (bulk of section) and X (top of section). Based on planktic foraminiferal spectra (Dubicka & Peryt, Reference Dubicka and Peryt2011, Reference Dubicka and Peryt2012) and the shape of the carbon isotope curve, Machalski et al. (Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021; Supplementary Information) concluded that the Chełm section corresponded to the interval between c. 180 and 115 m in the Stevns-1 reference borehole in Denmark, as described by Thibault et al. (Reference Thibault, Harlou, Schovsbo, Schiøler, Minoletti, Galbrun, Lauridsen, Sheldon, Stemmerik and Surlyk2012) and Surlyk et al. (Reference Surlyk, Rasmussen, Boussaha, Schiøler, Schovsbo, Sheldon, Stemmerik and Thibault2013). This interval represents the Hvidskud Member of the Møns Klint Formation, which comprises the topmost part of the UC19, entire UC20a and lower part of the UC20b-c nannofossil zones, and three magnetostratigraphic zones, namely 31n, 30r and 30n. This corresponds to the topmost part of the lower Maastrichtian (level VI not studied for brachiopods for the present paper) and the lower part of the upper Maastrichtian (remaining levels, see Supplementary Information figure 2 in Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021).

The Chełm chalk was deposited in an epicontinental setting, in the eastern part of the Boreal Chalk Sea of Europe (e.g., Surlyk et al., Reference Surlyk, Dons, Clausen and Higham2003; Engelke et al., Reference Engelke, Esser, Linnert, Mutterlose and Wilmsen2016, Reference Engelke, Linnert, Mutterlose and Wilmsen2017). The Chełm chalk matches the characteristics of the ‘benthos-poor’ variety of white chalk in the Boreal Chalk Sea facies model, representing the deepest epicontinental chalk facies, deposited below the photic zone and storm wave base (Surlyk et al., Reference Surlyk, Dons, Clausen and Higham2003, Fig. 13.7; see also Surlyk & Birkelund, Reference Surlyk, Birkelund, Kauffman and Hazel1977 and Hansen & Surlyk, Reference Hansen and Surlyk2014). Similar to other examples of this white chalk subfacies, the Chełm chalk is monotonous and lacks hardgrounds, omission surfaces, scour horizons, tabular fossil concentrations and flint nodules. Its macrofossil content is typified by a rather poor macrobenthic assemblage, a predominance of Zoophycos burrows (at least in the lower levels), a relative abundance of ammonites and an extreme rarity of belemnites represented solely by adult individuals (Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021). A shallowing-upwards trend is inferred from planktic foraminiferal data for the succession (Dubicka & Peryt, Reference Dubicka and Peryt2011, Reference Dubicka and Peryt2012), with depth estimates ranging from >100 m for the lower levels to several dozen metres in the uppermost part of the section (Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021). Correlation with the planktic foraminiferal spectra recorded from equivalent Maastrichtian levels in the Middle Vistula River section (central Poland) suggests that the record of the maximum mid-Maastrichtian sea level rise should be expected just beneath the bottom of the section exposed at Chełm (Dubicka & Peryt, Reference Dubicka and Peryt2011, Reference Dubicka and Peryt2012).

Material and methods

The brachiopod samples studied herein were collected in the late 1980s, at a time when level I of the Chełm quarry was still in existence, but level VI had yet to be developed. Therefore, these samples originate from levels I to V (Fig. 2).

The brachiopod assemblage studied, 729 specimens in all, comprise both macro- and micromorphic brachiopods. All micromorphic brachiopods studied herein come from bulk samples from levels I to V. Each of these samples weighed between 8 and 12 kg, yielding 109 specimens from level I, 94 from II, 267 from III, 87 from IV and 172 from V. After boiling in a Glauber-Salt solution, the samples were washed and wet-sieved at mesh widths of 0.5 mm at the laboratory. Only few macrobrachiopods were collected directly in the field by handpicking from chalk surfaces. The frequency of brachiopods at each level is low, and their preservation is relatively poor – many individuals are damaged or crushed and there are also many fragments in washing residues. It is impossible to assess whether the fragmentation resulted from sample processing or from original fossil preservation. Considering this and the fact that the precise weight of each sample was not recorded before preparation, the brachiopod frequency is given only in qualitative terms (i.e., rare vs common where a number of up to 25 specimens per level is considered as rare) in the present paper (Fig. 2). In addition to brachiopods, the washing residues from Chełm yielded a rather meagre lot of organic remains composed of fragments of calcitic bivalve shells, cirripede plates, echinoderm remains (crinoid columnals and echinoid spines) and rare bryozoan fragments.

Specimens selected for scanning electron microscopy were mounted on stubs, coated with platinum and photographed using a Philips XL-20 microscope at the Institute of Paleobiology, Warszawa. The material is housed at the Institute of Paleobiology under the collection number ZPAL Bp.50.

Taxonomy

In total, 15 brachiopod taxa have been recovered from the chalk succession at Chełm (Table 1). These are Lingula cretacea Lundgren, Reference Lundgren1885, Isocrania costata (Sowerby, Reference Sowerby1823) (Fig. 3G–I), Cryptoporella antiqua Bitner & Pisera, Reference Bitner and Pisera1979 (Fig. 4A–H), Cretirhynchia sp., Neoliothyrina sp., Carneithyris sp., Terebratulina chrysalis (Schlotheim, Reference Schlotheim1813) (Fig. 3C), T. faujasi (Roemer, Reference Roemer1841), T. longicollis Steinich, Reference Steinich1965 (Fig. 3A, B), Terebratulina spp., Gisilina sp., Bronnothyris bronni (Roemer, Reference Roemer1841) (Fig. 3E, F), Magas chitoniformis (Schlotheim, Reference Schlotheim1813) (Fig. 3D), Leptothyrellopsis polonicus Bitner & Pisera, Reference Bitner and Pisera1979 and ?Aemula sp. (Fig. 2; Table 1). Only Cryptoporella antiqua and some species of Terebratulina are common in the material studied, while others are rare (Fig. 2; Table 1). Six taxa were identified at all levels sampled for brachiopods (Fig. 2). Of these, the presence of Lingula cretacea is worth noting; this is represented by poorly preserved fragments throughout the section. Cretaceous to Recent representatives of Lingula have been characterised by a very low taphonomic potential in view of thin fragile shell, composed of chitinous and phosphatic layers (Emig, Reference Emig1990; Kowalewski & Flessa, Reference Kowalewski and Flessa1996).

Figure 3. Selected brachiopods from the lower upper Maastrichtian white chalk exposed at Chełm. A, B. Terebratulina longicollis; A – dorsal view of complete specimen, level IV, ZPAL Bp.50/8; B – inner view of dorsal valve to show brachidium, level V, ZPAL Bp.50/9; C – Terebratulina chrysalis, dorsal view of complete young specimen, level III, ZPAL Bp.50/7; D – Magas chitoniformis, inner view of dorsal valve, level III, ZPAL Bp.50/10; E, F – Bronnothyris bronni, ventral and dorsal views of complete specimen, level II, ZPAL Bp.50/11; G–I – Isocrania costata; G – inner view of ventral valve, level II, ZPAL Bp.50/1; H, I – outer and inner views of dorsal valve, level II, ZPAL Bp.50/2. All SEM photomicrographs.

Figure 4. Cryptoporella antiqua from the lower upper Maastrichtian white chalk exposed at Chełm, ZPAL Bp. 50/3-6. A, B – Dorsal view of complete specimen and enlargement of umbonal part to show details of beak, respectively. C–E – Inner view of ventral valve, enlargement of umbonal part and oblique view to show dentral plates, respectively. F – Inner view of ventral valve. G, H – Inner view of dorsal valve and enlargement of posterior part to show details of cardinalia, respectively. All SEM photomicrographs.

Table 1. Ecological groups of brachiopods identified from the lower upper Maastrichtian chalk exposed at Chełm and their relative abundance in the section (generalised, based on all levels). In parentheses, numbers of the groups after Schrøder & Surlyk (Reference Schrøder and Surlyk2020) are shown.

There is some variation in brachiopod diversity throughout the section, ranging from a minimum number of 9 taxa recorded from level IV to a maximum of 13 taxa from level II (Fig. 2). The number of specimens also varies between samples, ranging from a minimum number of 87 specimens in a sample from level IV to a maximum of 267 from level III (Fig. 2).

Most of the taxa identified at Chełm are common in the white chalk facies of northwest Europe, which are characterised by long stratigraphical ranges and a wide geographical distribution (compare Fig. 2 and Table 1 herein with Surlyk, Reference Surlyk1984, Fig. 2; see also Surlyk, Reference Surlyk1972). A notable exception is Cryptoporella antiqua (Fig. 4A–H), known so far only from the lower to upper Campanian of Mielnik (Bitner & Pisera, Reference Bitner and Pisera1979; stratigraphy based on Bojanowski et al., Reference Bojanowski, Dubicka, Minoletti, Olszewska-Nejbert and Surowski2017). Contrary to the Mielnik assemblage, this species dominates in the material from Chełm, constituting more than 40% of the material. Another species erected based on Mielnik material by Bitner & Pisera (Reference Bitner and Pisera1979) is Leptothyrellopsis polonicus. This was recovered by these authors from the chalk interval corresponding to the lower Campanian in currently accepted stratigraphy of the Mielnik section (Bojanowski et al., Reference Bojanowski, Dubicka, Minoletti, Olszewska-Nejbert and Surowski2017). This species has subsequently been recognised in the chalk facies of late Campanian and early Maastrichtian age in northern Europe (Surlyk, Reference Surlyk1982; Johansen & Surlyk, Reference Johansen and Surlyk1990; MacKinnon et al., Reference MacKinnon, Simon and Bitner1998; Simon & Mottequin, Reference Simon and Mottequin2018).

With a total of 15 identified taxa, the Chełm assemblage is rather poor in comparison with the most prolific white chalk brachiopod assemblages, described from the lower lower and upper upper Maastrichtian of Denmark (Surlyk, Reference Surlyk1972, Fig. 3; Surlyk, Reference Surlyk1984, Fig. 1). For example, the assemblage from the Argyrotheca stevensis–Magas chitoniformis Zone at the top of the Danish Maastrichtian comprises 23 species, and those from the Rugia spinosaTerebratulina subtilis, T. subtilisTrigonosemus pulchellus and T. pulchellusT. pulchellus zones from the middle portion of the lower Maastrichtian yield 22, 23 and 24 species, respectively. In contrast, the assemblage from the Rugia tenuicostataMeonia semiglobularis Zone of Surlyk (Reference Surlyk1984) comprises 16 species, which is the minimum number for the Danish Maastrichtian, matching well the Chełm assemblage as far as taxonomic diversity is concerned.

In terms of number of individuals per standard 10 kg sample, the Danish chalk assemblages yield from over 3,000 specimens (Argyrotheca stevensisMagas chitoniformis and Terebratulina subtilis–Trigonosemus pulchellus zones) to several hundred specimens in the Rugia tenuicostata–Meonia semiglobularis Zone (Surlyk, Reference Surlyk1972, Fig. 3). The specimen abundance at Chełm, ranging from 87 to 267 specimens per sample, is much lower than in any of the samples studied by Surlyk, including those from the Rugia tenuicostata–Meonia semiglobularis Zone, which are the poorest in specimens within the entire Danish Maastrichtian.

Stratigraphical position

As pointed out above, the Chełm assemblage is of relatively low diversity and abundance and is dominated by stratigraphically long-ranging forms which are known from the upper Campanian and Maastrichtian. In terms of the micromorphic brachiopod zonation of the Danish chalk (Surlyk, Reference Surlyk1972, Reference Surlyk1984), the assemblage studied herein is best comparable to the brachiopod assemblage from the Rugia tenuicostata–Meonia semiglobularis Zone (= tenuicostata-semiglobularis Zone in Surlyk, Reference Surlyk1984, abbreviated t-s, referred also to as Zone 7 in Surlyk, Reference Surlyk1970). The base of this zone was defined by Surlyk (Reference Surlyk1984) by the last occurrence of Rugia tenuicostata Steinich, Reference Steinich1963, and the top by the appearance of Meonia semiglobularis (Posselt, Reference Posselt1894). Both these morphologically distinctive species are absent at Chełm (Fig. 2; Table 1). The stratotype of the Rugia tenuicostata–Meonia semiglobularis Zone is sample 82 from the Hemmoor section, northern Germany, corresponding to the upper lower Maastrichtian part of the Hemmoor succession (Surlyk, Reference Surlyk1984).

Schulz & Schmid (Reference Schulz and Schmid1983, Fig. 3) correlated Zone 7 of Surlyk (Reference Surlyk1970), that is, the Rugia tenuicostata–Meonia semiglobularis Zone of Surlyk (Reference Surlyk1984), with the upper lower Maastrichtian belemnite Belemnella cimbrica and B. fastigata zones, making the appearance of Meonia semiglobularis, a marker for the higher Zone 8 of Surlyk, just beneath marl layer M-900. This bed has been selected as the conventional boundary between the lower and upper Maastrichtian at Hemmoor (e.g., Schulz & Schmid, Reference Schulz and Schmid1983; Christensen et al., Reference Christensen, Schmid and Schulz2005). The same upper lower Maastrichtian position of Zone 7 is presented by Reich & Frenzel (Reference Reich and Frenzel2002, Fig. 7) for the Maastrichtian chalk succession of the Isle of Rügen, northeast Germany. In contrast, the Chełm assemblage is recorded from the lower upper Maastrichtian Spyridoceramus tegulatusBelemnitella junior Zone sensu Schulz & Schmid (Reference Schulz and Schmid1983), so comes from the Chełm eqivalents of Zone 8 at Hemmoor. On the other hand, the lower upper Maastrichtian position of the Rugia tenuicostata–Meonia semiglobularis Zone is suggested on the log of Stevns 1 borehole by Surlyk et al., (Reference Surlyk, Rasmussen, Boussaha, Schiøler, Schovsbo, Sheldon, Stemmerik and Thibault2013, appendix 2). The problem of apparent diachroneity of various biostratigraphical markers in the Boreal Maastrichtian of Europe is beyond the scope of the present work.

Palaeoecology

Except for burrowing Lingula, all brachiopods from the European white chalk in general, and from the Chełm succession in particular, represent a guild of fixo- and libero-sessile epifaunal suspension feeders as distinguished by Engelke et al., (Reference Engelke, Esser, Linnert, Mutterlose and Wilmsen2016, Reference Engelke, Linnert, Mutterlose and Wilmsen2017) in their study of early Maastrichtian macrobenthos at Kroonsmoor, northwest Germany. In view of the ecological requirements of this group, the development of the Late Cretaceous brachiopod communities in the Boreal Chalk Sea of Europe must have been controlled largely by two interrelated environmental factors: 1) input of food and nutrients, and 2) availability of minute skeletal substrates which would have been suitable for brachiopod settlement (Surlyk, Reference Surlyk1972; Hansen & Surlyk, Reference Hansen and Surlyk2014; Engelke et al., Reference Engelke, Esser, Linnert, Mutterlose and Wilmsen2016, Reference Engelke, Linnert, Mutterlose and Wilmsen2017). Both factors were, in turn, indirectly influenced by the depth of the Boreal Chalk Sea and its variations (e.g., Hansen & Surlyk, Reference Hansen and Surlyk2014). The substrate–brachiopod relationship is easiest to grasp based on simple geological and palaeontological evidence and is considered in more detail below.

According to Schrøder & Surlyk (Reference Schrøder and Surlyk2020), the white chalk brachiopods may be subdivided into seven groups in terms of their adaptations and strategies to live on the sea bottom. Based on that paper, we characterise these groups as follows: 1) micromorphic species attached with a pedicle and able to use very small, hard substrates; 2) medium- to large-sized species attached with a pedicle to large, hard substrates; 3) species attached directly to the soft sediment with a rootlet pedicle; 4) secondarily free-living pedunculate species, attached to the substrate by pedicle at the juvenile stages; 5) species attached by cementation by the whole surface of the ventral valve; 6) species attached by cementation in the juvenile stage, but secondarily free-living in the adult stage, therefore possessing a small attachment surface on the ventral valve; and 7) species burrowed into the soft-bottom substrate. Table 1 presents the assignment of the brachopod taxa from Chełm to these categories along their relative abundance. Except for group 5, all the groups distinguished by Schrøder & Surlyk (Reference Schrøder and Surlyk2020) are present in the Chełm material, with a clear predominance of group 1 (Table 1).

As demonstrated by Surlyk (Reference Surlyk1972, Fig. 3), there is a striking parallelism between the washing residue curve (approximately corresponding to the bryozoan curve) and the curves illustrating the brachiopod species and specimen-abundance throughout the Danish chalk succession (see also Surlyk & Birkelund, Reference Surlyk, Birkelund, Kauffman and Hazel1977). According to these authors, the low brachiopod diversity and abundance in the upper lower and lower upper Maastrichtian assemblages, including that from the Rugia tenuicostata–Meonia semiglobularis Zone, resulted from low availability of substrates suitable for colonisation by brachiopods on the sea floor, reflected in low numbers of skeletal hash, mainly bryozoans, in the washed residues. In contrast, the lower lower and uppermost Maastrichtian maxima in brachiopod diversity and abundance reflect a superabundance of predominantly bryozoan hash on the sea bottom, discernible as relevant peaks in washing residues (Surlyk, Reference Surlyk1972, Fig. 3). The three curves seem, in turn, to be indirectly related to bathymetry, with depauperate brachiopod communities linked to the deeper-water portions of the chalk succession (Surlyk, Reference Surlyk1972; see also Hansen & Surlyk, Reference Hansen and Surlyk2014).

The brachiopod assemblage from the Chełm succession matches the above observations, as the Chełm chalk represents a relatively deep-water, ‘benthos-poor’ subfacies of the white chalk (Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021), characterised by a paucity of minute skeletal substrates on the sea floor. Minor variations in brachiopod diversity and abundance at Chełm (Fig. 2) are not easy to explain with the evidence at hand. The differences in diversity may simply result from sampling bias, but the highest abundance at level III (Fig. 2) may reflect a temporal improvement of environmental conditions on the sea floor. Notably, an increase in abundance of epifaunal suspension-feeding bivalves has been recorded from that level by Machalski et al., (Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021, Supplementary Information). Minor temperature variations inferred from oxygen stable isotopic analyses of benthic foraminiferal tests from Chełm (Machalski et al., Reference Machalski, Owocki, Dubicka, Malchyk and Wierny2021, Fig. 2) are not correlatable in any way with the changes in brachiopod abundance reported herein.

Conclusions

  • A brachiopod assemblage is described for the first time from the lower upper Maastrichtian (Upper Cretaceous) white chalk succession exposed at Chełm, eastern Poland.

  • The assemblage comprises 15 species in total, with taxonomic diversity and specimen abundance varying between the samples studied.

  • The brachiopod assemblage from Chełm is relatively poor in terms of taxonomic diversity and specimen abundance and is dominated by stratigraphically long-ranging species.

  • In terms of the micromorphic brachiopod zonation of the European Boreal chalk succession, the brachiopod assemblage from Chełm is best comparable to that from the Rugia tenuicostataMeonia semiglobularis Zone as distinguished in the white chalk successions in Denmark and northern Germany, although this zone is usually placed there in the upper lower Maastrichtian.

  • The brachiopod assemblage studied is typical of a relatively deep-water and ‘benthos-poor’ subfacies of white chalk of the Boreal Chalk Sea, the Chełm chalk belongs to; its development seems to have been controlled largely by a low availability of minute skeletal substrates suitable for brachiopod settlement.

Acknowledgements

The authors are indebted to Aleksandra Hołda-Michalska for computer processing of line illustrations and to the staff of Cemex Polska for allowing access to the chalk quarry at Chełm. John W.M. Jagt is thanked for linguistic correction of the text and two anonymous journal reviewers for their constructive criticism.

Footnotes

In: Jagt, John W.M., Fraaije, René H.B., Jagt-Yazykova, Elena A. & Vellekoop, Johan (eds). Aspects of Maastrichtian (Late Cretaceous) stratigraphy and palaeontology.

References

Bitner, M.A. & Pisera, A., 1979. Brachiopods from the Upper Cretaceous chalk of Mielnik. Acta Geologica Polonica 29: 6788.Google Scholar
Błaszkiewicz, A., 1980. Campanian and Maastrichtian ammonites of the Middle Vistula River Valley, Poland: a stratigraphic-paleontological study. Prace Instytutu Geologicznego 92: 163.Google Scholar
Bojanowski, M.J., Dubicka, Z., Minoletti, F., Olszewska-Nejbert, D. & Surowski, M., 2017. Stable C and O isotopic study of the Campanian chalk from the Mielnik section (eastern Poland): signals from bulk rock, belemnites, benthic foraminifera, nannofossils and microcrystalline cements. Palaeogeography, Palaeoclimatology, Palaeoecology 465: 193211. DOI: 10.1016/j.palaeo.2016.10.032.Google Scholar
Christensen, W.K., Schmid, F. & Schulz, M.-G., 2005. Belemnitella from the Upper Maastrichtian of Hemmoor, Northwest Germany. Geologisches Jahrbuch A157(for 2004): 2367.Google Scholar
Dubicka, Z. & Peryt, D., 2011. Integrated biostratigraphy of Upper Maastrichtian chalk at Chełm (SE Poland). Annales Societatis Geologorum Poloniae 81: 185197.Google Scholar
Dubicka, Z. & Peryt, D., 2012. Latest Campanian and Maastrichtian paleoenvironmental changes: implications from an epicontinental sea (SE Poland and western Ukraine). Cretaceous Research 37: 272284. DOI: 10.1016/j.cretres.2012.04.009.Google Scholar
Emig, C.C., 1990. Examples of post-mortality alternation in recent brachiopod shells and (paleo)ecological consequences. Marine Biology 104: 233238.Google Scholar
Engelke, J., Esser, K.J.K., Linnert, C., Mutterlose, J. & Wilmsen, M., 2016. The benthic macrofauna from the Lower Maastrichtian chalk of Kronsmoor (northern Germany, Saturn quarry): taxonomic outline and palaeoecologic implications. Acta Geologica Polonica 66: 671694.Google Scholar
Engelke, J., Linnert, C., Mutterlose, J. & Wilmsen, M., 2017. Early Maastrichtian benthos of the chalk at Kronsmoor, northern Germany: implications for Late Cretaceous environmental change. Palaeobiodiversity and Palaeoenvironments 97: 703722.Google Scholar
Ernst, H., 1984. Ontogenie, Phylogenie und Autökologie des inarticulaten Brachiopoden Isocrania in der Schreibkreidefazies NW-Deutschlands (Coniac bis Maastricht). Geologisches Jahrbuch A77: 3105.Google Scholar
Hagenow, F. von, 1842. Monographie der Rugen’schen Kreide-Versteinerungen III. Abtheilung: Mollusken. Neues Jahrbuch für Mineralogie, Geognosie, Geologie, und Petrefakten-Kunde 1842: 528579.Google Scholar
Hansen, T. & Surlyk, F., 2014. Marine macrofossil communities in the uppermost Maastrichtian chalk of Stevns Klint, Denmark. Palaeogeography, Palaeoclimatology, Palaeoecology 399: 323344.CrossRefGoogle Scholar
Jelby, M.E., Thibault, N.R., Surlyk, F., Ullmann, C.V., Harlou, R. & Korte, C., 2014. The lower Maastrichtian Hvidskud succession, Møns Klint, Denmark: calcareous nannofossil biostratigraphy, carbon isotope stratigraphy, and bulk and brachiopod oxygen isotopes. Bulletin of the Geological Society of Denmark 62: 89104.Google Scholar
Johansen, M.B., 1987a. Brachiopods from the Maastrichtian-Danian boundary sequence at Nye Kløv, Jylland, Denmark. Fossils & Strata 20: 1100.Google Scholar
Johansen, M.B., 1987b. The micromorphic brachiopod genus Rugia Steinich from the Middle Coniacian-Lower Maastrichtian chalk of Lägerdorf and Kronsmoor, northwest Germany. Mitteilungen aus dem Geologisch-Paläontologischen Institut der Universität Hamburg 63: 127183.Google Scholar
Johansen, M.B. & Surlyk, F., 1990. Brachiopods and the stratigraphy of the Upper Campanian and Lower Maastrichtian chalk of Norfolk, England. Palaeontology 33: 823872.Google Scholar
Kowalewski, M. & Flessa, K.W., 1996. Improving with age: the fossil record of lingulide brachiopods and the nature of taphonomic megabiases. Geology 24: 977980.Google Scholar
Lundgren, B., 1885. Undersökningar öfver Brachiopoderna i Sverges kritsystem. Ǻrsskrift Lunds Universitet 20: 172.Google Scholar
Machalski, M., 2005. Late Maastrichtian and earliest Danian scaphitid ammonites in central Europe: taxonomy, evolution, and extinction. Acta Palaeontologica Polonica 50: 653696.Google Scholar
Machalski, M., Owocki, K., Dubicka, Z., Malchyk, O. & Wierny, W., 2021. Stable isotopes and predation marks shed new light on ammonoid habitat depth preferences. Scientific Reports 11(1): 22730. DOI: 10.1038/s41598-021-02236-9.Google Scholar
MacKinnon, D.I., Simon, E. & Bitner, M.A., 1998. A reappraisal of the problematic European, Late Cretaceous brachiopod Leptothyrellopsis polonicus Bitner & Pisera, 1979. Bulletin de l’Institut royal des Sciences naturelles de Belgique, Sciences de la Terre 68: 175180.Google Scholar
Naidin, D.P., 1952. Upper Cretaceous belemnites of western Ukraine. Trudy Moskovskogo Geologicheskogo Razvedochnogo Instituta imieni S. Ordzhonikidze, vol. 27: 1170, [In Russian].Google Scholar
Nowak, J., 1913. Untersuchungen über die Cephalopoden der oberen Kreide in Polen. III Teil. Bulletin de l’Académie des Sciences de Cracovie. Classe des Sciences Mathématique et Naturelles. Série B. Sciences Naturelles 335: 1913–1415.Google Scholar
Posselt, H.J., 1894. Brachiopoderne i den danske Kridtformation. Danmarks Geologiske Undersøgelse, Second Series 4: 159.Google Scholar
Reich, M. & Frenzel, P., 2002. Die Fauna und Flora der Rügener Schreibkreide (Maastrichtium, Ostsee). Archiv für Geschiebekunde 3: 73284.Google Scholar
Roemer, A., 1841. Die Versteinerungen des norddeutschen Kreidegebirges. Hannover, 1145.Google Scholar
Schlotheim, E.F. von, 1813. Beiträge zur Naturgeschichte der Versteinerungen in geognostischer Hinsicht. Leonhard’s Taschenbuch für die gesammte Mineralogie 7: 1134.Google Scholar
Schrøder, A.E. & Surlyk, F., 2020. Adaptive brachiopod morphologies in four key environments of the Late Cretaceous-Danian Chalk Sea of northern Europe: a comparative study. Cretaceous Research 107: 104288. DOI: 10.1016/j.cretres.2019.104288.Google Scholar
Schulz, M.-G. & Schmid, F., 1983. Das Ober-Maastricht von Hemmoor (N-Deutschland): Faunenzonen-Gliederung und Korrelation mit dem Ober-Maastricht von Dänemark und Limburg. Newsletters on Stratigraphy 13: 203215.Google Scholar
Simon, E. & Mottequin, B., 2018. Extreme reduction of morphological characters: a type of brachidial development found in several Late Cretaceous and Recent brachiopod species – new relationships between taxa previously listed as incertae sedis . Zootaxa 4444(1): 001024.Google Scholar
Sowerby, C. de, 1823. Genera of recent and fossil shells. 4. Sherwood and Co, London, pp. 115160.Google Scholar
Steinich, G., 1963. Drei neue Brachiopodengattungen der Subfamilie Cancellothyridinae Thomson. Geologie 12(6): 732740.Google Scholar
Steinich, G., 1965. Die artikulaten Brachiopoden der Rügener Schreibkreide (Unter-Maastricht). Paläontologische Abhandlungen, Abteilung A, Paläozoologie 2: 1220.Google Scholar
Surlyk, F., 1970. Die Stratigraphie des Maastricht von Dänemark und Norddeutschland aufgrund von Brachiopoden. Newsletters on Stratigraphy 12: 716.Google Scholar
Surlyk, F., 1972. Morphological adaptation and population structures of the Danish chalk brachiopods (Maastrichtian, Upper Cretaceous). Det Kongelige Danske Videnskabernes Selskab. Biologiske Skrifter 19: 167.Google Scholar
Surlyk, F., 1982. Brachiopods from the Campanian-Maastrichtian boundary sequence, Kronsmoor (NW Germany). Geologisches Jahrbuch A61: 259277.Google Scholar
Surlyk, F., 1984. The Maastrichtian Stage in NW Europe, and its brachiopod zonation. Bulletin of the Geological Society of Denmark 33: 217224.Google Scholar
Surlyk, F. & Birkelund, T., 1977. An integrated stratigraphical study of fossil assemblages from the Maastrichtian White Chalk of northwestern Europe. In: Kauffman, E.G. & Hazel, J.E. (eds): Concepts and Methods in Biostratigraphy. Hitchinson and Ross Inc. (Stroudsbourgh, PA): 257281.Google Scholar
Surlyk, F., Dons, T., Clausen, C.K. & Higham, J., 2003. Upper Cretaceous. In: The Millennium Atlas: petroleum geology of the central and northern North Sea. Geological Society of London: 213233.Google Scholar
Surlyk, F., Rasmussen, S.L., Boussaha, M., Schiøler, P., Schovsbo, N.H., Sheldon, E., Stemmerik, L. & Thibault, N.R., 2013. Upper Campanian-Maastrichtian holostratigraphy of the eastern Danish Basin. Cretaceous Research 46: 232256.CrossRefGoogle Scholar
Thibault, N., Harlou, R., Schovsbo, N., Schiøler, P., Minoletti, F., Galbrun, B., Lauridsen, B.W., Sheldon, E., Stemmerik, L. & Surlyk, F., 2012. Upper Campanian-Maastrichtian nannofossil biostratigraphy and high-resolution carbon-isotope stratigraphy of the Danish Basin: towards a standard δ13C curve for the Boreal Realm. Cretaceous Research 33: 7290.CrossRefGoogle Scholar
Walaszczyk, I., Dubicka, Z., Olszewska-Nejbert, D. & Remin, Z., 2016. Integrated biostratigraphy of the Santonian through Maastrichtian (Upper Cretaceous) of extra-Carpathian Poland. Acta Geologica Polonica 66: 321358.Google Scholar
Walaszczyk, I., Jagt, J.W.M. & Keutgen, N., 2010. The youngest Maastrichtian ‘true’ inoceramids from the Vijlen Member (Gulpen Formation) in northeastern Belgium and the Aaschen area (Germany). Netherlands Journal of Geosciences 89(2): 147167.CrossRefGoogle Scholar
Figure 0

Figure 1. A. Location of the Chełm site in Poland (modified from Machalski et al., 2021, Fig. 1). B. Satellite view of the Chełm chalk pit (Google Maps, https://www.google.com/maps/place/Chełm).

Figure 1

Figure 2. Distribution of brachiopod species recognised in the lower upper Maastrichtian section exposed at Chełm along the section log and macrofossil biostratigraphy; vertical bars mark the occurrence of identified brachiopod taxa: thick – common, thin – rare (see text for further details).

Figure 2

Figure 3. Selected brachiopods from the lower upper Maastrichtian white chalk exposed at Chełm. A, B. Terebratulina longicollis; A – dorsal view of complete specimen, level IV, ZPAL Bp.50/8; B – inner view of dorsal valve to show brachidium, level V, ZPAL Bp.50/9; C – Terebratulina chrysalis, dorsal view of complete young specimen, level III, ZPAL Bp.50/7; D – Magas chitoniformis, inner view of dorsal valve, level III, ZPAL Bp.50/10; E, F – Bronnothyris bronni, ventral and dorsal views of complete specimen, level II, ZPAL Bp.50/11; G–I – Isocrania costata; G – inner view of ventral valve, level II, ZPAL Bp.50/1; H, I – outer and inner views of dorsal valve, level II, ZPAL Bp.50/2. All SEM photomicrographs.

Figure 3

Figure 4. Cryptoporella antiqua from the lower upper Maastrichtian white chalk exposed at Chełm, ZPAL Bp. 50/3-6. A, B – Dorsal view of complete specimen and enlargement of umbonal part to show details of beak, respectively. C–E – Inner view of ventral valve, enlargement of umbonal part and oblique view to show dentral plates, respectively. F – Inner view of ventral valve. G, H – Inner view of dorsal valve and enlargement of posterior part to show details of cardinalia, respectively. All SEM photomicrographs.

Figure 4

Table 1. Ecological groups of brachiopods identified from the lower upper Maastrichtian chalk exposed at Chełm and their relative abundance in the section (generalised, based on all levels). In parentheses, numbers of the groups after Schrøder & Surlyk (2020) are shown.