Borucice Formation

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Borucice Formation
Stratigraphic range: Middle-Late Toarcian
~178–174  Ma
O
S
D
C
P
T
J
K
Pg
N
Type Geological formation
Unit of Kamienna Group
Sub-unitsIdzikowice Tracksite
Underlies
Overlies
Area Polish Basin
Thickness120 m (390 ft)
Lithology
PrimaryCoarse-fine-grained sandstone
Other Mudstone
Location
CountryFlag of Poland.svg  Poland
Type section
Named forafter the village of Borucice in Kujawy [1]
Named by Stefan Zbigniew Różycki (as Borucice Series) [1] [2]
Year defined1958
Relief Map of Poland.svg
Blue pog.svg
Borucice Formation (Poland)

Original Outcrop Location

The Borucice Formation, also known in older literature as the Borucice Series, is a Jurassic (Middle-Late Toarcian) geologic formation that extends to nearly whole of Poland. [3] [4] This formation represents the last sequence of the lower Jurassic in Poland, recovering the depositional sequences IX and X, and may even recover lowermost parts of the first Middle Jurassic sequence. [4] It represents mostly a series of alluvial (braided or meandering channel) depositional systems with subordinate intervals of deltaic deposits. Dinosaur Tracks are among the fossils that have been recovered from the formation. Most of the sediments of the Polish realm come from deltaic, fluvial and marine deposits. [5] It mainly consists of light whitish-grey, fine grained sandstones interbedded by clay containing plant detritus and minute fragments of coal. It also has dark grey mudstones with marine lamellibranches and an Upper Lias microfauna. [2] Its main equivalents are the Jurensismergel Formation of Germany, upper part of the Rya Formation (Southern Sweden)and the uppermost Sorthat Formation (Bornholm). [1] There are also coeval abandoned informal units in Poland: Upper Lisiec beds (Czêstochowa region), or the Kamień Beds (Pomerania region). [1]

Contents

Sedimentological evolution

On the Częstochowa region the sequences IX and X are developed mostly as alluvial, meandering river deposits with subordinate lacustrine lithofacies. [1] The Deltaic deposits are found on the Suliszowice 38 BN Borehole and the arki 89 ¯ borehole, and show how these delta deposits were preceded by a short-lived brackish-marine ingression associated with lagoonal mudstones and heteroliths. [1] The mudstone layers show high boron, along with the presence of pyrite concretions and more abundant Fodinichnia. [1] The local delta episode is reported from the depositional sequence IX, while the sequence X is developed as alluvial deposits (sandstones with trough cross bedding and rich plant fossils) with some intercalations of lacustrine deposits. [1]

On the Pomerania region the formation starts with a depositional sequence IX that begins with a common erosional surface seen on the Mechowo IG 1 borehole exposed by medium-to-fine-grained sandstones with trough cross bedding and horizontal bedding, that come from a series of from alluvial channels to distributary channels on depositional subsystems. [1] It is overlaid by sediments composed by mudstone and heterolithic lithofacies that point to a rise in the level of the local water, but unclear if derived from a sea ingression or from alluvial floodplain deposits, delta plain deposits or, delta-front deposits. [1] There are present coarsening-upwards cycles as well as slightly elevated boron content, which point to the dominated deposition of a delta. [1] The Depositional sequence X is composed mostly of a thin sedimentary package of coarse alluvial sediments resting on the erosional surface and topped with a thin mudstone bed with the Paxillitriletes phyllicus spore. [1]

Stratygraphic profile

The profiles recovered between Aleksandrów Kujawski and Rogoźno on the Kuyavian-Pomeranian Voivodeship the Borucice Formation is known as the top of the sandstone series. [6] There level is composed mostly by an admixture of coarse grain sandstone, which mark the beginning of a new sedimentary cycle. [6] It has inserts of clayey Clay loupes present as a subordinate role. Is disposed along the Krogniewice series, composed of sandstones, in its main mass probably containing only thin and rarely broken clay inserts, while in the uppermost part there is abundant inserts. This part of the highest level is the equivalent of multiple phases of levels VI A and VI B in the vicinity of Kiodawa. [6] Apparently, there is a lack of VI C level flashers in Krogniewice, which are eroded before the Aalenian level. Locally, the border section Middle/Lower Jurassic wasn't worked and the location of it wasn't completely solved. The Borucice Formation has a thickness here of 100–150 m. Overlaying the formation, is covered with transgression Aalenian sea sediments, where the transition, if exists, is gradual and small. [6]

Stratigraphy of the Borucice Formation at the Gorzów Wielkopolski IG 1 Borehole [7]
UnitLithologyThickness (metres)PalynologyFossil Fauna

Youngest

0.3 m of fine-grained gray sandstone, poorly preserved core, illegible layering; 0.7 m of medium-grained, gray sandstone, poorly preserved core, illegible layering

753.9–760.7 m; thickness 7 m

Non Reported

Non Reported

N1

0.5 m - fine-grained, gray sandstone, poorly preserved core, illegible layering; 0.3 m of gray mudstone, horizontal lamination; 2.4 m of core with medium-grained gray sandstone, silt clusters in the upper and lower part, in the bottom large diameter (a few centimeters), made of green clay and siderite pebbles ilaste (erosion of underlying tracks). A clear erosive surface at a depth of 767.4 m is sequence limit

760.7–767.4 3.2 m of core

Non Reported

Stratigraphy at the Studzianna Borehole [8]
UnitLithologyThickness (metres)Fossil Palynology/FloraFossil Fauna

Upper complex [8]

Light gray sandstones, fine and medium-grained, infused with silt and light gray and gray yellows; in the lower part more numerous medium-grain inserts; numerous remains of flora, muscovite, pyrite concentrations.

40–55 m

Medium complex [8]

Fine-grained sandstones with numerous overflows of clayey and rhizoids, of dark gray and gray mudstones, prelate avenues; flora, mica.

40–45 m

Lower complex [8]

Fine-grained sandstones with overgrowth of loam and gray mudstones, numerous in the upper part; Shoals of translators; pyrite, fine mica, flora.

45 m

Annelida

GenusSpeciesStratigraphic positionMaterialNotesImages

Dictyothylakos [9]

  • D. pesslerae
  • D. "sp. Sing.1964"
  • Brody-Lubienia borehole
  • Wolin IG-1 borehole
  • Ciechocinek 58 Borehole
  • Boroszów Borehole

Cocoons

Freshwater Clitellata Cocoons (Oligochaeta and Hirudinea), identified with palynological residues, and thought to be tridimensional nets of probable algal origin. [10] Fragmentary mesh-like networks of hapsine threads composed of a homogenous translucent material. They show the outer wall (hapsine) construction specific to clitellate annelids and lack an alytine (inner) layer. A disorderly meshwork of the hapsine layer and hapsine fibres of unequal thickness, are diagnostic of the type species Dictyothylakos pesslerae. The cocoons Dictyothylakos pesslerae resemble specially those of modern Leechs, and are common on flooded basin sediments, what implies not only the presence of parasitic leeches, but also the presence of large hosts nearby, what has been confirmed on the case of the Borucice Formation, thanks to the presence of dinosaur Footprints.

Example of leech cocoon Cocoon of Hirudo verbana.jpg
Example of leech cocoon
Placobdella, example of leech Placobdella papillifera (YPM IZ 059049).jpeg
Placobdella, example of leech

Actinopteri

GenusSpeciesLocationMaterialNotesImages

Palaeoniscidae [3]

Indeterminate

  • Łęczycy
  • Isolated left Dermosphenoid
  • Dorsal body with Scales
  • Referred Teeth

A Freshwater Osteichthyes, member of the family Palaeoniscidae inside Palaeonisciformes. Is similar to the genus Oxygnathus from the Sinemurian of England, though this last one is a preoccupied name shared with a beetle and comes from marine deposits. The presence of fish locally bolsters the case for persistent, deep interplain lakes where this fishes probably lived. The teeth assigned have multidenticulate appearance, that is linked with benthic scraping, and fished that fed primarily on algae. One genus of Paleonisciform, Hemicalypterus weiri from the late Triassic Chinle Formation is known to have that kind of dentition.

Dinosauria

GenusSpeciesLocationMaterialNotesImages

Anchisauripus [11] [12] [13]

  • A. isp.
  • Dąbie Tracksite

Footprints

Theropod tracks, type member of the ichnofamily Anchisauripodidae, incertae sedis inside Neotheropoda. Assigned to Coelophysidae-alike dinosaurs. Small to medium slender primitive predatory dinosaurs, related with genera such as Liliensternus , Tachiraptor , Zupaysaurus , Procompsognathus or contemporaneous taxa such as the North American Segisaurus .

Anchisauripus footprints belong to a genus similar to Procompsognathus Procompsognathus.jpg
Anchisauripus footprints belong to a genus similar to Procompsognathus

Grallator [13]

  • G. isp.
  • Cf.G. isp.
  • Dąbie Tracksite
  • Idzikowice Tracksite

Footprints

Theropod tracks, member of the ichnofamily Eubrontidae, incertae sedis inside Neotheropoda. The footprints from Smilow are small-sized, tridactyl and relatively narrow. forms Assigned to Coelophysidae-alike dinosaurs.

Grallator footprints belong to a genus similar to Camposaurus Camposaurus arizonensis.png
Grallator footprints belong to a genus similar to Camposaurus

Therangospodus [13] [14]

  • T. isp.
  • Cf.T. isp.
  • Dąbie Tracksite
  • Idzikowice Tracksite

Footprints

Theropod tracks, member of the ichnofamily Eubrontidae, incertae sedis inside Theropoda. They have resemblance with the non-Tetanureae Sinosaurus , but match with Late Jurassic Orionides trackmakers. The distinct phalangeal pads make unsure to distinguish Therangospodus from Megalosauripus . [15]

Therangospodus footprints can belong to relative of Magnosaurus Magnosaurus.jpg
Therangospodus footprints can belong to relative of Magnosaurus

Trisauropodiscus [13]

  • T. isp.
  • Dąbie Tracksite

Footprints

Ornithischian tracks, member of the ichnofamily Anomoepodidae, incertae sedis inside Ornithischia. This tracks resemble Middle Jurassic Ichnotaxa

Trisauropodiscus footprints can belong to relative of Hexinlusaurus Hexinlusaurus.jpg
Trisauropodiscus footprints can belong to relative of Hexinlusaurus

Palynology

The Polish Toarcian Palynology is assigned to the Paxillitriletes phyllicus (Ph) level (Isoetales), due to the abundance of this genus. [16] The lower part of the Toarcian level is even marked by the numerous occurrences of this species, sometimes also slightly precede the appearance of the genera Erlansonisporites sparassis (Selaginella-like) and Minerisporites volucris (Isoetaceae), as shown on the Gorzów Wlkp. IG 1 Borehole. [16] While the uppermost part is marked by a notorious decrease on the genus. [16] The most common species found in Poland in this interval include: Erlansonisporites sparassis, E. excavatus, Minerisporites volucris and Biharisporites scaber (Lycopodiopsida), with Aneuletes potera (Selaginellaceae) and Trileites murrayi (Selaginellaceae) on the upper levels. [16] The Toarcian disturbance of the carbon cycle, recorded on the Ciechocinek formation, coincides roughly with the appearance of Paxillitriletes phyllicus, that comes also with a clear change on the type of dominant palynomorphs recovered, changing from the predominance of pollen grains in the Upper Pliensbachian to Megaespores, what indicates a rather significant climate change, from moderate and relatively dry in late Pliensbachian to warm and humid in the early Toarcian. [16] This shift on the local climate does correlate temporarily with a global maritime transgression, which allows the exact stratigraphic-sequential correlation of this event, where the initial volcanism in the volcanic province Karoo-Ferrar rise the global temperature and generating rapid abnormalities in the carbon cycle, manifested in the form of the super-greenhouse effect in the atmospheric system. [16] Moreover, the mass occurrence of megaspore Paxillitriletes phyllicus correlate with the mentioned pulses and thus with extremely repetitive episodes hot and humid (greenhouse) climate, as the flora appears to be dominated by the family Isoetaceae, extremely hydrophilic, needing standing water to reproduction. [16]

The Borucice Formation is where Paxillitriletes phyllicus drops significantly, which indicates a return to a more moderate climate during sedimentation, corresponding to the post-variabilis age, and related with drier conditions of the Middle Toarcian, as recovered in places such as the Raasay Ironstone Formation of the Inner Hebrides. It is measured also on the Lusitanian Basin or on Yorkshire. The Changes on the flora are also correlated with the more fluvial sedimentation of the Formation. [16]

Plant Remains

The local material comes from the plant-rich, Floodplain Claystones of the Borucice Formation (on the Ciechocinek IG 1 borehole). The formation is composed mostly of fluvial sandstones, less frequently of fine-grained deposits, mostly channel fill deposits in the lower part, and crevasse splay and floodplain deposits in the upper part. [17]

GenusSpeciesStratigraphic positionMaterialNotesImages

Phlebopteris [17]

  • P. muensteri
  • Ciechocinek IG 1 borehole

One Incomplete Pinna

Affinities with Matoniaceae inside Gleicheniales. Leaves of medium-sized ferns, related to modern Matonia . This type of ferns are found on tropical-humid environments, where they form large-scale colonies with +1000 individuals. The genus Laccopteris was synonymized with Phlebopteris elegans. The species has a characteristic venation, not really typical of the genus, in which the veins usually form meshes, at least at the midrib.

Fossil Phlebopteris Laccopteris elegans - drawing of fossil.png
Fossil Phlebopteris

Pachypteris [18]

  • P. lanceolata
  • P. rhomboidalis
  • Cianowice 2 borehole

Pinnae

Affinities with the Peltaspermales inside Pteridospermatophyta. Bipinnate leaves, rachis longitudinally striated, with a long petiole and secondary rachises inserted oppositely to suboppositely on the upper side of the primary rachis. This Leaves belong to large Aboreal Ferns related with dry environments.

Otozamites [19] [20]

  • O. falsus
  • Wyszmontów Borehole

Pinnae

Affinities with the Bennettitales inside Bennettitopsida. A more arbustive type of Bennetite, abundant on the Pliensbachian-Toarcian strata along Eurasia, related to rather dry climates. The specimen displays a considerable similarity to Otozamites falsus from the deposits of the Lower Deltaic Series of Scarborough, England.

Otozamites Anina jurassic (15586380432).jpg

Pterophyllum [18]

  • P. thomasii
  • P. aequale
  • Cianowice 2 borehole

Pinnae

Affinities with the Williamsoniaceae inside Bennettitopsida. Leaves from Arboreal Bennetites, similar to the modern Cyca Encephalartos woodii , with robust Trunks, built for Dry and hot climates.

Pterophyllum longifolium e P. brevipenne.jpg

Cycadolepis [18]

  • C. sp.
  • Cianowice 2 borehole

Bennettitalean cone scales

Affinities with the Cycadeoidaceae inside Bennettitales.

Ctenis [18]

  • C. sp.
  • Cianowice 2 borehole

Bennettitalean cone scales

Affinities with Cycadales inside Cycadopsida.

Ctenis specimen Ctenis nilsonii.jpg
Ctenis specimen

Bilsdalea [18]

  • B. dura
  • Cianowice 2 borehole

Four pieces of cuticles

Incertae sedis affinities inside Pinales.

Mirovia [18]

  • M. szaferi
  • Cianowice 2 borehole

Three leaf fragments with apex, one fragment of cuticle, found on separate rock

Affinities with the Miroviaceae inside Pinales.

Brachyphyllum [18]

  • B. stemonium
  • Cianowice 2 borehole

Terminal leafy shoot fragments

Affinities with the Cheirolepidiaceae or Araucariaceae inside Pinales. This species is only known from the Middle Jurassic of Wildtshire.

Economical resources

Different options of hydrogen reservoirs underground storage were studied at the Łeba Elevation, Fore-Sudetic Monocline, Carpathian Foredeep, and salt stocks in the Polish Lowlands. The Borucice Formation covered in turn by Middle Jurassic fine-grained clastics especially of Aalenian and Bajocian age. The open porosity commonly ranges from 15% to 20% and pore water salinity reaches 200 g/L. [21]

CO2 storage of this formation has been view on several locations, such as the Kamionki Anticline. [22] The measured best conditions for geologic CO2 storage are displayed on the Borucice Beds and Lower Aalenian sandstones (Upper Sławęcin Beds) occurring below the Upper Aalenian clay-mud cap. [23] On the Zaosie Anticline various aquifers for CO2 storage were reviewed, including two Lower Jurassic ones: Borucice Formation and the Pliensbachian Komorowo Formation [24] The Borucice storage was tested in the boreholes of Zaosie 1 (at 500.0–665.0 m), Zaosie 2 (at 518.0–686.0 m), Zaosie 3 (at 537.0–680.0 m) and Budziszewice IG-1 (at 649.0–850.0 m), showing good reservoir properties (in terms of geological structure, thickness, lithology and physico-chemical characteristics) and is probably infiltrated by surface waters. [24] The volumetric CO2 storage capacity was calculated on approximately 222 million tons. [24] But due to the small depth of the aquifer, the Borucice Formation did not meet the requirements for a major CO2 storage. [24]

Gostynin region has shown favourable geothermal conditions Lower-Middle Jurassic formations, with the Gostynin IG-1/1a Borehole (at 2290–2245 m depth) used for preliminary evaluation of balneological properties and thermodynamical status of these waters. [25] The Borucice Formation (at 2702.6 – 2661.8 m; 2615–2605; 2310 – 2096.4 m), the occurrence of brines with Total Dissolved Solids from 99.4 to 110.0 g/dm3 was confirmed, characterized by low alteration of its chemical composition. [25]

See also

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The Marne di Monte Serrone is a geological formation in Italy, dating to roughly between 181 and 178 million years ago, and covering the early and middle Toarcian stage of the Jurassic Period of central Italy. It is the regional equivalent to the Toarcian units of Spain such as the Turmiel Formation, units in Montenegro, such as the Budoš Limestone and units like the Tafraout Formation of Morocco.

<span class="mw-page-title-main">Azilal Formation</span> Geological unit in Morocco

The Azilal Formation, also known as "Aguerd-nˈTazoult" Formation,Toundoute Continental Series and "Wazzant" Formation, is a geological unit in the Azilal, Béni-Mellal, Imilchil, Zaouiat Ahansal, Ouarzazate, Tinerhir and Errachidia areas of the High Atlas of Morocco, part of the Tafraout Group that covers the Early Toarcian to Middle Aalenian stages of the Jurassic Period. While there have been atributions of it´s lowermost layers to the Latest Pliensbachian, the current oldest properly measured are part of the Earliest Toarcian regresion ("MRST10"), part of the Lower-Middle Palymorphum biozone. The Azilal Formation consists mainly of claystones rich in continental plant debris and laminated microbial facies. It is a continental deposit which overlies marine dolomites of equivalent age to the Rotzo Formation of Italy, mostly part of the Aganane Formation. The formation is the continental to marginal marine part of a massive Siliciclastic-Carbonate platform, best assigned to an alluvial environment occasionally interrupted by shallow marine incursions and marks a dramatic decrease of the carbonate productivity under increasing terrigenous sedimentation. Dinosaur remains, such the sauropod Tazoudasaurus and the basal ceratosaur Berberosaurus are known from the unit, along with several undescribed genera. The toarcian High Atlas is divided in 5 units: the continental layers with paralic deposits belong to the Azilal, along the shoreface layers of the Tagoudite Formation & Tafraout Formation, connected with the offshore Ait Athmane Formation and the deeper shelf deposits of the Agoudim 1 Formation.

<span class="mw-page-title-main">Krempachy Marl Formation</span> Geological formation in Poland and Slovakia

The Krempachy Marl Formation is a geological formation in Poland and Slovakia, dating to about 179 million years ago, and covering the middle Toarcian stage of the Jurassic Period. It is among the most important formations of the Toarcian boundary on the Carpathian realm, being the regional equivalent of the Posidonia Shale.

The Blanowice Formation is a geologic formation in Częstochowa, Poland. It is late Pliensbachian-Lowermost Toarcian age. Plant fossils have been recovered from this formation. Along with the Drzewica Formation is part of the Depositional sequence IV-VII of the late lower Jurassic Polish Basin. Deposits of sequences IV, V, VI and VII make up the Blanowice Formation, being all four sequences are of Pliensbachian age, documented by megaspores (Horstisporites). On the upper strata, “sub-coal beds" cover the sequence VII-lower VIII, while the uppermost part of VIII is identified with the Ciechocinek Formation. The Blanowice Formation has been known for decades thanks to the abundant plant fossils and plant roots, but mostly due to the Blanowice Brown Coals, where the oldest Biomolecules found worldwide have been recovered. The Mrzygłód mine dinocyst assemblage is taxonomically undiversified, containing specimens that are good age indicators allowing relatively precise suggestion of its age. Luehndea spinosa, with a single recovered specimen spans between the Late Pliensbachian (Margaritaus) to the Lowermost Toarcian (Tenuicostatum). Other ocal dinocysts such as Mendicodinium range Late Pliensbachian–Aalenian, a wider stratigraphic range. The lower part of the formation is coeval in age with the Gielniów Formation and Drzewica Formation, Lobez Formation and Komorowo Formation (Pomerania), Olsztyn Formation, the lower part of the Rydeback Member of the Rya Formation, lower Fjerritslev or Gassum Formation, lower and middle Sorthat Formation (Bornholm), Neringa Formation (Lithuania). The upper part is coeval with the lowermost upper Rydeback Member, upper Gassum Formation and lower Lava Formation (Lithuania).

<span class="mw-page-title-main">Sorthat Formation</span> Geologic formation in Bornholm, Denmark

The Sorthat Formation is a geologic formation on the island of Bornholm, Denmark and in the Rønne Graben in the Baltic Sea. It is of Latest Pliensbachian to Late Toarcian age. Plant fossils have been recovered from the formation, along with several traces of invertebrate animals. The Sorthat Formation is overlain by fluvial to lacustrine gravels, along with sands, clay and in some places coal beds that are part of the Aalenian-Bathonian Bagå Formation. Until 2003, the Sorthat Formation was included as the lowermost part of the Bagå Formation, recovering the latest Pliensbachian to lower Aalenian boundary. The Sorthat strata reflect a mostly marginally deltaic to marine unit. Large streams fluctuated to the east, where a large river system was established at the start of the Toarcian. In the northwest, local volcanism that started in the lower Pliensbachian extended along the North Sea, mostly from southern Sweden. At this time, the Central Skåne Volcanic Province and the Egersund Basin expelled most of their material, with influences on the local tectonics. The Egersund Basin has abundant fresh porphyritic nephelinite lavas and dykes of lower Jurassic age, with a composition nearly identical to those found in the clay pits. That indicates the transport of strata from the continental margin by large fluvial channels of the Sorthat and the connected Röddinge Formation that ended in the sea deposits of the Ciechocinek Formation green series.

<span class="mw-page-title-main">Saubach Formation</span> Geological formation in Austria and Germany, about 180–174 million years old

The Saubach Formation is a geological formation in Austria and Germany, dating to about 180–174 million years ago. It was described originally as Saubachschichten in 1975, and classified as part of the Lower Jurassic Adnet Group.

The Rya Formation is a geologic formation in Skåne County, southern Sweden. It is Early to early Middle Jurassic in age. The Rya Formation comprises siltstones, claystones, sandstones, mudstones and rare coal beds. The formation overlies the Höganäs Formation and is overlain by the Vilhelmsfält and Mariedal Formations.

The Röddinge Formation is a geologic formation in Skåne County, southern Sweden. It is Early Jurassic (Sinemurian-Toarcian) in age. It is a unit with a limited degree of exposure, being identified mostly by its deposits on the Fyledalen Fault Zone, specially on Kurremölla, where is present the main fossil deposit. It is a unit known mostly for large museum collections and estimated to have a thickness of several hundreds of meters. It is also known for its large iron deposits. It is correlated with the mostly marine Rya Formation of western Skåne County, the Volcanic deposits of the Djupadal Formation and specially the Sorthat Formation of Bornholm. Most likely, the coarse-grained nature of the Röddinge Formation is linked to rapid erosion of a tectonically active hinterland.

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