Geological Survey of Denmark and Greenland Bulletin 1, 543-554 543 An offshore transgressive–regressive mudstone-dominated succession from the Sinemurian of Skåne, Sweden Nils Frandsen and Finn Surlyk A Sinemurian mudstone-dominated succession was exposed until recently in the Gantofta quarry in Skåne, southern Sweden. The deposits are placed in the Döshult and Pankarp Members of the Sinemurian–Aalenian Rya Formation. Similar facies of the same age are widespread in the Danish Basin where they constitute the F-Ib unit (F-I member) of the Fjerritslev Formation. The Gantofta succession thus represents the easternmost extension of the environment characteris- tic of the Fjerritslev Formation and is essentially the only locality where it has been possible to study the facies of this formation in outcrop. Sedimentation seems to have taken place under rel- atively quiet tectonic conditions except for the possible fault-control of the basin margin. The lower part of the Gantofta section is of Early and early Late Sinemurian age. It represents the upper part of the Döshult Member and consists of muddy, lower shoreface sandstones, abruptly overlain by dark, bioturbated, fossiliferous mudstones with thin storm siltstones and sandstones. They are overlain by the Upper Sinemurian Pankarp Member which comprises red-brown, restricted marine calcareous mudstones with an upwards increasing number of storm siltstones and sandstones reflecting general shallowing and shoreline progradation. The succession spans the greater part of two simple sequences with a distal sequence bound- ary located at the boundary between the Döshult Member and the Pankarp Member. The exposed part of the lower sequence includes a thick transgressive systems tract and a very thin highstand systems tract. The upper sequence is represented by an undifferentiated transgressive and high- stand systems tract. An Early Sinemurian sea-level rise, a late Early Sinemurian highstand, an early Late Sinemurian fall and a Late Sinemurian minor rise and a major fall are recognised. Nearby bore- holes show evidence for an end-Sinemurian – Early Pliensbachian major rise. This evolution cor- responds well with trends recorded in the subsurface Fjerritslev Formation of the Danish Basin. Comparison with published European and British Jurassic sea-level curves show similar over- all trends, but exhibit differences in the precise ages of sequence boundaries and maximum flood- ing surfaces. This may reflect poor biostratigraphical resolution of the Gantofta section, differences in sequence stratigraphic interpretation, real differences in the age of sequence stratigraphic key surfaces, or the basin marginal position of Gantofta in the Fennoscandian Border Zone. Keywords: Skåne, southern Sweden, Lower Jurassic, Sinemurian, facies analysis, sequence stratigraphy, sedimentary environments, sea-level change N.F., DONG, Agern Allé 24–26, DK-2970 Hørsholm, Denmark. E-mail: nfr@dong.dk F.S., Geological Institute, University of Copenhagen, Geocenter Copenhagen, Øster Voldgade 10, DK-1350 Copen- hagen K, Denmark. Geological Survey of Denmark and Greenland Bulletin 1, 543–554 (2003) © GEUS, 2003 544 Jurassic sedimentary rocks occur in great thicknesses in the subsurface of Denmark and southern Sweden (Michelsen 1978; Norling et al. 1983; Nielsen 2003, this volume). They are, however, only exposed in a few rel- atively small outcrops on Bornholm in the Baltic Sea, and in Skåne, southern Sweden, in the Fennoscandian Border Zone (Fig. 1; Sellwood 1972; Rolle et al. 1979; Gravesen et al. 1982; Norling et al. 1983; Surlyk & Noe- Nygaard 1986; Ahlberg et al. 2003, this volume). This intensely block-faulted zone forms the north-eastern boundary of the Danish Basin. Detailed facies, bio- stratigraphic and sequence stratigraphic studies of exposed units are thus of outstanding importance in obtaining a more detailed picture of the sedimentary environments prevailing during Jurassic time in south- ern Scandinavia. The aims of the present paper are to interpret the facies and sequence stratigraphy of the Sinemurian off- shore marine deposits exposed in the Gantofta quarry in Skåne, southern Sweden, to place the succession in its regional context, and to compare the derived sea- level curve with the sea-level curves of Haq et al. (1988), Hallam (1988) and Hesselbo & Jenkyns (1998). Geological setting and stratigraphy Gantofta is located close to the NW–SE-trending western margin of the Fennoscandian Border Zone (Fig. 1). The margin is characterised by a major faulted flexure formed by Late Cretaceous – Palaeogene tectonic inversion which marks the transition to the major depocentre of the Danish Basin to the south-west (Norling 1981, fig. 37). The locality is a small clay pit (150 x 100 m) which was abandoned some years ago and the section is thus no longer easily accessible. The ammonites from the succession were described by Reyment (1969a, b), the foraminifera by Norling (1972), the palynology by Lund (1977), the ostracodes by Sivhed (1977, 1980, 1981) and the sedimentary facies and environments by Frandsen (1977), Rolle et al. (1979) and Pieńkowski (1991a, b). The succession is 70 m thick and consists of sandstones and mudstones of the Lower – lower Upper Sinemurian Döshult Member and the Upper Sinemurian Pankarp Member, which constitute the two lower members of the Sinemurian–Aalenian Rya Formation (Sivhed 1984; Ahlberg et al. 2003, this volume). The whole succes- sion is tilted, and the strata strike 140° and dip 30° SW (Fig. 2). Vomb Trough Fyledalen Fault Gantofta 25 km Höganäs Basin Malmö Trough Hanö Bay Kullen I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I II I I I I I I I I I I I I I I I I Sweden DK Bornholm I I I Rhaetian and Jurassic present distribution Fault active in the Jurassic Post-Jurassic fault N Norway Ängelholm Basin Fig. 1. Map showing the location of Gantofta in the Fennoscandian Border Zone of southern Skåne. Important Jurassic structural features are indicated; note that Jurassic normal faults were subsequently inverted in the Late Cretaceous – Palaeogene. Based on Norling & Bergström (1987). DK, Denmark. 545 A foraminifer fauna from the middle part of the Döshult Member at the base of the exposure indicates an Early Sinemurian age (Norling 1972). An ammonite fauna including Asteroceras obtusum (Sowerby) and Promicroceras planicostatum (Sowerby) from a level 2 m below the base of the overlying Pankarp Member is of early Late Sinemurian obtusum Chronozone, plan- icostatum Subzone age (Reyment 1969a). K. Hoffman (in: Bölau 1959) reported the occurrence of the birchi Subzone (top of the turneri Chronozone) immediately below the base of the Pankarp Member. The ostracode faunas of the Döshult Member indicate a latest Early Sinemurian to Late Sinemurian age (Sivhed 1977). Norling (1972) suggested that the succession spans the time interval of the semicostatum to obtusum Chronozones. A new find of the ammonite Euagassiceras cf. lundgreni Reyment in the basal muddy sandstone of the section suggests a mid Early Sinemurian semicostatum Chrono- zone age for this level (probably resupinatum Subzone). This is in agreement with Bölau (1973). Correlative strata are widely distributed in the Danish Basin where they form the F-Ib unit (F-I member) of the thickly developed, uniform mudstone package of the Fjerritslev Formation (Michelsen 1975, 1978, 1989; Pedersen 1985, 1986; Michelsen et al. 2003, this volume; Nielsen 2003, this volume). The succession of the Gantofta quarry consists of similar facies and thus essen- tially represents the only locality where it has been pos- sible to study the characteristic facies of the otherwise deeply buried Fjerritslev Formation in outcrop. Sedimentology A detailed sedimentological log of the succession was measured in 1975–1976 by Frandsen (1977). Special emphasis was placed on recording primary sedimen- tary structures, body and trace fossils, and details of con- cretions and other diagenetic features were also noted. Five sedimentary facies are recognised and are described below followed by an interpretation of the depositional processes and environments. Sedimentary facies Muddy sandstone (facies 1) This facies consists of fine- to very fine-grained quartz sandstone with a mud-rich matrix. It is only known Fault N A B BA I I I I I I I I I I I I I I I I I I Katslösa Mb Pankarp Mb Coal Seam Mudstone Sandstone Gantofta Quarry Fault I I 200 m Upper Sinemu rian Lower Sinemu rian 200 m Döshult Mb Fig. 2. Geological map and section (A–B) of the Gantofta area. Modified from Sivhed (1981). 546 se m ic os ta tu m C hr o no zo ne (? re su pi na tu m S ub zo ne ) ob tu su m C hr o no zo ne (p la ni co st at um S ub zo ne ) Trace fossils Chondrites isp. Rhizocorallium isp. Diplocraterion isp. Planolites isp. Skolithos isp. Pyritic tube Teichichnus isp. Bioturbation increasing density Body fossils Bivalves, suspension feeders Bivalves, deposit feeders Bivalve fragments Gastropods Ammonites Belemnites Scaphopods Serpulids Brachiopods Echinoid spines Shark teeth Ostracodes Foraminifers Sequence stratigraphy Sequence boundary Maximum flooding surface Transgressive surface of erosion Transgressive systems tract Highstand systems tract Parasequence SB MFS TSE TST HST Ps TSE TST MFS HST TST HST D ö sh ul t M b Pa nk ar p M b D ö sh ul t M b Lithology Mudstone Calcareous mudstone Silty and sandy mudstone Silt- and sandstone Carbonate cemented Conglomerate Structures Parallel lamination Parallel lamination with siltstone lenses Cone-in-cone structures Clay ironstone concretions C la y Si lt Sa nd vf f C la y Si lt Sa nd vf f 35 30 25 20 15 10 5 0 1 3 2 2 2 2&3 2&3 2&3 2&3 2 2 2 2 2&3 3 Ps Ps Ps Ps Ps Ps Ps 70 m m 65 60 55 50 45 40 35 2 4 5 SB Fa ci es Se q. St ra t. Fig. 3. Sedimentological section showing the biostratigraphy, chronostratigraphy and sequence stratigraphy of the Sinemurian suc- cession at Gantofta. from the base of the section (Fig. 3). Shelly coquinas with quartz granules occur at some levels. The colour varies from light grey to dark grey. The sandstone is almost totally bioturbated and the original structures are commonly difficult to recognise. However, fine bio- genic lamination caused by high densities of the trace fossil Teichichnus isp. is a characteristic feature of the facies. Siderite is the dominant cement, whereas the most indurated beds have a calcitic cement. The trace fossils include Teichichnus isp., Diplo- craterion isp., Rhizocorallium isp., Chondrites isp., Plan- olites isp. and Zapfella isp.; the last of these occurs as elongate borings in shells of the bivalve Liogryphaea arcuata. The facies contains a fully marine fauna of body fos- sils which occur in rather high densities. Frandsen (1977) compiled a list of the fauna and documented the pres- ence of species described from other localities by Troedsson (1951). A taxonomic revision has not been attempted. The fauna includes the bivalves Liogryphaea arcuata, Chlamys textoria, Chlamys interpunctata, Entolium sp., and Oxytoma sinemuriensis, the ammonite Euagassiceras cf. lundgreni Reyment, and indetermi- nate belemnites, echinoids, serpulids, ostracodes and nodosariid foraminifera. Coalified wood occurs as scat- tered pieces up to 6 cm long. The preservation of the shells is quite variable. Some are well-preserved and unworn, while others occur in coquinas and have clearly undergone some transport and destruction. The combination of marine body and trace fossils, intense bioturbation, shelly coquinas and a sand-dom- inated grain size indicates deposition under well-oxy- genated marine conditions with normal salinity and relatively low sedimentation rates, periodically inter- rupted by higher energy events resulting in erosion, reworking and transport of shells. The taphonomic con- ditions suggest that the fauna can be considered a neigh- bourhood assemblage representing a fauna which lived in the area and which underwent only limited transport. The muddy nature of the sandstone suggests that the original facies was a sand-dominated, possibly flaser- bedded heterolith, but the very high degree of biotur- bation does not allow a detailed process interpretation. Dark grey mudstone (facies 2) The mudstone of this facies characterises the bulk of the exposed part of the Döshult Member (Fig. 3). It has a high content of silt and fine sand. Silt and clay are roughly equally abundant, and the clay is dominated by kaolinite with some illite and chlorite. Coaly detri- tus, muscovite, very small shells and shell fragments, and framboidal pyrite nodules (0.1–0.3 mm in diame- ter) are characteristic constituents. A few intervals, up to 1 m thick, have a relatively higher content of sand and can be classified as muddy sandstones. The mudstone is laminated with light coloured lam- inae of coarse silt, 1 mm thick. Clay ironstone is a char- acteristic component and occurs as bedding-parallel siderite impregnated layers, 5 cm thick, with ellipsoidal concretions, 5–20 cm long. Thin conglomerate beds consisting of reworked clay-ironstone concretions are found at the 35.05 m and 38 m levels (Fig. 3). Carbonate concretions with cone-in-cone structures occur at sev- eral levels. The facies is strongly bioturbated, especially in the sandier portions, but several recognisable trace fossils were noted, including Diplocraterion isp., Skolithos isp., Rhizocorallium isp. (which has only been recorded from the clay-ironstone conglomerate) and Chondrites isp. Pyritic tubes, 0.2–1.0 mm in diameter, probably representing burrows of small deposit feeders, and ?Planolites isp. occur throughout. This facies and the laminated siltstone–sandstone facies (facies 3) contain a rich shelly fauna. The two facies and their faunas are closely related and their fau- nas are described together here. The carbonate shells have undergone dissolution and are mainly poorly pre- served, but wear due to transport appears to be negli- gible. Liogryphaea arcuata is relatively rare and the specimens are smaller than those of facies 1. Two species of Chlamys and minute specimens of Oxytoma sinemuriensis have been found. A major difference in faunal composition compared to facies 1 is the abun- dance of deposit-feeding bivalves of the Nuculanacea (Nuculana, Palaeoneilo, Rollieria, Leda) and Nuculacea (Nucula). Bivalves belonging to Cardinia, Astarte, Homomya and Pleuromya or related genera also occur, but the determinations are uncertain. Small, high-spired gastropods representing a number of different genera are very common. Poorly preserved scaphopods, brach- iopods, ammonites and rare shark teeth occur at sev- eral levels. The fine-grained muds were deposited from sus- pension in an offshore open marine environment. The content of silt and sand probably represents material transported to the area during storms. Bioturbation then resulted in mixing of the fine and coarser fractions, and destruction of primary current-produced structures. The high density and diversity of body and trace fossils show that the water was of normal salinity and well- 547 oxygenated. The abundance of deposit feeders is a common characteristic of fine-grained, nutrient-rich sed- iments, whereas the abundant small-sized gastropods suggest the presence of a marine vegetation. The clay ironstone layers were formed under con- ditions of negative Eh, low concentration of sulphide ions, high activity of ferrous ions, and the presence of bicarbonate ions. Following Sellwood (1971) it is sug- gested that iron was transported to the marine envi- ronment and deposited as insoluble ferrioxide which was adsorbed on clay minerals. The siderite nodules contain undeformed trace fossils and the mudstone shows compaction features around the nodules which were thus formed after burrowing but before com- paction. Laminated siltstone–sandstone (facies 3) This facies varies in grain size from coarse silt to fine sand, but grains up to granule size occur set in a muddy matrix. It forms beds up to 1–2 m thick and is commonly interbedded with facies 2. More than 95% of the grains consist of quartz. Other components are plagioclase, muscovite and coaly grains. Nodules of framboidal pyrite with a diameter of 0.1 mm occur locally. The cement consists mainly of calcite. The facies is parallel laminated, but structureless intervals are also observed and primary structures are commonly obliterated by bioturbation. Laminae are nor- mally 1–2 mm thick, and may be graded from fine sand to coarse silt. Thin laminae of shell hash occur locally. The facies is strongly bioturbated. Recognizable trace fossils include rare Skolithos isp., Chondrites isp., Rhizo- corallium isp. with protrusive spreiten, and ?Pygospi- oides isp. which is very similar to Chondrites, but more closely resembles Pygospioides isp. as described from the Hettangian of Niedersachsen by Häntzschel & Reineck (1968). ?Planolites isp. traces occur through- out the facies. Body fossils are described under facies 2 (see above). The coarse siltstones and sandstones of this facies probably represent distal offshore storm deposits (Pedersen 1985), but the pervasive bioturbation pre- cludes an unequivocal interpretation. Variegated mudstone (facies 4) This facies and facies 5 characterise the Pankarp Member in the upper part of the section (Fig. 3). It differs from facies 2 in the red-brown colour and a finer grain size dominated by clay and silt. Some levels are light-grey with a greenish tinge. The colour difference from facies 2 is associated with a greater content of iron; the red variety is richer in ferric and poorer in ferrous com- pounds than the greenish variety. The facies shows some lamination and upwards in the succession thin lenticular silt ripples start to appear. A few indeterminate bivalves and some pyrite-impreg- nated nodosariid foraminifers have been found. The facies was deposited under low energy conditions, probably in a marginal marine environment as inferred from the impoverished fauna and the scarcity of bio- turbation compared to facies 2 and 3. Calcareous siltstone and mudstone (facies 5) The facies consists of intimately interbedded, soft, var- iegated claystone and siltstone of the same type as facies 4, and harder light grey coarse siltstone and very fine sandstone. Up to 60–70% of the sediment consists of calcite while quartz, clay and some muscovite con- stitute the remaining part. The calcite occurs as recrys- tallized cement and grains of uncertain origin. Comminuted coaly fragments occur throughout. The facies shows an almost varve-like grading with 5–17 mm thick beds. The graded beds pass from light grey, calcite-rich clay into red clay, poor in calcite. The lower boundaries of the graded beds are sharp and the tops are flat or gently undulating. Some of the thicker, coarser-grained beds show parallel lamination passing into low-amplitude hummocky cross-stratification. These beds also display load structures, groove casts, flat- lying folds and wrinkle marks on their upper surfaces. The wrinkle marks are very similar to the Kinneya rip- ples of Reineck & Singh (1980). Trace fossils are scarce, typically represented by scat- tered 3–4 mm wide subhorizontal burrows, whereas Teichichnus isp. and subhorizontal Rhizocorallium isp. with protrusive spreiten are found in the upper coarser- grained part of the succession. Body fossils are only rep- resented by scattered shell fragments. The fine grain size and the scarcity of trace and body fossils suggest deposition under very low energy con- ditions in a marginal or high stress marine environ- ment. The graded beds probably represent deposition from storm-induced suspension clouds (Pedersen 1985). The upwards increase in grain size and in the frequency of beds displaying parallel lamination and hummocky cross-stratification indicate increasingly storm-influenced 548 deposition. The sum of characters thus indicates depo- sition under low energy conditions interrupted by sud- den influxes of storm-derived sediments. The environ- ment may have been distant offshore or more likely a relatively protected shallow marine area where the available grain sizes were very fine and where the effects of storm events were relatively subtle. The red coloration and the presence of Kinneya-type wrinkle marks lend some credence to the latter hypothesis. The wrinkle marks may have been caused by a strong wind blowing over a cohesive, fine-grained sediment covered by only a thin veneer of water, possibly with a micro- bial mat growing on the sea floor under environmen- tally stressed conditions (Reineck & Singh 1980). They are thus indicative of near emergent conditions. As indi- cated on the geological map (Fig. 2), a coal seam is sit- uated slightly above the studied section. This also sug- gests that facies 5 was deposited in a marginal to non-marine environment. Depositional environment Facies 1–5 form a regular vertical succession with facies 1 at the base and facies 5 at the top, and interbedding only occurs between facies 2 and 3. The section thus includes a basal muddy sandstone, a lower dark grey unit and an upper unit dominated by light grey and red- brown colours. The sedimentary structures and grain sizes do not show any marked changes and the main mechanisms of transport and deposition seem to have been rather uniform. The whole succession is thus con- sidered to represent an association of genetically related facies. The basal part of the association consists of muddy sandstone (facies 1; only 1.2 m exposed). It is followed with a sharp boundary by a unit dominated by dark grey mudstone with clay-ironstone layers (facies 2), 37.7 m thick, with numerous intercalations of thin siltstone and sandstone beds (facies 3). This unit is overlain with a sharp contact by a variegated mudstone unit, 14.9 m thick, (facies 4), which gradually gives way to a succession of calcareous mudstones and siltstones (facies 5); 15.9 m of this last unit was exposed in the 1970s. The succession is interpreted to reflect changes in relative sea level in an area with uniform subsidence and relatively constant sediment influx. Thus, facies 1 represents slow deposition in a well-aerated shallow shelf sea. The muddy sand was originally deposited as alter- nating thin layers of mud and thicker layers of sand which were thoroughly mixed by bioturbation in the offshore transition to lower shoreface zone close to wave-base. The sharp boundary to the overlying mud- stones of facies 2 is interpreted as a ravinement surface caused by combined drowning and transgressive ero- sion when coarser clastic material was trapped in estu- aries and other inshore environments. The main part of the succession represented by mud- stone with coarser-grained intercalations (facies 2 and 3) was deposited in deeper offshore areas with periodic influxes of silt and sand from storm-generated sus- pension clouds. Most of the silt and sand beds were thoroughly bioturbated and their identity as storm deposits became less obvious. The unit shows an upwards decrease in the density and diversity of body fossils cul- minating at the almost barren 35 m level (Fig. 3). The top 4 m of the unit are again rich in body fossils. This trend is interpreted to have resulted from transgression and increasing water depth associated with a decrease in oxygenation followed by a regression combined with increasing oxygenation at the sea floor. The variegated mudstones of facies 4 and 5 overlie the dark grey mudstone with a sharp contact (38.9 m in Fig. 3) and are somewhat difficult to interpret envi- ronmentally. They have the finest grain size of the whole succession indicating very low energy condi- tions during deposition. The red colour and the occur- rence of wrinkle marks or Kinneya ripples suggest well-oxygenated, very shallow water conditions. The sed- iments were possibly derived from erosion of fine- grained red beds of Triassic age exposed in a nearby source area. The upwards increase in storm siltstones and sandstones suggests coastal progradation, whereas the scarcity of body and trace fossils suggests a mar- ginal marine or high stress environment. The generally fine grain size points to deposition in a sheltered, some- what enclosed area. The variegated mudstones with storm siltstones and sandstones of facies 4 and 5 thus seem to have been rapidly deposited in a very shallow marine, restricted environment under the influence of storms. Sequence stratigraphy The Döshult Member can be divided into six or seven coarsening-upwards units, about 2–8 m thick, with sharp upper boundaries (Fig. 3). They are typical exam- ples of distal parasequences (Van Wagoner et al. 1990). Thin fining-upwards units, 10–20 cm thick, are not assigned any sequence stratigraphic significance but are interpreted as bioturbated storm siltstones and sand- 549 stones. The parasequences stack into a parasequence set which shows a subtle overall fining-upwards trend accompanied by a distinct decrease in density and diver- sity of body and trace fossils (0–25 m in Fig. 3). The trend is interpreted as an overall backstepping stack- ing pattern which culminates in the poorly fossiliferous interval between 25 m and 35 m in the upper part of the Döshult Member (Fig. 3). A few thin conglomerates rich in body and trace fossils occur between 35 m and 38.9 m. The dark mudstones of the Döshult Member (facies 2) are overlain by the Pankarp Member with a sharp conglomeratic boundary at 38.9 m. This unit comprises about 30 m of variegated, and red-brown, almost unfos- siliferous mudstones which contain an upwards increas- ing number of thin storm siltstones and sandstones. The slowly deposited fully marine muddy sandstones at the base of the section are interpreted to belong to the lower part of the transgressive systems tract. They are capped by a sharp erosional drowning or ravine- ment surface formed by transgressive marine erosion (TSE in Fig. 3). The overlying dark mudstones form the upper part of the transgressive systems tract (TST in Fig. 3). Lowstand deposits cannot be recognised and were probably not deposited in the area. The trans- gressive marine erosion surface corresponds to the lithostratigraphic boundary between units F-Ia and F-Ib (both F-I member) of the Fjerritslev Formation but is slightly younger than in most of the Danish Basin. The age of the erosion surface is close to the semi- costatum–turneri Chronozone boundary. A distinct maximum flooding surface cannot be iden- tified on the basis of the available data but a maximum flooding zone is interpreted to occur at about 34 m (MFS in Fig. 3). The upper part, from 34 m to the top of the section may represent a simple highstand sys- tems tract. The siderite pebble conglomerate at 38.9 m is not easy to interpret in terms of sequence stratigra- phy. It occurs at a marked facies change from dark fossiliferous mudstones (facies 2) to variegated and red- brown almost non-fossiliferous mudstones (facies 4, 5). This change seems to represent a significant environ- mental change associated with a marked seawards shift in facies and it is possible that it represents a distal sequence boundary. If this is the case then the high- stand systems tract of the underlying sequence is a maximum of 5 m thick and consists of dark, uniform mudstones at the top of the Döshult Member (34–38.9 m in Fig. 3). This interpretation is tentatively preferred here and the exposed Döshult Member thus includes a lower transgressive systems tract (TST), a transgres- sive surface of erosion (TSE), a thick upper transgres- sive systems tract (TST), a maximum flooding surface or zone (MFS) and a thin highstand systems tract (HST) topped by a distal sequence boundary (SB; Fig. 3). The overlying Pankarp Member probably represents poorly differentiated transgressive and highstand systems tracts. The fossiliferous siderite pebble conglomerate at the Döshult–Pankarp Member boundary may be interpreted as reworked hiatus concretions formed when sediment supply to the basin was shut off during maximum flood- ing (Hesselbo & Palmer 1992). This interpretation is, how- ever, considered unlikely due to the marked facies change, the seawards shift in facies and the associated inferred major drop in water depth across the boundary. Correlation to the contemporaneous Sose Bugt Member (Rønne Formation) on Bornholm in the Baltic Sea is hampered by the paralic, poorly fossiliferous nature of that unit (Surlyk et al. 1995). Dating of the Gantofta succession is based on ammonites, ostracodes and foraminifera, whereas the Sose Bugt Member is dated on the basis of pollen in the lower part and a few dinoflagellates in the upper part. A major sequence boundary is situated close to the Hettangian–Sinemurian boundary in the Sose Bugt section. This correlates well with a sequence boundary at the base of the Döshult Member in Skåne, below the Gantofta section (Surlyk et al. 1995). Two minor sequence boundaries are iden- tified in the Sose Bugt section in the Lower Sinemurian and in the middle Upper Sinemurian, respectively. The lower sequence boundary occurs at a level roughly cor- responding to the top of the muddy sandstone (facies 1) at the base of the Gantofta section (1.2 m in Fig. 3), whereas the upper one may correlate with the interpreted sequence boundary at the sharp break between dark mudstones (facies 2) and variegated mudstones (facies 4) at Gantofta (Döshult Member – Pankarp Member boundary; 38.9 m in Fig. 3). This correlation may cor- roborate the interpretation of the erosional boundary between the Döshult and Pankarp Members as repre- senting the distal expression of a sequence boundary. It is remarkable that highstand systems tract deposits are almost absent in the Sinemurian Sose Bugt section which mainly consists of transgressive systems tract deposits. This is thought to be typical of the more prox- imal, basin margin areas (Surlyk et al. 1995) and may also account for the thinly-developed highstand deposits at Gantofta which occupied an intermediate basinal position between the paralic setting of the Sose Bugt Member and the offshore Danish Basin. Higher parts of the Pankarp Member are known from boreholes sit- uated close to the Gantofta quarry. The red-brown, var- 550 551 iegated and light grey mudstones of facies 4 and 5 are overlain by 10–17 m of bluish-grey mudstone. This is followed by about 5 m of sand with an allochthonous coal seam, 5–15 cm thick, representing a marked regres- sion (Sivhed 1980). The sand is overlain by about 15 m of red-brown or bluish-grey mudstone. The Pankarp Member spans the Upper Sinemurian oxynotum and most of the raricostatum Chronozones. The nature of the lower boundary of the sand bed is not known and a sequence stratigraphic interpretation cannot be under- taken on the basis of the available data. A relative sea-level curve constructed on the basis of the sedimentary evolution as interpreted here is shown on Figure 4. It is compared with the Jurassic eusta- tic sea-level curves of Haq et al. (1988) and Hesselbo & Jenkyns (1998). The overall trends of the curves are remarkably similar, but the exact ages of the main highs and lows differ somewhat. The Haq et al. (1988) and Hesselbo & Jenkyns (1998) curves show the highest degree of similarity although the latter is more detailed and shows more candidate sequence boundaries and maximum flooding surfaces. The two curves show major sequence boundaries in the uppermost Hettangian, uppermost Lower Sinemurian and uppermost Sine- murian, and maximum flooding surfaces in the middle Lower Sinemurian and middle Upper Sinemurian. The Gantofta curve is simpler due to a combination of uniform facies development and lower biostrati- graphical resolution. It differs from the curve of Hesselbo & Jenkyns (1998) in that they place the main Sinemurian sequence boundary at the base or immediately below the base of the obtusum Chronozone whereas it occurs within this chronozone at Gantofta. The mismatch between the Gantofta curve and the two other curves may be due to the basin marginal position and the lack of lowstand deposits at Gantofta. The low biostrati- graphic resolution prevents identification of possible hia- tuses in the mudstone-dominated succession. The eustatic signal may thus be overprinted by tectonism in the Fennoscandian Border Zone, by higher sediment input during transgression and condensation and bypass during regression. Hallam (1988) did not give any detailed zonal data for his transgressive and regressive events and his curve is thus difficult to compare with the other curves. Conclusions Until recently, a Lower Jurassic, Sinemurian marine suc- cession, 70 m thick, was exposed at the Gantofta local- ity in north-western Skåne, southern Sweden. Gantofta represents the only place where it has been possible to study exposed strata of the same facies as the deeply- buried contemporaneous Fjerritslev Formation of the Danish Basin. The succession comprises the upper part SB SB SB SBSB SB SB SB MFS MFS MFS MFS MFS High Low High Low High Low After Haq et al. (1988) After Hesselbo & Jenkyns (1998) This paper, Gantofta 200 195 Ma jamesoni Chrono- zones rari- costatum oxynotum obtusum turneri semi- costatum bucklandi angulata U pp er U pp er Lo w er Lo w er Pliensbachian Stages Sea-level changes Sinemurian Hettangian Fig. 4. Relative sea-level curve con- structed for the Gantofta succession compared with the Jurassic sea-level curves of Haq et al. (1988) and Hesselbo & Jenkyns (1998); the time scale is after Gradstein et al. (1994). An ammonite from the basal muddy sandstone at Gantofta suggests a mid-semicostatum Chronozone age for this level. The level of the obtusum Chronozone is well located and the lower part of the succession has a general Early Sinemurian age. The age of the post- obtusum Chronozone beds is not well- known but ostracode data suggest a Late Sinemurian age (Sivhed 1980). MFS, maximum flooding surface; SB, sequence boundary. of the Döshult Member and the lower part of the Pankarp Member, both belonging to the Sinemurian–Aalenian Rya Formation. The basal 1.2 m of the Gantofta section exposed the uppermost levels of the sand-dominated Lower Sinemurian part of the lower Döshult Member. This overall transgressive, fluvial and lacustrine to shal- low marine succession is known from temporary expo- sures at nearby Örby where it is 32 m thick (Erlström et al. 1999). Five genetically related facies are recognised. The lower half of the Gantofta section, representing the upper Döshult Member, is composed of three facies (1–3). The lowermost 1.2 m consists of Lower Sinemurian bioturbated, richly fossiliferous muddy sandstones (facies 1), interpreted as having been deposited relatively slowly in an offshore to transition zone environment. They are followed with a sharp contact by Lower – lower Upper Sinemurian, dark grey, bioturbated, fossiliferous mudstones (facies 2) with intercalations of siltstones and sandstones (facies 3). The mudstones represent slow, fair-weather deposition below wave base under offshore shelf conditions interrupted by deposition of thin silts and sands from storm-generated suspension clouds. The general low sedimentation rate and the distal, thin nature of the storm deposits is reflected by the pervasive bioturbation and mixing of both facies. The succeeding Upper Sinemurian succession, referred to the lower Pankarp Member, comprises mar- ginal marine, variegated mudstones and red-brown cal- careous mudstones (facies 4, 5) with an upwards in- creasing number of storm siltstones and sandstones reflecting general shallowing and progradation of the coastline associated with restriction of the marine cir- culation. A fossiliferous siderite pebble comglomerate occurs at the boundary between the Döshult and Pankarp Members. The succession encompasses the greater part of two, relatively simple depositional sequences. The basal muddy sandstone is interpreted as belonging to the lower transgressive systems tract of the lower sequence. It is topped by a ravinement surface formed by trans- gressive marine erosion overlain by a backstepping parasequence set representing the upper transgressive systems tract. A maximum flooding zone is identified close to the top of the dark Döshult Member mud- stones. It is overlain by a thinly developed highstand systems tract topped by an erosion surface marked by the siderite pebble conglomerate. The erosion surface is tentatively interpreted as a distal sequence bound- ary and the overlying variegated and red-brown Pankarp Member mudstones belong to the poorly differentiated transgressive and highstand systems tracts of the sec- ond sequence. Comparison with the sequence strati- graphy of the contemporaneous Sose Bugt Member (Rønne Formation) of Bornholm lends some credence to this interpretation. The Gantofta succession records an Early Sinemurian sea-level rise, a mid-Sinemurian highstand, an early Late Sinemurian sea-level fall followed by a Late Sinemurian minor rise and subsequent major fall. Data from nearby boreholes indicate an end Sinemurian – Early Pliensbachian major rise. The sea-level curve con- structed on the basis of the Gantofta section is com- pared with the sea-level curves of Haq et al. (1988) and Hesselbo & Jenkyns (1998) in Figure 4. It is remarkable that the three curves show similar overall trends but the sequence boundaries and maximum flooding surfaces are delayed in the Gantofta curve compared to the two other curves. 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