Geological Survey of Denmark and Greenland Bulletin 6, 29-39 29 The Neoproterozoic Rivieradal Group of Kronprins Christian Land, eastern North Greenland M. Paul Smith, A.K. Higgins, N.J. Soper and Martin Sønderholm The Rivieradal Group, formally defined here, is confined to the Vandredalen thrust sheet of the Caledonian orogen in Kronprins Christian Land, eastern North Greenland. It comprises a suc- cession of Neoproterozoic siliciclastic sediments that represent the fill of a half-graben basin. The syn-rift Rivieradal Group is overlain by post-rift sediments of the Hagen Fjord Group. The latter succession is present in both the thrust sheet and the Caledonian foreland to the west. In the foreland, where the Rivieradal Group is not represented, the Hagen Fjord Group disconformably overlies Palaeoproterozoic–Mesoproterozoic sandstones of the Independence Fjord Group. Keywords: Caledonian, North Greenland, Precambrian, Proterozoic, stratigraphy M.P.S., Lapworth Museum, School of Geography, Earth and Environmental Sciences, University of Birmingham, Edgbaston, Birmingham B15 2TT, UK. E-mail: m.p.smith@bham.ac.uk A.K.H. & M.S., Geological Survey of Denmark and Greenland, Øster Voldgade 10, DK-1350, Copenhagen K, Denmark. N.J.S., Gams Bank, Threshfield, Skipton BD23 5NP, UK. Also affiliated with: Department of Geology, University College, Galway, Ireland. Kronprins Christian Land lies at the northern termina- tion of the East Greenland Caledonides, and consti- tutes a key area for studies of the western border zone of the orogen (Fig. 1). This region exposes continu- ous sections from the undisturbed foreland in the west, across parautochthonous foreland affected by folding and thin-skinned thrusting to allochthonous thrust sheets in the east (Higgins et al. 2001a, b). The fore- land comprises three principal lithostratigraphical di- visions: (1) Palaeoproterozoic–Mesoproterozoic sand- stones of the Independence Fjord Group, the Meso- proterozoic Zig-Zag Dal Basalt Formation and associ- ated dolerites (Midsommersø Dolerite Formation); (2) Neoproterozoic shallow marine sediments of the Hagen Fjord Group (Sønderholm & Jepsen 1991); (3) Cambrian–Silurian shelf sediments of the Franklinian Basin (Higgins et al. 1991). The Hagen Fjord Group is also represented within the allochthon, in the Van- dredalen thrust sheet, where it overlies the clastic sedi- ments of the Rivieradal Group, which are the subject of this paper. In Kronprins Christian Land the parautochthonous Lower Palaeozoic sediments lie in the foot wall of the Vandredalen thrust sheet, and are deformed by a se- ries of thin-skinned thrusts that constitute a duplex below the Vandredalen thrust (Figs 1, 2). This parau- tochthonous area extends as a 30–50 km wide belt to the west of the 200 km long, N–S-trending Vandreda- len thrust front. The Vandredalen thrust displays a clas- sical staircase trajectory with very long (20+ km) flats developed in dolomitic horizons, and ramps devel- oped in the more resistant subtidal carbonate units of the Franklinian Basin succession (cf. Smith et al. 2004, this volume). The thrust roots to the east along the Spærregletscher – Hekla Sund lineament and has a total westward displacement estimated at c. 40 km, of which c. 18 km are taken up in the thin-skinned parau- tochthonous belt (Higgins et al. 2001b, 2004). The Geological Survey of Denmark and Greenland Bulletin 6, 29–39 © GEUS, 2004 GEUS Bulletin 6.pmd 10-02-2005, 09:5329 30 ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲▲ ▲ ▲ ▲ Ro m er Sø I n go lf Fjor d Amdrup Land Holm Land Hovgaard Ø Kap Bernhoft Dijmphna Sund H ek la Sund Cen tru ms ø S K A L L IN G E N Sy dv ejd al SP T SP T R ivie r a d a l 20°W 80°N 81°N Blåsø Sk jo ld un ge el v Nio gha lvfje rdsf jord en Gr æs elv Sæ faxi Elv D an m ar k Fj or d Va nd re d al en th ru st V an dr ed al en Kap Holbæk P C M A Hj H BS FL D V Lambert Land MFig. 3 Wandel Sea Basin sequence (post-Caledonian) Samuelsen Høj Formation Lauge Koch Land Formation Odins Fjord Formation Turesø Formation Wandel Valley Formation Kap Holbæk Formation Crystalline basement Thrust Fault, shear zone Børglum River and Sjælland Fjelde Formations Fyns Sø, Kap Bernhard, Campanuladal Fms Hagen Fjord Gp Rivieradal Group Independence Fjord Gp and basaltic formations Vandredalen thrust Hagen Fjord Group ▲ ▲ ▲ ▲ Vandredalen thrust sheet ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲ ▲▲ ▲ ▲ C A LE D O N ID ES Greenland I 25 km GEUS Bulletin 6.pmd 10-02-2005, 09:5330 31 Vandredalen thrust sheet, in turn, is structurally over- lain by a thrust sheet that transported Palaeoprotero- zoic to Mesoproterozoic clastic and volcanic rocks westwards. The allochthonous quartzites have tradi- tionally been viewed as equivalents of the Independ- ence Fjord Group on the foreland (see Figs 1, 2), but SHRIMP isotopic studies on rhyolites interbedded with the quartzites that yielded an age of 1740 Ma (Kals- beek et al. 1999) have cast some doubt on this inter- pretation (see also Pedersen et al. 2002). Still farther to the east, higher thick-skinned thrust sheets incor- porate crystalline basement gneisses. This paper provides a formal stratigraphic basis, at group level, for the rocks that underlie the Hagen Fjord Group within the Vandredalen thrust sheet, and col- lates available field data regarding this succession. As noted below, formal definition of the constituent for- mations awaits more detailed field analysis of the Ri- vieradal Group. The informal units of Fränkl (1954, 1955) were found to be generally usable as field divi- sions, although there is uncertainty in places about their correlation. Stratigraphy of the Vandredalen thrust sheet Restoration of the displacement associated with the Vandredalen thrust sheet demonstrates that much of the sediment within the thrust sheet was deposited in an east-facing extensional half-graben (Hekla Sund basin) that originally lay immediately to the east of the Spærregletscher – Hekla Sund lineament (Higgins et al. 2001b). This basin fill was thrust out of the half- graben and transported westwards on the Vandreda- len thrust (Fig. 2). These syn-rift sediments are as- signed to the Rivieradal Group, which is formally erected below. They are overlain by sediments of the Hagen Fjord Group, which were deposited during post- rift thermal subsidence and extended westwards be- yond the confines of the Hekla Sund basin. The Hagen Fjord Group, in consequence, is present both in the foreland and the hanging wall of the Vandredalen thrust whereas the Rivieradal Group is restricted to the hanging wall (Higgins et al. 2001b). The Hagen Fjord Group within the Vandredalen thrust sheet is represented by the Campanuladal, Kap Bernhard and Fyns Sø Formations. The Campanuladal Formation comprises 200 m of variegated sandstones, siltstones and mudstones of generally similar appearance to successions of the same unit in the foreland around Danmark Fjord. A lower, greenish weathering unit con- taining parallel and trough cross-laminated sandstones, and mudstones with desiccation cracks, is overlain by an upper, dark red weathering unit dominated by cal- careous mudstones with some trough cross-bedded sandstones (Jepsen & Sønderholm 1994). The Kap Bern- hard Formation comprises brownish red weathering, finely laminated algal limestones and the Fyns Sø For- mation contains pale stromatolitic dolostones; both correspond very closely to their counterparts in the foreland. In the northernmost part of the outcrop area of the Vandredalen thrust sheet, in Finderup Land (Fig. 1), the Fyns Sø Formation is unconformably overlain by sandstones of the Kap Holbæk Formation. This latter unit was included within the redefined Hagen Fjord Group of Clemmensen & Jepsen (1992), but strati- graphic data obtained during the 1994–1995 field sea- sons demonstrated that a significant hiatus occurs between the two units. In particular, a well-developed palaeokarst horizon developed at the top of the Fyns Sø Formation is infilled by the Kap Holbæk Forma- tion (Smith et al. 1999). It is probable that the carbon- ates of the Fyns Sø Formation are correlatives of simi- lar late Riphean to Sturtian units, which are widely developed in the North Atlantic region, while the pres- ence of deep Skolithos burrows in the Kap Holbæk Formation indicates a Lower Cambrian age (Smith et al. 2004, this volume). Since the hiatus between the two units probably spans the entire Vendian, Smith et al. (2004) proposed that the Kap Holbæk Formation be removed from the Hagen Fjord Group. Facing page: Fig. 1. Geological map of Kronprins Christian Land, eastern North Greenland, and Lambert Land, North-East Greenland. Black oval symbols in the Rivieradal Group, in legend and on map, indicate conglomerates. BS, Brede Spærregletscher; D, ‘Dunkeldal’; FL, Finderup Land; H, Harefjeld; Hj, Hjørne- gletscher; M, Marmorvigen; PCMA, Prinsesse Caroline Mathilde Alper; SPT, Spærregletscher thrust; V, Vardedalen. On index map: I, Independence Fjord. See Figs 2 and 3 for cross-sections along Rivieradal. Modified from Rasmussen & Smith (2001). Note that the traditional interpretation of the allochthonous quartzites as equivalents of the foreland Independence Fjord Group (as depicted here and on Fig. 2), has been brought into doubt by the 1740 Ma age on inter- bedded rhyolites (see discussion in Kalsbeek et al. 1999 and Pedersen et al. 2002). GEUS Bulletin 6.pmd 10-02-2005, 09:5331 32 Rivieradal Group new group History. The Proterozoic rocks of Kronprins Christian Land were first examined systematically by geologists of Lauge Koch’s 1926–1958 expeditions. The region around Danmark Fjord was documented by Adams & Cowie (1953), and that around Centrumsø by Fränkl (1954, 1955). Fränkl recognised that the Neoprotero- zoic succession could be divided into autochthonous and allochthonous parts, the two separated by a ma- jor thrust upon which his ‘main nappe’ was transported. The metasediments of the nappe were divided into a lower, more metamorphosed part, comprising the Stenørkenen Phyllites (> 1000 m) and the Sydvejdal Marbles (100–400 m), and an upper less metamorphic part. The latter included, from base to top, the Taagefjeldene Greywackes (> 700 m) with a layer of alum shales at the base (c. 150 m), the Rivieradal Sand- stones (1000–2000 m), the Ulvebjerg Sandstones & Tillites (20–35 m), the red, shaly Campanuladal Lime- stone and the Fyns Sø Formation. The two last-named units were also identified as lying in the foot wall of the nappe (Fränkl 1954, 1955). The succession pre- sent in the ‘main nappe’ was recognised as having been deposited in a basin located to the east, which Fränkl (1955) termed the ‘Hekla Sund Basin’; the lat- ter term is retained here for the depositional basin in which the Rivieradal Group accumulated. Fig. 2. Schematic NW–SE cross-sections of the Vandredalen rift system, approximately along the section line of Fig. 3 shown on Fig. 1, but with extensions to both south-east and north-west. A: Present-day section, with overburden calculated from conodont alteration temperatures (after Rasmussen & Smith 2001). B: With displacements on the thrusts restored, illustrating the fault-bounded control of the west margin of the Hekla Sund Basin. Modified from Higgins et al. (2001b). SPÆRREGLETSCHER THRUST IF RG 22 km 18 km SPT 50 ? km 100 ? km ST HF IF O–S O–S O– S HF VT VT O–S UPPER ALLOCHTHON– higher thrust sheets comprising Ordovician–Silurian, Hagen Fjord Group, Rivieradal Group (distal part of Hekla Sund basin), Independence Fjord Group and associated volcanic rocks and crystalline basement. ESTIMA TED O VERBUR DEN ST VT SPT Spærregletscher thrust Vandredalen thrust Sole thrust RG IF CB HF O–S Ordovician–Silurian Hagen Fjord Group Rivieradal Group Crystalline basement Independence Fjord Group and associated volcanic rocks 5 km 0 10 20 km HF PRESENT DAY RG CB CB IF IF IF IF CB CB HEKLA SUND BASIN Rivieradal Group succession) A B WNW ESE Conglomerate Hekla Sund basin (Rivieradal Group) Sandstone Mudstone and calcareous mudstone GEUS Bulletin 6.pmd 10-02-2005, 09:5432 33 Haller (1961, 1971) erected the Hagen Fjord Group for Proterozoic sediments of the autochthon and allochthon in Kronprins Christian Land, including volcanic rocks now referred to the Zig-Zag Dal Basalt Formation, Hekla Sund Formation and Aage Berthel- sen Gletscher Formation, and Lower Cambrian car- bonates now referred to the Portfjeld Formation. Clem- mensen & Jepsen (1992) restricted the group, follow- ing work by the Geological Survey of Greenland in 1978–1980, to include only the Neoproterozoic shal- low water carbonate and siliciclastic succession pre- sent in the area between Lambert Land and Independ- ence Fjord. Additional formations were also erected by Clemmensen & Jepsen, to improve the stratigraph- ical framework of the group. Hurst & McKerrow (1981a, b), on the basis of re- connaissance field work in Kronprins Christian Land in 1980 by the former Geological Survey of Green- land (GGU), concluded that all of the units beneath the Campanuladal Formation within the main thrust sheet were representative of a single unit of deep- water turbidites, mud and resedimented conglomer- ates; they collectively referred to this succession as the ‘Rivieradal sandstones’. Although sedimentologi- cal interpretations of the succession have been re- fined (see below), this is the concept that we here formalise as the Rivieradal Group. Hurst & McKerrow (1981a, b) and Hurst et al. (1985) recognised a number of thrust sheets in the Kron- prins Christian Land sector of the East Greenland Cal- edonides. These included the Vandredalen Nappe (which corresponds to Fränkl’s ‘main nappe’), the Finderup Land Nappe and the Sæfaxi Elv Nappe. The Finderup Land Nappe was a geographically isolated structure rimming the western edge of the main ice sheet, and a succession that incorporated the Campanuladal, Fyns Sø and Kap Holbæk Formations was recognised. Subsequent regional mapping by GGU in 1994–1995 has demonstrated that the Finderup Land Nappe is a northward continuation of the Vandreda- len Nappe (now the Vandredalen thrust sheet) in which only the higher stratigraphic levels are preserved. The Sæfaxi Elv Nappe was considered by Hurst & McKerrow to be a thrust sheet containing allochtho- nous Early Palaeozoic sediments that were deep-wa- ter equivalents of the platform succession, and these were assigned to the Harefjeld Formation by Hurst (1984). However, Rasmussen & Smith (1996) demon- strated that these sediments were highly strained equivalents of the platform succession, and that the lower contact with the underlying Fyns Sø Formation was an unconformity and not a thrust. The ‘Sæfaxi Elv Nappe’ is thus a succession of parautochthonous fore- land carbonates deformed in the foot wall of the Van- dredalen thrust, and the concept of an independent thrust sheet (and of the Harefjeld Formation) has been abandoned (Rasmussen & Smith 1996). Name. The group takes its name from Rivieradal, the E–W-trending valley south-east of Centrumsø that contains the most complete section through the unit (Higgins & Soper 1994, 1995). Type area and reference sections. The type area for the group is Rivieradal itself, where an excellent ref- erence section through the upper part of the group occurs and the lower part, although highly deformed, is also present. Additional reference sections through parts of the group are available through ‘Dunkeldal’ (between northern Vandredalen and inner Ingolf Fjord; Fig. 1), and along much of the western side of Van- dredalen between the western end of Ingolf Fjord and Romer Sø. Thickness. Hurst et al. (1985) estimated a thickness of 2.5 km for the ‘Rivieradal sandstones’. Structural stud- ies in Rivieradal and ‘Dunkeldal’, carried out during the 1994 and 1995 field seasons, suggest that the com- bined thickness of the highly deformed lower part of the Rivieradal Group and the less deformed upper part is substantially higher, in the order of 7.5–10 km (Higgins et al. 2001b). Lithology, facies associations and depositional envi- ronments. The sedimentological and stratigraphical variations within the Rivieradal Group should be viewed in the context of the internal structure of the Vandredalen thrust sheet, which is best exposed in the 35 km long section along Rivieradal between the thrust sheet front at the east end of Centrumsø and its trailing edge near Marmorvigen (Fig. 3). The western frontal region of the thrust sheet is characterised by simple, large-scale folds developed in the Fyns Sø and Kap Bernhard Formations; these overlie the Riviera- dal Group sediments, which are well exposed through- out the valley of Rivieradal. Steep to vertical dips char- acterise much of the western third of the section, with occasional west-facing fold pairs showing flat com- mon limbs. The central third of the section begins with an abrupt change to tightly developed folds, which become progressively more intense eastwards with the inclination of the axial surfaces decreasing GEUS Bulletin 6.pmd 10-02-2005, 09:5433 34 from moderate eastward dips to almost horizontal. In the eastern third of the section deformation is intense with complete erasure of sedimentary way-up indica- tors in long-limbed isoclinal folds; the units exposed here correspond to the most distal parts of the Rivie- radal Group. The fold style and orientation of strata in the Rivie- radal section suggest that the Vandredalen thrust fol- lows a series of ramps and flats, and can be viewed as sampling an oblique segment of the half-graben Hekla Sund Basin in which the Rivieradal Group accumu- lated. The oldest and most distal parts of the succes- sion are therefore preserved in the eastern part of the thrust sheet, and the younger and more proximal lithofacies are present in the west. The present-day distribution of remnants of the Rivieradal Group suc- cession indicates that the original Hekla Sund Basin must have been at least 200 km long from north to south and 50 km wide from east to west. The Rivieradal Group is lithologically variable and possesses a strong proximal to distal polarity. One of the most distinctive lithologies present is a coarse conglomerate, which occurs repeatedly along the lead- ing edge of the Vandredalen thrust sheet. Substantial conglomerate units are present in three discrete areas (Fig. 1). The northernmost is along a 15–20 km strike section on the west side of Romer Sø, the second is a 20 km long strike section on the west side of central Vandredalen, and the southernmost is found in south- ern Skallingen near Blåsø. The best known of the conglomeratic successions is that in central Vandredalen where several thick sec- tions have been measured. Quartzite clasts (90–95%) dominate everywhere over dolerite clasts (5–10%), and are probably derived from the Independence Fjord Group and the Midsommersø Dolerite Formation; these units are presumed to have been exposed to active erosion to the west of the basin. Clasts vary in size from a few decimetres to well over a metre in the thicker beds, with occasional outsize clasts as much as 3–4 m across; these large clasts are indisputably proximal. Viewed from a distance, the thick conglom- erate units appear to have a lensoid form, suggesting deposition in a series of nested channels. In E–W valley sections to the west of Romer Sø, rapid lateral facies changes are well exposed. Thick conglomerate-dominated units pass eastwards, over aS an ds to ne M ud st o ne M ud st o ne , s ilt st o ne an d sa nd st o ne C ar bo na te a nd ca lc ar eo us m ud st o ne Lo w er P al ae o zo ic p la tf o rm T U , T ur es ø F o rm at io n; B R , B ø rg lu m R iv er F o rm at io n; S F, Sj æ lla nd F je ld e Fo rm at io n; W V, W an de l V al le y Fo rm at io n R iv ie ra da l G ro up ( Pr o te ro zo ic ) O th er P ro te ro zo ic a nd L o w er P al ae o zo ic u ni ts : FS , F yn s Sø F o rm at io n; K B , K ap B er nh ar d Fo rm at io n; C D , C am pa nu la da l F o rm at io n; I F, In de pe nd en ce F jo rd G ro up 0 5 10 k m 1 km IF IF K B F S SF FS W V K B B R Pa ra ut o ch th o no us th ru st b el t V an dr ed al en th ru st f ro nt H ag en F jo rd G ro up R iv ie ra da l G ro up M ar m o rv ig en E SE W N W B R C D T U W V ? V A N D R E D A L E N T H R U ST Fig. 3. Cross-section through the Vandredalen thrust sheet along Rivieradal. See Fig. 1 for section line. Modified from Higgins et al. (2001b). GEUS Bulletin 6.pmd 10-02-2005, 09:5434 35 distance of 1–2 km, into upward-thickening packets of sandstone in which the individual beds coarsen upwards, sometimes into conglomerate. These in turn pass farther eastwards, over a similar distance, into upward-thickening and coarsening mudstone-siltstone- sandstone packets. In the southern area of conglomerates near Blåsø, rounded granite and quartz pebbles (up to 20%) make an appearance, although most clasts are again quartz- ite and dolerite; a deeper erosion level was evidently reached in the southern source region. The geometry of the conglomerate deposits, togeth- er with their discrete occurrences, suggests the pres- ence of three discrete fan delta systems that acted as major feeder distributary systems on the western side of the original basin. While the three main conglom- erate developments are all in the upper part of the Rivieradal Group succession, they may not be at ex- actly the same stratigraphical level. Input might have been via a single major fluvial system, which varied in position with time, and if so the Blåsø fan delta with its crystalline clasts may be the youngest of these. The repeated cycles of conglomeratic deposition, and the upward-coarsening sandstone cycles in other ar- eas at the frontal part of the thrust sheet, may have been controlled by displacements on the basin-mar- gin fault system. In ‘Dunkeldal’, a valley on the east side of Vandre- dalen, a total thickness of 3000 m has been measured in a continuously exposed section (lower part of meas- ured section in Fig. 4). The basal 200 m of this section lie above a thrust contact with Ordovician carbon- ates, and comprise strongly sheared conglomerates. The conglomerates are overlain by a 500 m thick phyllite-dominated unit (‘Stenørkenen Phyllites’ of Fränkl 1955), and then by over 2200 m of sandstone turbidites interbedded with dark pyritic mudstones (‘Taagefjeldene Greywackes’ of Fränkl). Laterally and vertically, this sandstone-dominated succession grades into homogeneous black mudstones, and equivalent phyllitic rocks, which are widely exposed around the innermost branch of Ingolf Fjord. The lack of marker horizons and non-exposure in the flat valley bottom of Vandredalen makes thickness estimates in these areas difficult; thus the notional gap of 350 m in the measured section of Fig. 4 may in fact correspond to several kilometres of section. On the west side of Vandredalen, to the north-west of innermost Ingolf Fjord, a 900 m thick succession comprises coarsening-upwards sequences of parallel laminated mudstone, lenticular and wavy-bedded mudstones, sandstone-dominated heterolithic sedi- ments with parallel lamination, trough cross-lamina- tion and hummocky cross-stratification, overlain by trough and planar cross-bedded sandstones with oc- casional herringbone cross-bedding (upper part of section in Fig. 4). These correspond to the original ‘Rivieradal sandstones’ of Fränkl (1955). Current di- rections are predominantly towards the north-east and are interpreted as the products of storm- and tide- dominated shallow marine deposition. This facies as- sociation in the upper part of the Rivieradal Group can be recognised throughout the outcrop area, from Romer Sø in the north to Blåsø in the south. On the west side of Vandredalen, the succession of Fig. 4 continues with about 300 m of interfingering conglom- erates and sandstones (the ‘Ulvebjerg Sandstones and Tillites’ of Fränkl – equivalent to the conglomeratic developments described above), which are overlain by sediments referred to the Hagen Fjord Group. The latter shallow marine succession constitutes the post- rift fill of the basin. The most distal representatives of the Rivieradal Group are seen in the valley of Rivieradal itself. At the eastern end of the valley, pelitic slates with sandstones form the coastal mountains south of the mouth of Rivieradal. These are overlain farther to the west by pelitic and calcareous slates and siltstones with promi- nent yellow-weathering carbonate units, which corre- spond to the ‘Sydvejdal Marbles with chloritic shales’ of Fränkl (1955). This unit is overlain, in turn, by phyllites and turbidites corresponding to those seen in the ‘Dunkeldal’ section (Fig. 4). Overall, the Rivieradal Group is characterised by point sources of sediment input which generated sub- stantial conglomerate fan deltas, and which are asso- ciated with sandy, proximal turbidites. Between the fans and in the eastern (distal) part of the basin, sedi- mentation was dominated by mud and calcareous mud. As the basin filled, the depositional style switched from deep to shallow marine, and less localised, more laterally persistent, tidal and storm-dominated depo- sition began to predominate. Boundaries. Since the group is restricted to the Van- dredalen thrust sheet, the Rivieradal Group is every- where bounded on its lower surface by the Vandre- dalen thrust; a stratigraphic base to the group has not been identified within the thrust sheet. The upper boundary of the group is placed where sandstones and laterally equivalent conglomerates are overlain by a characteristic 200 m variegated unit comprising a GEUS Bulletin 6.pmd 10-02-2005, 09:5435 3 6 1200 2500 3700 3600 3500 3400 3300 3200 3100 3000 2900 2800 2700 2600 2500 3800 3900 4000 4100 4200 4300 4400 4500 4600 4700 4800 4900 5000 2400 2300 2200 2100 2000 1900 1800 1700 1600 1500 1400 1300 1100 1000 900 800 700 600 500 400 300 200 1000 ? ? 'Taagefjeldene Greywackes' Massive Ta,b sandstone turbidites and black pyritic mudstones 'Stenørkenen Phyllites' ? Black phyllites, pyritic 'Taagefjeldene Greywackes' not exposed Black mudstones with thin sandstones Sandstone dominated coarsening-upward sequences Fyns Sø Fm Pale dolostone Kap Bernhard Fm Red limestone Campanuladal Fm. Variegated sandstones and mudstones 'Ulvebjerg Sandstones' Laterally interfingering conglomerates and sandstones 'Rivieradal Sandstones' Mudstone dominated coarsening-upward sequences Basal conglomerate B asal thrust M ud cracks C ro ss- bedding Parallel lam inatio n 'Rivieradal Sandstones' 'Taagefjeldene Greywackes' G E U S B u lle tin 6 .p m d 1 0 -0 2 -2 0 0 5 , 0 9 :5 4 3 6 37 lower greenish sandstone and mudstone interval over- lain by a dark red calcareous mudstone-dominated interval. The greenish sandstone and mudstone inter- val contains parallel and trough cross-laminated sand- stones and abundant desiccation cracks. The vari- egated unit is identified as the Campanuladal Forma- tion of the foreland and, as in the foreland, is overlain by brownish red weathering microbially laminated limestones of the Kap Bernhard Formation (Fig. 4). Distribution. The Rivieradal Group is restricted to the Vandredalen thrust sheet, and crops out in a broad zone extending from Romer Sø southwards along Vandredalen; a further broad zone extends from the eastern end of Centrumsø southwards through Rivie- radal and Skallingen to Blåsø (Fig. 1). A narrow strip of outcrops, in the hanging wall of the main thrust ramp, extends from Vardedalen (on the north side of central Ingolf Fjord) southwards to Brede Spærreglet- scher and along the west side of Hekla Sund to Mar- morvigen. The southernmost outcrops of the Riviera- dal Group are present in nunataks at the westernmost extremity of Lambert Land (Fig. 1). Geological age. The group is older than the Hagen Fjord Group, specifically the Kap Bernhard and Fyns Sø Formations, thought to be of probable Riphean age (Smith et al. 1999). However, Frederiksen (2000) has suggested the Hagen Fjord Group is Sturtian, and equivalent to the Andrée Land Group of the Eleonore Bay Supergroup. The Rivieradal Group post-dates the Independence Fjord Group, Midsommersø Dolerite Formation and Zig-Zag Dal Basalt Formation, all of which are represented by clasts within the conglom- eratic units. The dolerites of the Midsommersø Dolerite Formation were originally dated at c. 1230 Ma by Kals- beek & Jepsen (1984), but a recent baddeleyite age on a dolerite of 1380 Ma has been obtained by Upton et al. (in press); this provides a maximum age limit for deposition. The Rivieradal Group was thus deposited in the interval between 1380 Ma and ~ 700 Ma. G. Vidal (in Hurst et al. 1985) recorded ‘several comparatively well-preserved specimens’ of acritarchs from the upper part of the Rivieradal Group which were thought indicative of an upper Proterozoic age. In particular, a single specimen of Chuaria circularis was considered to be indicative of an upper Riphean age since, elsewhere in Scandinavia and North Ame- rica, the species occurs at around 800 Ma. Taken to- gether with the evidence for a conformable upper boundary, this suggests that the Rivieradal Group was deposited in the younger part of the broad age range outlined above. Subdivision. Fränkl (1954, 1955) recognised five units within the succession now assigned to the Rivieradal Group: ‘Stenørkenen Phyllites’, ‘Sydvejdal Marbles with chloritic shales’, ‘Taagefjeldene Greywackes’ with a layer of alum shales at the base, ‘Rivieradal Sandstones’, and the ‘Ulvebjerg Sandstones and Tillites’. These units were used as field terms during the 1994–1995 field seasons and proved to be recognis- able throughout the area, although this is at least partly because they represent lithological types rather than coherent and homologous stratigraphic units. The ‘Stenørkenen Phyllites’ are present in Rivieradal and similar phyllites are present throughout the region, although thickness estimates and correlation is ham- pered by the paucity of marker horizons. Fränkl (1955) estimated a thickness of > 1000 m. The ‘Sydvejdal Marbles with chloritic shales’ are also present in east- ern Rivieradal, and include pelitic and calcareous slates and siltstones with prominent yellow-weathering car- bonate units. Fränkl (1955) estimated a thickness of 100–400 m. The ‘Taagefjeldene Greywackes’ are best seen in the section through ‘Dunkeldal’ (Fig. 4), where Jepsen & Sønderholm (1994) recorded a thickness of over 2200 m. This compares with Fränkl’s (1954, 1955) estimate of > 700 m, of which 150–200 m were alum shales; multicoloured friable shales cover large areas around the head of Ingolf Fjord, and pass laterally (northwards) along Vandredalen into a sandstone- siltstone-mudstone succession. The ‘Rivieradal Sand- stones’ sensu Fränkl have a thickness of 1400 m, meas- ured in a section across Skallingen for which no base was present (Leslie & Jepsen 1995), and Jepsen & Søn- derholm (1994) measured a thickness of 900 m on the western side of Vandredalen (Fig. 4). Fränkl (1954) estimated a range of 1000–2000 m, which appears to be the right order of magnitude. The ‘tillites’ of Fränkl’s (1954, 1955) ‘Ulvebjerg Sandstones and Tillites’ unit were relatively soon re-interpreted as non-glacial Facing page: Fig. 4. Simplified measured section through part of the syn- rift Rivieradal Group succession, the lower part in ‘Dunkel- dal’, and the upper part from the west side of Vandredalen. The corresponding lithostratigraphical terms of Fränkl (1955) are indicated. The designation ‘T a,b ’ refers to Bouma cycle intervals in the sandstone turbidites. The Campanuladal, Kap Bernhard and Fyns Sø Formations form part of the post-rift Hagen Fjord Group. Slightly modified from Jepsen & Sønder- holm (1994). GEUS Bulletin 6.pmd 10-02-2005, 09:5437 38 conglomerate horizons (Haller 1971; Hurst & McKerrow 1981a), and they are one of the most spec- tacular stratigraphic developments within the group. On the western side of Vandredalen, a sandstone- dominated unit at least 300 m thick can be seen to pass laterally into thick conglomerates up to 500 m thick (Jepsen & Sønderholm 1994). As noted above, three of these major conglomerate developments are present within the region and represent fan deltas that supplied sediment to the basin. Although these observations indicate that Fränkl’s units may in time form the basis for a stratigraphic framework, any formal definition must await more detailed investigation of the Rivieradal Group. Acknowledgements We are grateful to the referees, L. Clemmensen and J.S. Peel, for their helpful comments. 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