Your search keyword '"SUBMARINE fans"' showing total 7 results

1. Downslope variability in deep-water slope channel fill facies and stacking patterns.

Author

Daniels, Benjamin G., Hubbard, Stephen M., Stright, Lisa, and Romans, Brian W.

Subjects

*SEDIMENTATION & deposition, *FACIES, *SANDSTONE, *SUBMARINE fans, *NATURAL resources, *SLOPE stability

Abstract

Lithologic variations in deep-water slope channel systems provide critical insight into sedimentary processes on deep-water slopes, and are a key control on natural resource distribution and connectivity in subsurface reservoirs associated with ancient deep-water systems. While many studies have described these variations at outcrop-scale along depositional strike (across-channel), few have focused on documenting along-depositional-dip changes due to: (1) the dearth of along-slope perspectives afforded by outcrops; or (2) limited resolution and coverage of subsurface data sets. In this study, slope channel elements (≤30 m thick; ≤400 m wide) and composite channelform bodies composed of ≥2 stacked channel elements (channel complexes and channel systems; >30 m thick; >400 m wide) were characterized along a 50-km-long depositional-dip-oriented outcrop belt of the Campanian-Maastrichtian Tres Pasos Formation (Chile) to constrain longitudinal changes in channel fill character and stacking patterns. Results show that channel elements become more sandstone-rich downdip. Outcrop observations are supported by channel element net-to-gross ratios (measures of sandstone proportion), which increase downdip. Sandstone-prone channel elements within channel complexes and channel systems are more prevalent downdip; however, variability in lateral and vertical offset between successive channel elements downdip results in a poor correlation between net-to-gross values and paleoslope position when composite channelform bodies are considered. These findings suggest that the along-slope distribution of coarse-grained sediment in channel systems is tied to the degree of coarse-grained sediment bypass and erosion that occurs along a slope. The results of this study provide a detailed perspective into downdip changes in slope channel fill and stacking patterns, and help clarify aspects of analogous subsurface reservoirs, including sandstone proportion trends for several scales of deep-water slope channel architecture. • Deep-water slope channel systems are analyzed using outcrop and subsurface data • Sandstone content in studied slope channel systems is found to increase downslope • Sandstone content is linked to sand-rich sediment bypass/deposition along a slope • Channel fill stacking is linked to autogenic processes and local slope morphology • Study findings provide insight into the properties of analogous reservoir units [ABSTRACT FROM AUTHOR]

Published

2024

2. Sedimentary characteristics of hyperpycnites in a shallow lacustrine environment: A case study from the Lower Cretaceous Xiguayuan Formation, Luanping Basin, Northeast China.

Author

Dou, Luxing, Hou, Jiagen, Song, Suihong, Zhang, Li, Liu, Yuming, Sun, Shuang, Li, Yongqiang, Wang, Xixin, Ren, Xiaoxu, Tang, Ying, Tian, Heng, Yang, Yuhua, and Patacci, M.

Subjects

*SEDIMENTATION & deposition, *SUBMARINE fans, *SEDIMENTOLOGY, *SANDSTONE, *CASE studies

Abstract

Hyperpycnites are extrabasinal turbidites related to hyperpycnal flows which form during river floods. Compared to intrabasinal turbidite systems in deep marine or lacustrine settings, hyperpycnites in shallow lakes settings are not understood. In this work, we studied the typical sedimentary characteristics of shallow lacustrine hyperpycnal flow deposits in outcrops of the Luanping Basin, Northeast China. Based on the sedimentary architecture and analysis of the facies associations in these outcrops, the hyperpycnites can be classified into the following three types: (a) bedload‐dominated erosional channel deposits, (b) bedload‐ and suspended‐load‐dominated channel‐to‐lobe transitional deposits, and (c) suspended‐load‐dominated lobe deposits. The erosional channels in proximal locations are filled by mud clasts, parallel‐laminated sandstones, massive sandstones, cross‐bedded sandstones, massive siltstones, and mudstones. The channel‐to‐lobe transitional deposits in a middle location are composed of parallel‐laminated sandstones, cross‐bedded sandstones, mud clasts near internal erosional surfaces, ripple cross‐bedded sandstones, massive siltstones, and mudstones. The lobe deposits in distal locations are composed of ripple cross‐bedded sandstones, massive siltstones, and mudstones. The sedimentary process of the shallow lacustrine hyperpycnal flows shows obvious response to periodic flood energy fluctuations. Gentle slope, small capacity of flood discharges and semiarid paleoclimate may be the possible reason for the observed sedimentary architecture of the shallow lacustrine hyperpycnal flow deposits. Therefore, this study offers new insights into the sedimentology of shallow lacustrine deposits in rift basins. [ABSTRACT FROM AUTHOR]

Published

2020

3. Intra‐clinothem variability in sedimentary texture and process regime recorded down slope profiles.

Author

Cosgrove, Grace I. E., Poyatos‐Moré, Miquel, Lee, David R., Hodgson, David M., McCaffrey, William D., Mountney, Nigel P., and Ghinassi, Massimiliano

Subjects

*SEDIMENTATION & deposition, *TURBIDITY currents, *SUBMARINE fans, *GRAIN size, *MASS-wasting (Geology), *SEDIMENTOLOGY, *SANDSTONE

Abstract

Shelf‐margin clinothem successions can archive process interactions at the shelf to slope transition, and their architecture provides constraints on the interplay of factors that control basin‐margin evolution. However, detailed textural analysis and facies distributions from shelf to slope transitions remain poorly documented. This study uses quantitative grain‐size and sorting data from coeval shelf and slope deposits of a single clinothem that crops out along a 5 km long, dip‐parallel transect of the Eocene Sobrarbe Deltaic Complex (Ainsa Basin, south‐central Pyrenees, Spain). Systematic sampling of sandstone beds tied to measured sections has captured vertical and basinward changes in sedimentary texture and facies distributions at an intra‐clinothem scale. Two types of hyperpycnal flow‐related slope deposits, both rich in mica and terrestrial organic matter, are differentiated according to grain size, sorting and bed geometry: (i) sustained hyperpycnal flow deposits, which are physically linked to coarse channelized sediments in the shelf setting and which deposit sand down the complete slope profile; (ii) episodic hyperpycnal flow deposits, which are disconnected from, and incise into, shelf sands and which are associated with sediment bypass of the proximal slope and coarse‐grained sand deposition on the medial and distal slope. Both types of hyperpycnites are interbedded with relatively homogenous, organic‐free and mica‐free, well‐sorted, very fine‐grained sandstones, which are interpreted to be remobilized from wave‐dominated shelf environments; these wave‐dominated deposits are found only on the proximal and medial slope. Coarse‐grained sediment bypass into the deeper‐water slope settings is therefore dominated by episodic hyperpycnal flows, whilst sustained hyperpycnal flows and turbidity currents remobilizing wave‐dominated shelf deposits are responsible for the full range of grain sizes in the proximal and medial slope, thus facilitating clinoform progradation. This novel dataset highlights previously undocumented intra‐clinothem variability related to updip changes in the shelf process‐regime, which is therefore a key factor controlling downdip architecture and resulting sedimentary texture. [ABSTRACT FROM AUTHOR]

Published

2020

4. Petrographic classification of sand and sandstone.

Author

Garzanti, Eduardo

Subjects

*SEDIMENTATION & deposition, *SANDSTONE, *SAND, *SUBMARINE fans, *TECHNICAL reports, *PETROLOGY

Abstract

Petrographic classifications of sand and sandstone proposed more than half a century ago are still in use, although they were formulated at a time when depositional and post-depositional sedimentary processes were poorly understood, and before the relationships between tectonics and sedimentation could be interpreted in modern plate-tectonic terms. As a consequence, too many scientific articles and technical reports are still encumbered with obsolete concepts, graphical tools, and ambiguous terminology that make sediment descriptions awkward and misleading. A renovation that treasures the legacy of the pioneers is required. The descriptive petrographic classification of sand and sandstone proposed in this paper is based on the quasi-universally used Gazzi-Dickinson point-counting method, and simply translates into words ternary compositions of quartz, feldspar, and lithic fragments without introducing any new names. The classic QFL plot is subdivided into 15 fields - labelled by adjectives introduced long ago by K.A.W. Crook and endorsed by W.R. Dickinson and more recently by G.J. Weltje - which reflect relative abundances of the three main framework components (provided they exceed 10%QFL). According to standard use, the less abundant component goes first, the more abundant last (e.g., litho-feldspatho-quartzose composition translates into Q > F > L > 10%QFL). For lithic-rich sand and sandstone, information on the prevailing rock fragment type can be added by an additional free adjective (e.g., metamorphiclastic, carbonaticlastic), as proposed long ago by R.V. Ingersoll. For lithic-poor feldspatho-quartzose and quartzose sand and sandstone, further formal subdivisions are proposed based on the Q/F ratio, thus reaching a total of 18 compositional fields overall. Modern sand known to be derived from different source rocks and found in major world's rivers, deserts, and deep-sea fans fits in the pigeonholes defined by the relative abundance of quartz, feldspar, and lithic fragments. The aim of this classification is to restore directness in sandstone petrology, and to avoid ambiguities generated in the past by making reference to badly defined archetypes, such as greywacke or arkose, thus confusing petrographic composition with subjective considerations about plate-tectonic setting, texture, hydraulic behaviour, mechanical durability, or chemical durability in the illusion that a classification could be genetic at the same time as descriptive. [ABSTRACT FROM AUTHOR]

Published

2019

5. Transitional flow deposits on submarine lobe flank (Veřovice and Lhoty Fms, Albian – Cenomanian, Polish Outer Carpathians).

Author

Łapcik, Piotr

Subjects

*SEDIMENTARY structures, *SEDIMENTATION & deposition, *SUBMARINE fans, *TURBIDITES, *SANDSTONE, *FACIES

Abstract

The Zagórnik-Rzyki studied section includes the upper part of the Veřovice Fm and the lower part of the Lhoty Fm (Aptian–Albian), which are small fragments of the much thicker sedimentary succession of the Silesian Nappe (Polish Outer Carpathians). Logged section gives a good insight into the relatively proximal but muddy submarine fan environment with at least partially confined nature and widely distributed facies of heterolithic deposits and banded sandstone. Three distinguished facies associations represent a gradual lateral shift toward the depositional lobe flank in a relatively proximal setting, away from the main sediment distribution pathways. The studied heterolithic deposits show various internal sedimentary structures (muddy ripples, draped ripples, low-amplitude bed-waves, low-angle laminated bedforms, small lenticular bedforms and plane-parallel laminated mudstone) considered as a record of the dynamic of sedimentary processes on a submarine depositional lobe flank environment. Despite the predominance of finning upward grain size trends (wanning flow deposits), sedimentary structures in the heterolithic deposits may stack in a varied order, also forming coarsening upward trend (waxing flow deposits), bi-gradational trend (waxing to wanning flow deposits), and complex trends (deposits with multiple waxing to wanning flow pulses) indicating record of hyperpycnal flows. Lack of hybrid event beds despite the occurrence of transitional flow deposits is evidence that even in mud-dominated to mixed sand-mud submarine turbidite systems, the flow transformation from fully turbulent to cohesive laminar behaviour is incomplete in relatively proximal depositional environment. Instead, a variety of facies banded sandstone and heterolithic deposits may represent a significant fragment of the sedimentary record in the proximal depositional lobe flank setting. [ABSTRACT FROM AUTHOR]

Published

2023

6. Can liquefied debris flows deposit clean sand over large areas of sea floor? Field evidence from the Marnoso-arenacea Formation, Italian Apennines.

Author

TALLING, PETER J., MALGESINI, GIUSEPPE, and FELLETTI, FABRIZIO

Subjects

*SEDIMENTATION & deposition, *OCEAN bottom, *GEOLOGICAL formations, *SANDSTONE, *TURBIDITY currents, *ROCKS, *SUBMARINE fans

Abstract

The Marnoso-arenacea Formation in the Italian Apennines is the only ancient rock sequence where individual submarine sediment density flow deposits have been mapped out in detail for over 100 km. Bed correlations provide new insight into how submarine flows deposit sand, because bed architecture and sandstone shape provide an independent test of depositional process models. This test is important because it can be difficult or impossible to infer depositional process unambiguously from characteristics seen at just one outcrop, especially for massive clean-sandstone intervals whose origin has been controversial. Beds have three different types of geometries (facies tracts) in downflow oriented transects. Facies tracts 1 and 2 contain clean graded and ungraded massive sandstone deposited incrementally by turbidity currents, and these intervals taper relatively gradually downflow. Mud-rich sand deposited by cohesive debris flow occurs in the distal part of Facies tract 2. Facies tract 3 contains clean sandstone with a distinctive swirly fabric formed by patches of coarser and better-sorted grains that most likely records pervasive liquefaction. This type of clean sandstone can extend for up to 30 km before pinching out relatively abruptly. This abrupt pinch out suggests that this clean sand was deposited by debris flow. In some beds there are downflow transitions from turbidite sandstone into clean debrite sandstone, suggesting that debris flows formed by transformation from high-density turbidity currents. However, outsize clasts in one particular debrite are too large and dense to have been carried by an initial turbidity current, suggesting that this debris flow ran out for at least 15 km. Field data indicate that liquefied debris flows can sometimes deposit clean sand over large (10 to 30 km) expanses of sea floor, and that these clean debrite sand layers can terminate abruptly. [ABSTRACT FROM AUTHOR]

Published

2013

7. Sedimentary processes of shallow-marine turbidite fans: An example from the Huangliu Formation in the Yinggehai Basin, South China Sea.

Author

Huang, Yintao, Tan, Xianfeng, Liu, Entao, Wang, Jia, and Wang, Jianpeng

Subjects

*SEDIMENTATION & deposition, *TURBIDITES, *SUBMARINE fans, *INTERNAL waves, *MIOCENE Epoch, *SANDSTONE

Abstract

The shallow-marine turbidite fans in the Upper Miocene Huangliu Formation of the Yinggehai Basin in the northwestern South China Sea (SCS) provide an excellent opportunity to understand their sedimentary processes in a shelf depositional environment. The down-slope gravity flow processes and along-slope bottom-current reworking processes of shallow-marine turbidite fans were interpreted by using seismic, well logging, core, petrographic, geochemical, and petrophysical data. Several depositional elements were identified in the shallow-marine turbidite fans, namely, channel-fill high-density turbidites (HDTs), channel-fill low-density turbidites (LDTs) and associated frontal splays, sand-rich/mud-rich lobe deposits, and bottom-current reworked channel-fill/lobe deposits. Deep U-shaped (or V-shaped) seismic reflections and low root-mean-square (RMS) amplitudes characterize the channel-fill HDTs that consist of massive fine-grained sandstones with mud clasts. The channel-fill LDTs, characterized by V-shaped or worm-shaped reflections, mostly consist of normally graded, laminated and rippled, very fine-grained sandstones. Frontal splays are generally associated with channel-fill LDTs. The sand-rich lobe deposits show continuous high-amplitude sheet-like reflections and consist of HDTs and LDTs, whereas the mud-rich lobe deposits show continuous moderate-amplitude reflections and consist of muddy debrites. The bottom-current reworked sandstones (BCRSs), which comprise well-sorted, fine-grained sandstones with traction-current structures, are usually located in the upper parts of thick sandbodies. The variability of depositional elements from large-scale channel-fill HDTs with strong basal erosion in fan-1 to small-scale channel-fill LDTs in fan-2 is closely linked with sea-level fluctuations that result in variable gravity-flow energy and sediment input. However, the reoccurrence of large-scale channel-fill HDTs in fan-3 at sea-level highstands may possibly be attributed to enhanced sediment input from the source areas. Down-slope flow transformation from turbidity flows into muddy debris flows within an individual channel-lobe complex (CLC) resulted in a dramatic increase in clay content and resultant decreasing reservoir quality from the channel-fill HDTs to the mud-rich lobe deposits, because muddy sediments are incorporated into the precursor turbidity flows and turbulence is suppressed. Additionally, it is suggested that the widely developed traction-current structures and tidal signatures (double mud layers, mud-draped ripples, discrete wavy bedding, internal truncation surface, and convex-up laminae) are the products of reworking by internal waves and -tides. During periods of sea-level highstands, the upper parts of gravity-flow sandstones would undergo bottom-current reworking, thus resulting in the retransportation of muddy fines and the formation of reworked sandstones with traction-current structures and tidal signatures. In this study, a combination of traction-current structures, tidal signatures, vertical sequences showing sharp upper contacts and non-gradational upper contacts, and trace elements is considered to be convincing diagnostic criteria in distinguishing reworked sandstones from gravity-flow sandstones. The representative bottom-current reworked sandstones should be preferable hydrocarbon targets in further exploration because of their better reservoir properties compared with gravity-flow sandstones. This research offers some insight into gravity-flow processes and bottom-current reworking processes in a shallow marine environment. • The variability of depositional elements is associated with sea-level fluctuations. • Down-slope flow transformations result in the variations of reservoir quality. • The upper parts of gravity-flow deposits have been reworked by internal waves and -tides. • An association of diagnostic criteria can help to identify bottom-current reworked sandstones. • The bottom-current reworked sandstones may represent a preferable hydrocarbon unit than turbidites. [ABSTRACT FROM AUTHOR]

Published

2021