The role of provenance in the diagenesis of siliciclastic reservoirs in the Upper Triassic Yanchang Formation, Ordos Basin, China

Ding, Xiaoqi; Han, Mei; Zhang, Shaonan

doi:10.1007/s12182-013-0262-9

Cited by 17 publications

(8 citation statements)

References 23 publications

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“…These samples are derived from two principal provenance directions: samples N75, B12, L189, Z129, and Z191 are originated primarily from the Qinling and Liupanshan orogenic belts in the southwest, whereas the sands in sample H218 are derived from the Yinshan palaeocontinental terrain in the northeast. Sample S110, on the other hand, is believed to be of mixed provenance. ,, These samples were subjected to thin section petrology, scanning electron microscope (SEM), X-ray diffraction (XRD), X-ray fluorescence (XRF), and NMR analyses.…”

Section: Sampling and Methodologymentioning

confidence: 99%

“…Sample S110, on the other hand, is believed to be of mixed provenance. 14,15,18 These samples were subjected to thin section petrology, scanning electron microscope (SEM), X-ray diffraction (XRD), X-ray fluorescence (XRF), and NMR analyses.…”

Section: Sampling and Methodologymentioning

confidence: 99%

“…The tight sandstone of Chang-7 Member in the Ordos Basin was deposited within a lacustrine basin, with significant provenance variability, and under diverse sedimentary conditions . This resulted in a diversity of mineralogical composition and highly variable diagenetic evolution of the sandstones . Intense compaction, facilitated by fine grain size and high clay content, together with late-stage carbonate cementation, are deemed to be the major cause for porosity loss in the Chang-7 sandstone. ,, These conclusions are based on consideration of total porosity variation during digenetic processes, as in conventional reservoirs.…”

Section: Introductionmentioning

confidence: 99%

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Diagenetic Controls on the Reservoir Quality of Fine-Grained “Tight” Sandstones: A Case Study Based on NMR Analysis

et al. 2018

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Accurate description of diagenetic controls on reservoir quality in “tight” sandstones can be difficult because of the inherent fine grain size and complex components of such oil reservoirs. In this study, petrological techniques and nuclear magnetic resonance (NMR) analysis were applied to fine-grained tight sandstones with varying grain sizes in order to reveal the diagenetic controls on reservoir quality. Results show that macropores in tight sandstones occur mainly as intergranular and dissolution pores, whereas micropores are distributed within ductile rock fragments, clay, and mica minerals, as well as occurring as dissolution micropores. Pore size distribution (PSD)/T 2 spectra display three distribution patterns: (i) a macropore-dominant bimodal distribution, (ii) a macropore–micropore bimodal distribution, and (iii) a micropore-dominant skewed distribution. A decrease in grain size correlates with weaker framework support of particles and thus more intensive mechanical compaction, resulting in the loss of both macroporosity and microporosity. Consequently, PSD change from macropore-dominant bimodal distributions to micropore-dominant skewed distributions as the pore type shifts from being dominated by macropores to intragranular micropores. In fine-grained sandstones, an increase in the abundance of ductile components corresponds to a loss of total porosity, related to the decrease in abundance of macropores, whereas the change in micropore abundance is negligible. This change is reflected in PSD by a shift from macropore-dominant bimodal distributions to macro–micropore bimodal distributions. The authigenic minerals in tight sandstone reservoirs occur mainly as late-stage carbonate minerals, and the precipitation of this carbonate cement preferentially occurs within macropores. When carbonate cement content is low, it has a limited influence on total porosity. However, it does significantly reduce the connectivity of the pore system, which is different from what might be expected in conventional sandstone reservoirs. Therefore, particle grain size, the abundance of ductile components, and late-stage cementation all contribute to the prediction of reservoir quality in oil-bearing tight sandstones.

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Section: Sampling and Methodologymentioning

confidence: 99%

Section: Sampling and Methodologymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Diagenetic Controls on the Reservoir Quality of Fine-Grained “Tight” Sandstones: A Case Study Based on NMR Analysis

et al. 2018

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“…The 7th and 6th members of the Yanchang Formation in the Binchang area of the Ordos Basin were deposited in a deep-water environment (Lei et al 2015) and are the main production formation of tight oil in China (Yang et al 2012;Ding et al 2013;Yuan et al 2015). Understanding the origin, distribution pattern, scale and continuity of this sandstone is important, and these factors must be considered during exploration and decision-making in the development of the oil field.…”

Section: Introductionmentioning

confidence: 99%

Origin and depositional model of deep-water lacustrine sandstone deposits in the 7th and 6th members of the Yanchang Formation (Late Triassic), Binchang area, Ordos Basin, China

et al. 2017

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Sandstones attributed to different lacustrine sediment gravity flows are present in the 7th and 6th members of the Yanchang Formation in the Ordos Basin, China. These differences in their origins led to different sandstone distributions which control the scale and connectivity of oil and gas reservoirs. Numerous cores and outcrops were analysed to understand the origins of these sandstones. The main origin of these sandstones was analysed by statistical methods, and well logging data were used to study their vertical and horizontal distributions. Results show that the sandstones in the study area accumulated via sandy debris flows, turbidity currents and slumping, and sandy debris flows predominate. The sandstone associated with a single event is characteristically small in scale and exhibits poor lateral continuity. However, as a result of multiple events that stacked gravity flow-related sandstones atop one another, sandstones are extensive overall, as illustrated in the cross section and isopach maps. Finally, a depositional model was developed in which sandy debris flows predominated and various other types of small-scale gravity flows occurred frequently, resulting in extensive deposition of sand bodies across a large area.

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“…Studies have been performed on many sedimentary formations such as the Upper Triassic Yanchang Formation in the Ordos Basin Ding et al 2013;Zhang et al 2013;Zhu et al 2015), the Upper Jurassic in the Songliao Basin (Zeng 1996), Xujiahe Formation in the Sichuan Basin Huang et al 2010;Zou et al 2013), Middle Jurassic Shaximiao Formation in the Sichuan Basin (Lü et al 2015), Jurassic Sangonghe Formation in the Junggar Basin (Xi et al 2015), Upper Cretaceous in the Santos Basin, Brazil (Bahlis and Luiz 2013), and the Lower Vicksburg Formation in Southern Texas (Grigsby 2001). However, the clastic sequences which developed grain-coating chlorite in these sedimentary basins have varying characteristics.…”

Section: Introductionmentioning

confidence: 99%

Formation mechanisms and sequence response of authigenic grain-coating chlorite: evidence from the Upper Triassic Xujiahe Formation in the southern Sichuan Basin, China

Lin

Gao

2016

Pet. Sci.

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Authigenic grain-coating chlorite is widely distributed in the clastic rocks of many sedimentary basins around the world. These iron minerals were mainly derived from flocculent precipitates formed when rivers flow into the ocean, especially in deltaic environments with high hydrodynamic conditions. At the same time, sandstone sequences with grain-coating chlorites also tend to have relatively high glauconite and pyrite content. EPMA composition analysis shows that glauconites with ''high Al and low Fe'' content indicate slightly to semi-saline marine environments with weak alkaline and weakly reducing conditions. By analyzing the chlorite-containing sandstone bodies of the southern Sichuan Xujiahe Formation, this study found that chlorite was mainly distributed in sedimentary microfacies, including underwater distributary channels, distributary channels, shallow lake sandstone dams, and mouth bars. Chlorite had a tendency to form in the upper parts of sandstone bodies with signs of increased base level, representing the influence of marine (lacustrine) transgression. This is believed to be influenced by megamonsoons in the Middle and Upper Yangtze Region during the Late Triassic Epoch. During periods of abundant precipitation, river discharges increased and more Fe particulates flowed into the ocean (lake). In the meantime, increases or decreases in lake level were only affected by precipitation for short periods of time. The sedimentary environment shifted from weakly oxidizing to weak alkaline, weakly reducing conditions as sea level increased, and Fe-rich minerals as authigenic chlorite and glauconite began to form and deposit.

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The role of provenance in the diagenesis of siliciclastic reservoirs in the Upper Triassic Yanchang Formation, Ordos Basin, China

Cited by 17 publications

References 23 publications

Diagenetic Controls on the Reservoir Quality of Fine-Grained “Tight” Sandstones: A Case Study Based on NMR Analysis

Diagenetic Controls on the Reservoir Quality of Fine-Grained “Tight” Sandstones: A Case Study Based on NMR Analysis

Origin and depositional model of deep-water lacustrine sandstone deposits in the 7th and 6th members of the Yanchang Formation (Late Triassic), Binchang area, Ordos Basin, China

Formation mechanisms and sequence response of authigenic grain-coating chlorite: evidence from the Upper Triassic Xujiahe Formation in the southern Sichuan Basin, China

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