Stratigraphic correlation and provenance study of exposed Eocene - Oligocene sedimentary sequences in southern Nigeria using high-resolution heavy minerals and garnet geochemical analyses

IF 2 4区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
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引用次数: 0

Abstract

Provenance and stratigraphic correlations across the exposed Eocene-Miocene sedimentary sequences of southern Nigeria that exhibit similar lithologies and are biostratigraphically-barren have been carried out. Heavy mineral assemblages in the 63–250 μm sand fractions of 43 sediment samples across the sedimentary sequences were assessed via wet-sieving, centrifugation, and polarizing petrologic microscopic analyses. Opaque, apatite, garnet, kyanite, zircon, rutile, staurolite, tourmaline, and epidote heavy mineral species were identified and point-counted. Electron microprobe analysis was carried out on the garnet-heavy mineral species using a CAMEBAX Cameca electron microprobe with a link four-wavelength energy-dispersive mode spectrometer analyser. This study revealed the existence of three heavy mineral associations and three lithostratigraphic formations. Heavy mineral association A is characterized by assemblages of kyanite, zircon, and rutile grains. The occurrence of kyanite in this association indicates derivation from schist and gneissic rocks. Zircon grains indicate sialic to intermediate igneous rocks derivatives that has sustained several periods of recycling, and redeposition. The occurrence of rutile indicates metamafic and metapelitic rocks with other sources being minor. Heavy mineral association B is characterized by assemblages of staurolite, opaque materials, garnet, and epidote. The presence of opaque grains indicates a shorter distance of transport possibly from proximity. The occurrence of staurolite grains indicates metamorphic and magmatic rock derivatives from schists, slates, and gneisses. Garnets are predominantly derived from high-grade metamorphic rock (granulite-facies) metasediments and charnockites and lower grade (amphibolite-facies) metasedimentary rocks and granitoids. An epidote is a metamorphosed igneous rock derived from the adjoining radix. Heavy mineral association C is characterized by assemblages of tourmaline and apatite. Tourmaline grains indicate pneumatolytic rocks, pegmatite, schist, gneisses, and marble source rocks. Apatite indicates derivation from local outcrops exposed during the Benue Trough uplift. The occurrence of apatite and its assemblages with tourmaline indicate felsic igneous rocks with ultramafic compositions, metamorphic rocks with low to high grades and derivatives of diverse protolith compositions. The exposed Eocene-Miocene sedimentary deposits that exhibit similar lithologies and biodata are relatively lacking. They were differentiated into three different lithostratigraphic formations and correlated. These analyses were performed using heavy mineral characterization, optical property, garnet geochemical composition, and inference supported by multivariate statistical analyses. Variations in the numerical values of unstable heavy minerals reveal dissolution and overgrowth through acidic groundwater, changes in climatic conditions, and relative eustatic sea-level changes. This study was able to derive information and demonstrate, differentiate, and validated the significance of resolving provenance and stratigraphic uncertainties using a heavy mineral and garnet geochemical-based approach. These findings were supported by multivariate statistical analyses. This methodology will help to facilitate the prediction and correlation of hydrocarbon reservoirs and source rocks in sedimentary basins globally.

利用高分辨率重矿物和石榴石地球化学分析,对尼日利亚南部出露的始新世-渐新世沉积序列进行地层关联和成因研究
对尼日利亚南部出露的始新世-中新世沉积序列进行了产状和地层学关联研究,这些沉积序列呈现出相似的岩性,并且在生物地层学上是贫瘠的。通过湿筛、离心和偏振岩石显微镜分析,对沉积序列中 43 个沉积物样本的 63-250 μm 沙粒中的重矿物组合进行了评估。对不透明、磷灰石、石榴石、褐铁矿、锆石、金红石、金钨矿、电气石和绿帘石等重矿物种类进行了鉴定和点计数。使用带有链接四波长能量色散模式光谱分析仪的 CAMEBAX Cameca 电子微探仪对石榴石重矿物种类进行了电子微探分析。这项研究揭示了三种重矿物组合和三种岩层构造。重矿物集合体 A 的特征是由闪锌矿、锆石和金红石颗粒组成的集合体。该集合体中出现的闪锌矿表明其来源于片岩和片麻岩。锆石颗粒表明矽卡岩到中间火成岩的衍生物经历了几个时期的再循环和再沉积。金红石的出现表明其来源于偏闪长岩和偏闪长岩,其他来源较少。重矿物群 B 的特征是集合了白云母、不透明物质、石榴石和绿帘石。不透明颗粒的出现表明其搬运距离较短,可能是由于距离较近。辉绿岩颗粒的出现表明了来自片岩、板岩和片麻岩的变质岩和岩浆岩衍生物。石榴石主要来源于高品位变质岩(花岗片岩型)变质岩和角闪岩,以及低品位(闪长岩型)变质岩和花岗岩。闪长岩是一种变质火成岩,由邻近的放射岩衍生而来。重矿物群 C 的特征是电气石和磷灰石的集合体。电气石颗粒表明是气成岩、伟晶岩、片岩、片麻岩和大理石源岩。磷灰石表明其来源于贝努埃海槽隆升过程中露出的当地露头。磷灰石的出现及其与电气石的组合表明了具有超基性成分的长粒火成岩、从低到高品级的变质岩以及不同原岩成分的衍生物。出露的始新世-中新世沉积沉淀物显示出类似的岩性和生物数据,但相对缺乏。这些沉积物被区分为三种不同的岩相地层,并进行了相关分析。这些分析是利用重矿物特征、光学性质、石榴石地球化学成分以及多元统计分析支持的推论进行的。不稳定重矿物数值的变化揭示了酸性地下水的溶解和过度生长、气候条件的变化以及相对震旦纪海平面的变化。这项研究能够利用基于重矿物和石榴石地球化学的方法获取信息,并证明、区分和验证解决出处和地层不确定性的意义。这些发现得到了多元统计分析的支持。该方法将有助于促进全球沉积盆地油气储层和源岩的预测和关联。
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来源期刊
Solid Earth Sciences
Solid Earth Sciences GEOSCIENCES, MULTIDISCIPLINARY-
CiteScore
3.60
自引率
5.00%
发文量
20
审稿时长
103 days
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