白垩纪大洋红层的致色机制及成因研究

为了查明白垩纪大洋红层的致色矿物及其赋存状态,并探讨白垩纪大洋红层可能的制约因素及成因模式,本文以中国西藏床得剖面红色页岩、意大利Vispi Quarry剖面红色灰岩以及北大西洋ODP1049C孔12X岩芯段Aptian-Albian期高频旋回红色泥灰岩为研究对象,对各剖面(或岩芯)中的红色和非红色样品分别进行了X射线衍射和漫反射光谱测试,同时对配制的含赤铁矿的标样进行了同样的测试。测试结果表明,无论是红色页岩、红色灰岩,还是红色泥灰岩,赤铁矿都是主要的致色矿物,其中西藏床得剖面红色页岩由结晶较好的碎屑状赤铁矿和结晶较差的细分散状的赤铁矿共同致色。在意大利Vispi Quarry剖面红色泥岩中,结晶程度相近的赤铁矿是唯一的致色铁氧化物,而在ODP1049C孔红色泥灰岩中,结晶差的赤铁矿和针铁矿的出现是泥灰岩呈红色的矿物学根源。赤铁矿的形成主要受铁的来源、沉积时的氧化还原条件以及成岩作用的影响,这些因素也成为制约红层形成的关键因素。本课题组在多年研究的基础上,结合前人研究成果进一步从矿物学的角度深化了大洋红层的成因模式。     

沉积物中铁氧化物的定量方法及其 在白垩纪大洋红层中的应用

赤铁矿和针铁矿是自然界中最稳定的两种铁氧化物,广泛存在于地球的各个圈层。很多沉积物的颜色都是由它们引 起的,它们的形成和保存具有重要的环境指示意义。实验室中赤铁矿和针铁矿的表征和鉴定手段很多,但受其含量低、结 晶差、颗粒细小难分离等因素的困扰以及某些测试方法自身的限制,能用于铁氧化物定量分析的方法很少。文中就常用的 基于X射线衍射（XRD） 和漫反射光谱（DRS） 的铁氧化物定量方法进行了系统评价。在定性分析的基础上,采用基于 XRD的K值法获得西藏床得剖面红色页岩中赤铁矿的含量为3.81％~8.11％,采用DRS与多元线性回归相结合的方法获得北 大西洋ODP1049C孔12X岩芯段棕色层中赤铁矿和针铁矿的含量分别为0.13％~0.82％和0.22%~0.81％,橙色层中赤铁矿和 针铁矿的含量分别为0.19%~0.46％和0.29%~0.67％。与其它分析结果的比较表明,这两种定量方法在白垩纪大洋红层中的 应用是可行的。但在实际应用时,首先要通过XRD和DRS相结合来提高定性分析的准确性,然后通过综合分析铁氧化物的 预判含量范围和结晶程度来选择合适的定量方法。     

利用漫反射光谱鉴定红粘土中针铁矿和赤铁矿

针铁矿(Gt)和赤铁矿(Hm)是广泛存在于土壤和沉积物中的重要铁矿物。这两种矿物在土壤和沉积物中含量很低,常规的测试手段很难有效地测定其含量。利用反射光谱联合加热处理的方法,可对土壤及沉积物样品中针铁矿和赤铁矿进行定性或半定量测定。实验结果显示,样品加热到300℃后,针铁矿的反射光谱的一阶导数特征峰发生了变化,赤铁矿的一阶导数特征峰却没有明显的变化。因此加热前后样品反射光谱一阶导数的变化取决于针铁矿和赤铁矿的含量。利用这种方法估计黄土高原第三纪红粘土样品中的赤铁矿含量约为0.3%～0.4%,针铁矿含量约为0.5%～1%。     

红铁尘—红层的染色剂与砂岩铜矿的成因

在研究红层砂岩铜矿成矿规律和矿床成因的过程中,常会遇到构成岩石紫色和浅色的物质成分、岩石颜色的成因,以及其所代表的地质意义.通过几年的工作,我们把形成红层的紫色物质称为红铁尘.它分布广泛而普遍,在沉积成岩、成矿过程中具有很重要的意义;研究其地质过程有助于砂岩铜矿成因问题的解决和成矿规律的认识. 长期以来,人们都对红层的紫色给予一定的注意.在沉积矿物学、沉积岩石学和砂岩铜矿的研究中,认为形成红层的红色取决于其中所含的赤铁矿、褐铁矿和氢氧化铁等成分.例如,苏联普列奥勃拉任斯基等著的《沉积岩矿物》一书中指出:“形成于海底,含于盐矿层的红色夹层中;海成红色淤泥和粘土的红色取决于赤铁矿”.“杂     

青藏高原腹地湖泊沉积物磁化率及其环境意义

通过青藏高原腹地可可西里边缘地区BDQ0608 钻孔岩芯分析,表明其岩性主要为浅绿色湖相沉积物,其中夹杂部分较薄的氧化色层段.热退磁表明:BDQ0608钻孔中磁性矿物主要有磁铁矿、磁赤铁矿、针铁矿和胶黄铁矿,赤铁矿表现不太明显,其组分含量直接控制磁化率值的大小;并且对样品进行了磁化率、粒度、总有机碳及色度的测定.磁化率...     

碳酸盐岩红色风化壳中的氧化铁矿物

氧化铁矿物是碳酸盐岩红色风化壳的主要矿物成分和重要结构单元。运用X射线衍射、透射电镜、扫描电镜、穆斯堡尔谱和电子探针等方法对碳酸盐岩红色风化壳中的氧化铁矿物进行了系统研究。碳酸盐岩红色风化壳中的氧化铁矿物主要有针铁矿、赤铁矿和磁赤铁矿。氧化铁矿物组合、含量和化学成分随成土环境和风化强度在剖面中呈明显的规律性变化,这为碳酸盐岩风化成土作用、红色风化壳成因与环境问题的深入研究提供了重要的矿物学依据。     

西藏江孜地区海相白垩系铁赋存状态及古海洋意义

白垩纪黑色页岩至大洋红层的转变,预示着古海洋氧化还原条件及海洋-气候系统的改变。海相白垩纪黑色页岩与大洋红层在我国西藏江孜地区广泛发育,其中床得剖面已经成为海相白垩系研究的经典剖面之一,根据岩性的不同以及剖面上所表现出的风化色差异,床得剖面自底部至顶部可分为黑层段、白层段和红层段等岩性单元。本文以床得剖面为代表,分析了江孜海相白垩系黑色页岩至大洋红层样品中铁、铝含量、Fe3 /Fe2 比值的变化规律、铁的富集特征及其漫反射光谱特性。红层的铁、铝含量及Fe3 /Fe2 比值均远高于其它层位。红层中铁铝含量呈线性相关,认为红层中的铁元素主要来源于陆源输入,铁在红层中富集,是由于陆源输入的增加造成。而黑层和白层中铁铝相关系数很低,可能的解释是由于这两个层段中常见的黄铁矿化结核而导致铁的流失。漫反射光谱学实验显示黑层段和白层段下部的漫反射光谱略显435nm处针铁矿特征峰值,白层段上部反射光谱的峰值不明显,而红层样品在波长565nm处呈现赤铁矿特征峰值。因而,在红层中铁矿物主要以赤铁矿形式存在,而黑层和白层下部有针铁矿存在,在白层上部没有高价态铁矿物。床得剖面的红层段铁富集程度很高,黑层段和白层下部铁相对较为富集,而在白层上部,铁呈亏损状态。综合以上研究结果,我们认为江孜地区红层沉积时期大洋底层水为富氧状态,而黑层和白层下部可能为弱氧化状态,大洋缺氧沉积出现于白层上部。     

黄土剖面中赤铁矿和针铁矿的定量分析与气候干湿变化研究

为了了解黄土剖面中赤铁矿和针铁矿的分布特征,文章采用对铁氧化物矿物灵敏的漫反射光谱法(DRS),开展了赤铁矿和针铁矿的鉴定和测定研究,提出了定量分析赤铁矿和针铁矿含量的DRS新方法.选择天然典型黄土和古土壤样品,首先采用柠檬酸盐-重碳酸盐-连二亚硫酸盐(CBD)方法去除其中成壤成因的铁氧化物矿物,以其为基体配制含不同赤铁矿和针铁矿的系列标样,然后进行DRS测试和多元逐步回归分析,分别建立测定赤铁矿和针铁矿含量的校准方程并加以检验.利用DRS方法,分析了多个黄土剖面的赤铁矿和针铁矿含量,发现黄土-古土壤剖面的赤铁矿/针铁矿比值可作为东亚季风干/湿变化的敏感指标.该比值较高时反映了干燥土壤环境,而较低时指示了潮湿土壤环境.对灵台和洛川剖面中赤铁矿/针铁矿比值的分析,初步揭示了2.6Ma年以来黄土高原东亚季风阶段性变强的特征.     

3种典型富锰沉积物的形貌学与矿物学特征

本文采集了3种典型的富锰沉积物样品,即岩石漆、树枝晶与土壤铁锰胶膜,并制作了相应的纵切片。运用光学显微镜、原位微区拉曼光谱仪、扫描电镜、EDX能谱仪分别对其形貌学与矿物学特征进行了研究。结果表明岩石漆呈黑色致密层状、葡萄状,主要由水钠锰矿、赤铁矿、针铁矿、粘土矿物等组成,是一种高度混杂的沉积物。宏观上岩石漆与基岩有截然的接触面,发育有微层理结构,在微观上的表现即锰含量的周期性波动。树枝晶呈黑色分枝状,主要由锰钡矿组成,极端富锰而贫硅铝,与基质呈交织结构。土壤铁锰胶膜呈黑色粘稠层状,由水钠锰矿、赤铁矿、针铁矿、钛铁矿、粘土矿物等组成,可细分为外层黑褐色的富锰条带和内层黄棕色的富铁条带。这3种富锰沉积物的形貌学和元素分布特征与各自的成因机制密切相关。     

长江三角洲晚新生代沉积物磁性特征和磁性矿物及其指示意义

笔者通过对长江三角洲平原晚新生代钻孔SG7孔沉积物的粒度和磁性分析,揭示磁性矿物类型随时间的演变,探讨新构造运动、气候、海平面等对本区沉积物源、沉积环境的耦合作用。研究结果显示,上新世磁性强弱相间,且达到全剖面最强,磁性矿物为磁铁矿、磁赤铁矿、针铁矿和黄铁矿,反映本区气候暖湿,发育山间湖泊,沉积物主要来自周边白龙港玄武岩的风化产物;早更新世早期,磁性为全剖面最弱,以磁铁矿为主,反映在构造沉降作用下,发生物源改变,即主要来自贫铁的中酸性浅成岩或喷出岩,同时沉积物主要为冰期的河道相沉积,反映山间河流/冲积扇环境;早更新世晚期至晚更新世末,磁性显著增强且和沉积物粗细变化一致,粗颗粒沉积物中磁性矿物以变质岩来源的粗粒磁铁矿为主,细粒沉积物中磁性矿物见针铁矿、赤铁矿和黄铁矿,反映古地理环境逐渐向冲积平原、滨海平原演变;自晚更新世晚期出现细粒磁赤铁矿和磁铁矿,反映长江上游物源的加入。全新世沉积物磁性较更新世泥质沉积物显著增强,反映长江河口、三角洲环境。     

福建白垩系沙县组地层磁学特征及其环境意义

广泛分布于中国南方的白垩系巨厚地层被认为是河湖相沉积,蕴含着丰富的古气候古环境变化的信息。白垩纪是典型的温室时期,其气候特征可以为当代和未来温室气候研究提供重要借鉴。对位于中国东南的福建省三明市沙县和永安地区的白垩系沙县组典型地层进行了系统的环境磁学参数测量,结合漫反射光谱(DRS)和色度指标,探讨了该地层磁学特征及其环境指示意义和红色的成因。结果表明:1)红色调和黄色调地层的主要磁性矿物分别为赤铁矿和针铁矿,均含有顺磁性矿物和极少量的亚铁磁性矿物;2)相对于粗粒的砂岩,细粒的粉砂岩赤铁矿含量较高;3)红色赤铁矿与黄色针铁矿均形成于成岩阶段之前,具体形成阶段与形成原因需要具体分析;4)红色调地层的赤铁矿指示高温的气候环境;黄色调地层的针铁矿指示局部的湿润环境。磁学参数变化的具体环境指示意义需要进一步研究。     

Constraining the colouration mechanisms of Cretaceous Oceanic Red Beds using diffuse reflectance spectroscopy

We have used diffuse reflectance spectroscopy to investigate the colouration mechanisms of hematite in Cretaceous Oceanic Red Beds (CORBs). Data for samples of CORBs from the Chuangde section in Tibet, Vispi Quarry section in Italy, and Core 12X of Ocean Drilling Program Hole 1049C in the North Atlantic were compared with calibration datasets obtained for hematite in different crystalline forms (kidney and specular hematite) and calcite matrix. Spectra for hematite in either pure form or in calibration datasets show that the centre of the reflection peak shifts to a longer wavelength and depth (D) decreases as the crystallinity of the hematite increases. Compared with specular hematite, the presence of just 0.5% of kidney hematite can cause a much deeper absorption peak and greater redness value, which indicates that kidney hematite has a higher colouration capacity than specular hematite. However, both kidney and specular hematite exhibit a good correlation between the redness value for each calibration dataset and the absorption peak depth. In all three studied sections, hematite is the main iron oxide mineral responsible for colouration. Spectral features such as absorption peak depth and peak centre reveal that hematite crystallinity gradually decreases from red shale to limestone to marl. Based on a spectral comparison of red shale in the Chuangde section before and after citrate–bicarbonate–dithionite (CBD) treatment, we found that two forms of hematite are present: a fine-grained and dispersed form, and a detrital form. The former is relatively poorly crystalline hematite, which has a much stronger colouration capacity than the detrital form. In the Vispi Quarry section and Core 12X of ODP Hole 1049C, a good correlation between the absorption peak depth of hematite and redness value indicates that the red colouration is caused by hematite of similar crystallinity in each section.     

Opaque mineralogy and magnetic properties of selected banded iron‐formations,Hamersley Basin,Western Australia

The oxide mineralogy and rock magnetic properties of unmineralised banded iron‐formations in selected portions of four drillholes in the Hamersley Basin, Western Australia are reviewed. In all four drillholes, petrographic studies indicate that primary euhedral to subhedral hematite is partially replaced by magnetite as a result of subsolidus reduction. All drillholes show partial recrystallisation of the secondary magnetite, suggesting that early subsolidus reduction was probably a regional event occurring during prograde metamorphism. Incomplete replacement of primary hematite by magnetite within and between sedimentary band structures indicates that equilibration in the magnetite stability field was not reached even at the mesoband scale. Subsequent subsolidus oxidation of magnetite and the formation of a second‐generation hematite are documented in only two of the drillholes. Goethite‐filled veins and thick selvages of goethite around some veins reflect movement of circulating oxidising fluids. The absence of goethite and second‐generation hematite in two of the drillholes indicates that subsolidus oxidation is not a regional event, but very much localised. Rapid changes in down‐hole susceptibility measurements correlate directly with detailed petrographic results as susceptibility readings change with the hematite/magnetite ratio on a mesoband scale. Acquisition of the main remanence correlates with the formation of hematite as the primary oxide phase followed by partial replacement by magnetite as a result of subsolidus reduction, supporting regional models requiring pre‐folding remanence. The strong orientation of the primary hematite parent parallel to band structures in the banded iron‐formations has influenced the direction of crystallisation remanent magnetisation during subsolidus reduction to the magnetite daughter. The strong planar alignment has also produced a planar magnetic fabric and marked anisotropy of magnetic susceptibility. A natural remanent magnetisation overprint and reduction in anisotropy of magnetic susceptibility are only recorded in samples that have undergone subsolidus oxidation and the recognition of localised post‐metamorphic oxidation overprinting can also explain ore deposit models requiring post‐folding remanence. The relative timing of and between oxidising fluid events is not known, but both petrographic and rock magnetic evidence to date suggests that there was at least one and probably two post‐folding oxidising events in the area of study.     

江西信江盆地上白垩统风成红层的古地磁研究

红层是古地磁学的重要研究对象之一。以往对河湖相红层的古地磁研究较多,而对于风成红层的研究较少。因 此,对于风成红层剩磁记录是否可靠等基本问题仍然缺乏清晰的认识。文章对江西信江盆地上白垩统圭峰群塘边组风成 红层和河口组河流相红层开展了古地磁研究,并通过对比风成红层与河流相红层的古地磁结果,探究风成红层剩磁记录 的可靠性及不同沉积过程对古地磁记录的影响。逐步热退磁实验结果显示仅有19% 的塘边组风成红层分离出稳定的特征 剩磁,而且其强度衰减曲线为凸形,表明特征剩磁为碎屑赤铁矿携带的原生剩磁。其平均方向为Ds=15.6 °, Is=28.9 °, n= 25, κ=13.0, α95=8.3 °;对应的古地磁极为Latitude=70.7 °, Longitude=245.6 °, A95=6.8 °。该古地磁极与赣州地区河湖相红层 的古地磁极及华南晚白垩世的古地磁极位置一致,表明风成红层的剩磁记录是可靠的。河口组河流相红层绝大部分样品 未能分离出稳定的特征剩磁。磁化率各向异性结果显示塘边组和河口组为沉积组构。岩石磁学结果表明,载磁矿物为赤 铁矿和磁铁矿。通过对塘边组风成红层的薄片观察和红度值比较等进一步研究表明,颗粒粒度和胶结程度可能对红层剩 磁记录的稳定性有一定影响。     

江西信江盆地上白垩统风成红层的古地磁研究

红层是古地磁学的重要研究对象之一。以往对河湖相红层的古地磁研究较多，而对于风成红层的研究较少。因 此，对于风成红层剩磁记录是否可靠等基本问题仍然缺乏清晰的认识。文章对江西信江盆地上白垩统圭峰群塘边组风成 红层和河口组河流相红层开展了古地磁研究，并通过对比风成红层与河流相红层的古地磁结果，探究风成红层剩磁记录 的可靠性及不同沉积过程对古地磁记录的影响。逐步热退磁实验结果显示仅有19% 的塘边组风成红层分离出稳定的特征 剩磁，而且其强度衰减曲线为凸形，表明特征剩磁为碎屑赤铁矿携带的原生剩磁。其平均方向为Ds=15.6 °, Is=28.9 °, n= 25, κ=13.0, α95=8.3 °；对应的古地磁极为Latitude=70.7 °, Longitude=245.6 °, A95=6.8 °。该古地磁极与赣州地区河湖相红层 的古地磁极及华南晚白垩世的古地磁极位置一致，表明风成红层的剩磁记录是可靠的。河口组河流相红层绝大部分样品 未能分离出稳定的特征剩磁。磁化率各向异性结果显示塘边组和河口组为沉积组构。岩石磁学结果表明，载磁矿物为赤 铁矿和磁铁矿。通过对塘边组风成红层的薄片观察和红度值比较等进一步研究表明，颗粒粒度和胶结程度可能对红层剩 磁记录的稳定性有一定影响。     

Iron mineralization in the Garagu Formation of Gara Mountain,Duhok Governorate,Kurdistan, NE Iraq: geochemistry,mineralogy and origin

The iron mineralization is hosted in carbonate beds of the Garagu Formation (Early Cretaceous) at Gara Mountain, Duhok Governorate, Kurdistan Region, NE Iraq. The Garagu Formation is composed of a series of limestone and siltstone beds with iron-rich beds in the middle part. The iron-rich limestones are iron-rich oolitic grainstone and bioclastic wackestone with hematite and goethite minerals. Geochemical results drawn from this study indicate that the percentage of iron in these beds reaches 19.73 %. Moreover, petrographical investigation of thin and polished sections reveals the presence of different types of fossils, indicating an open marine interior platform depositional environment. Different iron minerals, including hematite, goethite, siderite, pyrite and magnetite, were identified in the sections, and their geneses were related to syngenetic and diagenetic processes. The geochemical distribution of major and trace elements, as well as the V/Ni, V/(V+Ni), V/Cr and Sr/Ba ratios, indicates a reducing environment during the precipitation of carbonate sediments and a subsequent oxidizing condition during the concentration of iron minerals via diagenesis.     

Origin of red beds in the Ringerike Group (Silurian) of Norway

The Ringerike Group is a meandering fluviatile succession which is about 60% red. Most of the red zones are formed of mudrocks and siltstones and correspond to the fine members of fining-upwards cyclothems. The majority of coarse members are drab coloured.Textural studies of thin and polished sections show that the red colour is caused by finely crystalline hematite as matrix and grain-coatings. This hematite apparently crystallized post-depositionally. Hematite also occurs in other textural sites: within altered phyllosilicates, as detrital grains and as totally pseudomorphed phyllosilicates. This, and the lack of consistency between colour and clay mineralogy, suggests that the red beds have had a long and complex diagenetic history.Iron analyses indicate that the red beds are enriched in Fe³⁺ and total iron (FeO) by about 1%. This is thought to have been derived from the pre-depositional weathering of iron minerals and introduced into the sediments as amorphous iron hydroxide or iron-bearing clays. Crystallization of iron hydroxide under oxidizing conditions and the post-depositional alteration of iron-silicates and oxides is thought to be responsible for the formation of the red beds.