贵州织金新华含稀土磷矿床稀土元素地球化学研究

对贵州织金新华含稀土磷矿床进行的稀土元素及微量元素分析结果表明,磷块岩中普遍富集稀土元素,含稀土总量∑REE较高,并富集Y、La、Nd等重稀土及轻稀土元素.LREE/HREE比值较高,但低于上部围岩之值.含稀土磷块岩普遍具Ce的负异常,显示其对源区的继承性,也指示成磷环境处于氧化程度相对较高状态.稀土元素球粒陨石标准化模式曲线、北美页岩标准化模式曲线、Ce元素异常、LREE/HREE比值、微量元素特征及岩石矿物特征表明,织金新华含稀土磷矿床具以正常海相生物-化学沉积等为主伴有海相热水沉积混合成因的特征.文中讨论了含稀土磷块岩氧化矿石中稀土元素的迁移富集规律及特征.     

贵州织金新华含稀土磷矿床稀土元素地球化学及生物成矿基本特征

对贵州织金新华含稀土磷矿床进行的稀土元素及微量元素分析结果表明，磷块岩中普遍富集稀土元素，稀土总量∑REE较高，并富集Y元素及La，Nd等轻稀土元素。LREE／HREE比值较高。含稀土磷块岩普遍具Ce负异常，显示其对源区的继承性。指示成磷环境处于氧化程度相对较高状态。稀土元素球粒陨石标准化模式曲线、北美页岩标准化模式曲线、Ce元素异常、LREE／HREE比值、微量元素特征及岩石矿物特征表明，织金新华含稀土磷矿床具以正常海相生物-化学沉积等为主伴有海相热水沉积混合成因的特征。在磷矿成矿过程中沉积物沉积时，活体生物及死亡残骸不同程度地摄取和富集了La，Nd，Ce等稀土元素、Y元素及其他微量元素，沉积在含磷层位，构成大量的含稀土、含生物碎屑白云质磷块岩。     

松嫩平原黑土区西北部阿荣旗地下黑土稀土元素特征及环境指示

东北黑土的形成长期备受学者们的关注,然而人类活动不同程度影响着表层黑土的自然特征。地下黑土能较为真实地反映客观属性,但其研究仍然匮乏,由此本文选择松嫩平原黑土区阿荣旗钻孔内的地下黑土为研究对象,进行稀土元素地球化学测试,采用地质统计学分析地下黑土层ΣREE、HREE、LREE的分布特征,结合Ce异常、Eu异常、(La/Yb)_N、(La/Sm)_N、(Gd/Yb)_N、Al₂O₃/TiO₂图解、Ce_anom讨论了黑土的物源特征与环境记录。结果显示,阿荣旗地下黑土ΣREE含量较高,平均值为141.45×10^-6。球粒陨石标准化曲线表现为向右倾斜,轻稀土富集,δEu微弱负异常,δCe明显负异常。(La/Yb)_N平均值7.58,(La/Sm)_N平均值为1.14,(Gd/Yb)_N平均值为3.54,表明地下黑土重、轻稀土元素分异程度大,轻稀土元素相比重稀土元素分馏...     

囊谦古近纪盆地砂岩地球化学特征及其对物源和沉积环境的指示作用

砂岩地球化学特征对物质来源、古气候和沉积环境具有十分重要的示踪和指示作用。通过分析砂岩的微量元素和稀土元素含量的变化,研究了囊谦盆地沉积环境、古气候及物源特征。结果表明:囊谦古近纪盆地的古环境为气候干旱炎热、氧化环境;微量元素中的深源元素低于地壳粘土岩中的平均值,说明物源为陆源物质,而陆源元素则与地壳粘土岩中的平均值相当,反映沉积速度快;砂岩的REE北美页岩和球粒陨石标准化配分模式表现出轻稀土元素富集、重稀土元素亏损但变化平缓,反映典型的沉积成因特征;Th/Sc、Th/U、La/Th元素比值和La/Sc-Co/Th、Th-Hf-Co、La/Yb-∑REE以及砂岩函数判别图解显示囊谦古近纪盆地碎屑岩物源具有多样性,主要来自于上地壳长英质源区,源岩可能为沉积岩、酸性火山岩和拉斑玄武岩的混合。     

湘江悬浮物的稀土元素地球化学研究

在湘江及其支流采集了44件悬浮物样品进行稀土元素 ICP—MS分析。研究表明,湘江悬浮物中稀土总量(∑REE)、轻稀土(LREE) 和重稀土(HREE)含量分别为63～387 μg/g,58.2～353 μg/g和4.8～34μg/g。尽管湘江悬浮物中稀土分布不均匀,稀土含量相差很大,所有样品的球粒陨石标准化曲线均呈向右倾斜的富LREE的模式,北美页岩标准化模式为LREE稍富集的平坦型。湘江中下游河心与两岸水体悬浮物中稀土发生了明显分异。湘江悬浮颗粒物中REE受多方面因素控制,其源区控制了REE分配模式,而其稀土元素含量与颗粒中粘土矿物及重矿物有关。支流捞刀河悬浮物稀土的分布模式为Eu正异常型,与北美页岩有显著差别,捞刀河的悬浮物物源及成因有待进一步研究。     

北京平原沉积物稀土元素地球化学特征及物源意义

文中总结了北京平原永定河、潮白河流域钻孔沉积物中稀土元素分布特征,两流域沉积物稀土元素总量∑REE、轻重稀土比(LREE/HREE)及轻(La/Sm)N、重(Gd/Yb)N稀土分馏特征差异较为显著。粒度对沉积物稀土分布(总量、轻重稀土比及分馏特征)有一定影响;各流域沉积物均表现为轻稀土相对富集、弱Eu负异常的球粒陨石标准化曲线。细颗粒沉积物稀土分馏特征(La/Yb)N有较好的物源示踪意义。根据沉积物(La/Yb)N值对永定河、潮白河交互沉积区不同深度沉积物进行了物源示踪,不同深度上沉积物来源不同。此外,同一流域上、中、下游沉积物稀土分馏特征不同。常量元素Al2O3/Fe2O3与稀土元素(La/Yb)N划分结果相符,但精度低于稀土元素物源分析。     

柴北缘鱼卡地区中侏罗统石门沟组页岩段稀土元素地球化学特征与地质意义

对柴达木盆地北缘(简称柴北缘)鱼卡地区鱼油页1井(YYY-1)页岩段稀土元素地球化学分析,揭示了其对古环境、古物源和古气候的响应,并探讨了对油页岩成矿的影响。分析结果表明:石门沟组页岩段稀土元素总量(ΣREE)为(139.16~342.59)×10~(-6),平均值为236.66×10~(-6),高于北美页岩(NASC)和后太古宙页岩(PASS)。ΣLREE/ΣHREE和(La/Yb)_N等地球化学参数表明,轻重稀土元素分异明显;分布模式为轻稀土元素富集、重稀土元素相对亏损。地球化学参数以及La/Yb-ΣREE图解表明,研究区物源主要为上地壳沉积岩和火山岩的混合来源。元素Eu具有明显的负异常,指示沉积水体为缺氧的还原环境,为油页岩中有机质的富集提供良好的保存条件。根据高含量的ΣREE值以及δEu异常值,结合前人对该地区的孢粉研究成果,石门沟组页岩段形成于暖湿的气候条件,为油页岩的形成提供良好的物质来源和保存条件。     

桦甸盆地始新统油页岩稀土元素地球化学特征及其地质意义

稀土元素因其稳定的地球化学性质已经成为研究油页岩等细粒湖泊沉积物的物源、古环境、古气候等变化的良好指示剂,具有重要的研究意义。笔者测试并重点分析了桦甸盆地始新统桦甸组油页岩REE地球化学特征。分析结果表明：桦甸含油页岩段稀土元素含量要低于上下段泥岩和炭质页岩样品,油页岩稀土元素总量（∑REE）为（91.51～355.98）×10^-6,平均值为162.56×10^-6,高于全球平均大陆上地壳成分（UCC）,略低于北美页岩;∑LREE/∑HREE及(La/Yb)_N等化学参数表明轻、重稀土元素分异明显,REE分布模式为明显的轻稀土元素富集、重稀土元素亏损呈平坦状、具中等程度的负Eu异常和弱负Ce异常。以Ce异常值反映水介质的氧化还原性,桦甸油页岩形成于缺氧的还原环境;以REE的分异程度来表征油页岩的沉积速率,桦甸组自下而上(La/Yb)_N值呈逐渐由增大→降低→增大的变化趋势,含油页岩段的沉积速率普遍比下段和上段低,与根据恢复压实后的桦甸组地层厚度和孢粉年龄估算得出的沉积速率结果相吻合,说明较低的沉积速率更有利于有机质的聚集和保存;以∑REE的纵向变化作为古气候波动的代用指标,高∑REE值指示暖湿的气候环境,低∑REE值指示冷干的气候环境。桦甸油页岩形成于干旱与温湿交替的气候环境,气候通过影响湖泊水体蒸发量与补给量的平衡而控制着湖平面的变化,从而控制了油页岩的层数和厚度。     

曼达岬海盆渐新世-中新世沉积物的稀土元素组成及其物源指示意义

为了探究东南印度洋曼达岬海盆(Mentelle Basin)内沉积物的源-汇过程,利用国际大洋发现计划(IODP)369航次在该海盆内获取的渐新世-中新世岩心沉积物,进行了稀土元素(REE)组成特征及其控制因素和物源指示意义的研究.结果显示,与球粒陨石、上地壳(UCC)和澳大利亚后太古代页岩(PAAS)这三种标准物质相比,所研究沉积物的稀土元素含量(ΣREE)与轻/重稀土含量比值(ΣLREE/ΣHREE)等总体特征与UCC最为相近,其UCC标准化后的稀土元素配分模式则呈现出轻稀土稍富集的整体平缓特征.样品的ΣREE与稀土分馏指标(La/Yb)_UCC和(Gd/Yb)_UCC明显受控于粒度效应与风化作用,而ΣLREE/ΣHREE、δEu、(La/Sm)_UCC和(Sm/Nd)_UCC则基本不受上述两种作用的影响.UCC标准化后的稀土元素配分模式、基于稀土元素组成的物源判别函数以及Zr-Th-Sc物源判别三角图均表明伊尔冈克拉通是所研究沉积物最可能的物源区,并且该物源区的主要源岩在13 Ma时由中基性岩向酸性岩...     

斯里兰卡普塔拉姆地区ZK593号钻孔沉积物的地球化学特征及意义

根据岩性、主微量元素特征和元素比值分析,斯里兰卡普塔拉姆地区ZK593钻孔的沉积物可分为6段。它们分别沉积于温暖潮湿、水动力较强的浅海-滨海相环境,经历了3次明显的海水进退。各层北美页岩标准化曲线平缓,轻重稀土元素没有明显的分异,Ce轻度亏损,球粒陨石标准化曲线斜率为负,轻稀土元素相对富集,各层Eu亏损明显,Ce轻度亏损,表明沉积物属于受陆源影响的陆棚沉积物。Ce负异常与碳酸盐沉积及气候环境有关。元素相关系数分析表明,Ca和Sr与生物作用关系明显;ΣREE与Al₂O₃和SiO₂等微量元素与陆源碎屑关系密切。δ¹⁸ O 的负向偏移与沉积后地下水的作用有关。     

Geochemistry and origin of rare earth elements (REEs) in the Shengli River oil shale, northern Tibet, China

The Shengli River-Changshe Mountain oil shale zone, located in the North Qiangtang depression, northern Tibet plateau, represents a potentially large marine oil shale resource in China. Twenty-eight samples including oil shale, micritic limestone and marl were collected from the Shengli River area to determine the contents and distribution patterns of rare earth elements (REEs) in marine oil shale. Oil shale samples from the Shengli River area have high ash yield (61.86–67.48%) and TOC content (8.02–13.67%) with low total sulfur (S_t,d) content (0.76–1.39%) and intermediate shale oil content (3.60–16.30%). The total rare earth element (ΣREE) content in oil shale samples is notably depleted (46.79–67.90 μg/g), approximately one third of the mean value of the North American Shale Composite (NASC), and lower than that of world-wide black shales and Chinese coals, but higher than that of world-wide coals and micritic limestone samples (29.21 μg/g) from the Shengli River area. The oil shale samples from the Shengli River area exhibit shale-like Chondrite or NASC-normalized REE patterns similar to those of micritic limestone and marl samples from this area, indicating that REEs of these different lithological samples may have been derived from a similar terrigenous source.REE contents of oil shale samples are highly positive correlated with ash yield and show a positive correlation with Fe and a weakly positive correlation with organic sulfur, and the vertical variations of REEs mainly follow those of Si, Al, K and Ti. All these facts indicate that the REE contents in oil shale seams are mainly controlled by clay minerals and, to a lesser extent, by pyrite, as well as partly associated with oil shale organic constituents. Rare earth elements in the Shengli River oil shale have originated from two sources: a felsic volcanic rock source and a clastic or/and limestone source.     

准噶尔盆地吉木萨尔地区二叠系芦草沟组油页岩地球化学特征与成矿条件

【研究目的】本文旨在通过对比准噶尔盆地吉木萨尔地区二叠系芦草沟组高品位和低品位油页岩的品质和成因差异,揭示高品位油页岩的特殊成矿条件。【研究方法】对吉木萨尔地区两个剖面采集的露头样品,进行TOC、热解、含油率、微量、稀土元素测试,从而开展高品位和低品位油页岩有机地球化学特征,微量稀土元素特征及成矿条件差异分析。【研究结果】研究区高品位油页岩有机质类型为I型;低品位油页岩有机质类型为I-II1型。高品位和低品位油页岩中B、Ba、Cr、Nb、Sr、V、Zr等微量元素含量差异明显,高品位油页岩中各稀土元素平均含量和各样品稀土元素分布区间都小于低品位油页岩,且外源元素富集程度也相对更低,显示了更少的陆源碎屑输入。微量元素比值显示,研究区油页岩形成于温暖湿润气候,淡水—半咸水,还原环境。高品位油页岩与低品位油页岩相比,形成时水体盐度值更大,有机质生产力更高。【结论】温暖湿润气候背景下,相对较少的陆源碎屑供给,减少了对有机质的稀释和氧化破坏,同时较高的水体盐度值更利于水体分层,从而形成一个长时间的还原环境,再加上更高的有机质生产力,从而形成了高品位油页岩。     

抚顺西舍场油页岩的淋滤行为及其对周围水体的影响

为研究抚顺市区南部地表堆积的油页岩中微量元素的淋滤作用对水体的影响,本文分别进行了抚顺西露天矿采场和西舍场油页岩pH为4.0、6.5和8.0的动态淋滤实验,以ICP-MS测试了淋滤液及水体中的微量元素。结果表明,高、低品位油页岩中Cu、Zn、Pb、Ni、Rb、Bi、Ba、Ti、Co、Cr、Cu和Mn等淋出率较高;水体中Pb、Cd、Co、Cr、Ni、Zn、Mn等元素超标,表明抚顺西舍场油页岩的堆积已对周围地表水体和地下水体造成了污染。     

Rare Earth and High Field‐Strength Elements in the Multani Mitti Clay: A Study Using INAA

Instrumental neutron activation analysis was used to determine nine rare earth elements (REE), Sc and five high field‐strength elements (HFSE) in the Multani Mitti (MM) clay. Chondrite‐normalised rare earth element patterns for the MM clay compared with those for the Post‐Archaean Australian Shale (PAAS), Upper Continental Crust (UCC) and North American Shale Composite (NASC) showed enrichment of light REEs and depletion of heavy REEs with a slight negative Eu anomaly. The Multani Mitti clay showed close resemblance to PAAS and NASC in its average REE and HFSE contents. Positive correlations between La/Ce, La/Sm, La/Yb, Zr/Hf, Th/U and Th/Ta ratios predict enrichment of LREEs, Zr and Th and depletion of HREEs. A parent source of felsic origin for the MM clay is also endorsed through the high La/Th and low Th/Sc ratios observed.     

煤系高岭岩的地球化学判别标志

本文主要研究了煤系高岭岩的微量、稀土、氧同位素地球化学特征。根据高岭岩产出层序、岩石学、矿物学、地球化学特征的研究，将煤系高岭岩分为两类：（１）铝土质高岭岩，微量元素含量、稀土总量，氧同位素值高，稀土配分模式与典型北美页岩相似，Ｅｕ负异常，反映其源岩为风化壳化学风化作用产物。（２）夹矸高岭岩，微量元素含量，稀土总量，氧同位素值低，稀土配分模式部分与典型北美页岩相似，反映其源岩与铝土质高岭岩类似；部     

巢湖的稀土元素地球化学特征

采用液-液萃取法和ICP-MS测试技术对巢湖的溶解态稀土元素进行了分析。结果表明,巢湖的溶解态稀土的含量与世界淡水相当,丰水期的样品含量高于其他季节。pH值和悬浮物、胶体是控制巢湖水体中溶解态稀土含量的主要因素。巢湖的溶解态稀土的分布模式以平坦型为主,少数呈现重稀土富集。丰水期和枯水期的溶解态稀土的(La/Yb)N值从西半湖区到东半湖区呈现有规律性的逐渐增大,并且丰水期的(La/Yb)N值低于枯水期。在富营养化湖泊中,胶体和水生生物可能是造成这一现象的主要原因。     

The “North American shale composite”: Its compilation,major and trace element characteristics

The compilation and major element composition of the “North American shale composite” (NASC) are reported for the first time, along with redeterminations for the REE and selected other elements by modern, high precision analytical methods. The NASC is not strictly of North American origin; 5 of the constituent samples are from Africa and Antarctica, and 15 are from unspecified locations. The major element composition of the NASC compares quite closely with other average shale compositions. New analyses of the NASC document that significant portions of the REE and some other trace elements are contained in minor phases (zircon and possibly other minerals) and that their uneven distribution in the NASC powder appears to have resulted in heterogeneity among analyzed aliquants. The results of this study show that the REE distributions of detrital sediments can be dependent to some extent on their minor mineral assemblages and the sedimentological factors that control these assemblages. Consequently, caution should be exercised in the interpretation of the REE distributions of sediment samples as they may be variable and biased relative to average REE distribution of the crustal rocks supplying detritus. These effects appear to be largely averaged out in sediment composites, with the result that their REE distributions are more likely to be representative of their provenances.     

Geochemistry of trace and rare earth elements during weathering of black shale profiles in Northeast Chongqing,Southwestern China: Their mobilization,redistribution, and fractionation

In this study, the mobilization, redistribution, and fractionation of trace and rare earth elements (REE) during chemical weathering in mid-ridge (A), near mountaintop (B), and valley (C) profiles (weak, weak to moderate, and moderate to intense chemical weathering stage, respectively), are characterized. Among the trace elements, U and V were depleted in the regolith in all three profiles, Sr, Nb, Ta, Zr, and Hf displayed slight gains or losses, and Th, Rb, Cs, and Sc remained immobile. Mn, Ba, Zn, Cu, and Cr were enriched at the regolith in profiles A and B, but depleted in profile C. Mn, Pb, and Co were also depleted in the saprock and fractured shale zones in profiles A and B and enriched in profile C. REEs were enriched in the regolith and depleted at the saprock zone in profiles A and B and depleted along profile C. Mobility of trace and REEs increased with increasing weathering intensity. Normalized REE patterns based on the parent shale revealed light REE (LREE) enrichment, middle REE (MREE), and heavy REE (HREE) depletion patterns. LREEs were less mobile compared with MREEs and HREEs, and this differentiation increased with increasing weathering degree. Positive Ce anomalies were higher in profile C than in profiles A and B. The Ce fractionated from other REE showed that Ce changed from trivalent to tetravalent (as CeO₂) under oxidizing conditions. Minimal REE fractionation was observed in the saprock zone in profiles A and B. In contrast, more intense weathering in profile C resulted in preferential retention of LREE (especially Ce), leading to considerable LREE/MREE and LREE/HREE fractionation. (La/Yb)_N and (La/Sm)_N ratios displayed maximum values in the saprock zone within low pH values. Findings demonstrate that acidic solutions can mobilize REEs and result in leaching of REEs out of the highly acidic portions of the saprock material and transport downward into fractured shale. The overall behavior of elements in the three profiles suggests that solution pH, as well as the presence of primary and secondary minerals, play important roles in the mobilization and redistribution of trace elements and REEs during black shale chemical weathering.