应用碳、氦、氩同位素探讨济阳拗陷二氧化碳气成因

应用碳、氦、氩同位素和气体组分指标 ,以及流体包裹体测定等手段 ,结合济阳拗陷基本地质条件 ,提出二氧化碳气藏的二氧化碳气主要以幔源成因为主。     

上海地区深部构造特征和地震活动趋势探讨

本文介绍由重磁资料计算上海地区居里面、莫霍面、均衡重力异常及地幔流应力场的方法和成果,并在对成果初步分析的基础上,探讨了深部地质构造特征及其与地震活动趋势的关系,其中着重讨论了居里面及其与地震活动的关系。文章最后提出了对上海地区地震活动趋势的几点认识。     

安徽庐枞盆地中巴家滩岩体的岩石地球化学特征及成因

巴家滩岩体位于长江中下游庐枞中生代火山岩盆地的中心地带,出露面积约4km2.岩性主要为辉石二长岩和含英辉石二长岩,发育黄铁矿化和黄铜矿化.野外及室内证据表明该岩体可分为两期,第一期表现为闪长质岩石包体;第二期主要为旱阶段的辉石二长岩和晚阶段的含石英辉石二长岩.巴家滩岩体随着由早到晚的演化,其SiO2含量、总碱含量(Na2O K2O)和岩石的氧化度不断增高.稀土配分整体呈右倾趋势,轻稀土富集,重稀土分馏不明显.岩石学、稀土和微量元素地球化学特征表明巴家滩岩体成岩物质来源于富含金云母的富集地幔Ⅱ.巴家滩岩体属于橄榄玄粗岩系,形成于伸展构造环境.巴家滩岩体具有高Al2O2、Sr、St/Y、La/Yb,低Y、Yb、Sr正异常,Eu弱负异常,与沙溪岩体的特征相似,早期包体的Cu含量高达0.8402,推断在其深部可能有可能有类似沙溪岩体的矿化岩浆存在.     

地幔流体的前缘研究

地幔流体是与地幔环境处于平衡的气体和挥发分。其主要化学组分为碳、氢、氧、氮、硫（ＣＨＯＮＳ）。它以富于地球内部原始组分为特征，但也包含部分再循环组分。地幔挥发分在弱还原条件下主要为ＣＯ２－Ｈ２Ｏ，强还原环境则以ＣＨ４－Ｈ２Ｏ－Ｈ２为主。地幔流体地球化学的重要性质为：（１）易溶于硅酸盐熔体；（２）净化作用；（３）再沉淀作用。近年来，有关地幔流体中稀有气体和挥发分的起源、分布及同位素组成等前缘领域的研究已取得重要进展。当前拟优先探索的问题包括气体裂化与金刚石成因，非生物成因地幔烃，地幔流体与成矿作用，以及地幔挥发分注入与地壳重熔等。     

地幔流体研究进展

介绍了在地幔流体的成分、源区、形成机制、运移方式和分异模式以及地幔流体与地幔交代作用、岩浆作用和成矿作用的关系等方面研究的一些新进展 ,总结了地幔流体的研究途径和方法的一些新突破 ,并指出了今后的重点研究方向。     

内蒙古喀喇沁早白垩世橄辉云煌岩岩筒

探寻地幔物质上涌的通道口，是大陆岩石圈研究所感兴趣的，它将为人们提供更多的岩石圈深部信息。本文报道的是在内蒙古喀喇沁黑龙潭火山颈中发现的橄辉云煌岩，其K-Ar同位素年龄为124Ma。火山活动明显受到中生代构造活动控制。火山岩的元素地球化学特征反映岩浆来自富集地幔，在源区存在陆壳的混染作用。     

MT约束的青藏高原东南缘上地幔热结构研究——以兰坪—贵阳剖面为例

青藏高原东南缘是青藏高原软弱物质运移的关键位置,研究其深部结构有助于理解青藏高原的扩张机制.本文利用穿过青藏高原东南缘的一条起始于兰坪—思茅块体,穿过川滇菱形块体,终止于华南块体的长约750 km的大地电磁测深（MT）剖面的电阻率结构,基于上地幔矿物和熔融体温度与电导率的关系,获得了研究区上地幔温度结构与熔融百分比分布.结果表明,采用随深度变化的含水熔融上地幔矿物组分模型才能合理地获得整个上地幔温度;上地幔全岩含水量约4.69（40 km深度）~0.13 wt%（150 km深度）,矿物熔融百分比约0~1.4%之间,并在70 km深度附近出现了较明显的局部熔融带;上地幔温度位于400~1300℃之间,随深度加深而逐渐增加;70 km以浅的温度表现出相对强烈的横向变化,且川滇和兰坪—思茅块体的上地幔温度和矿物熔融百分比的深度平均值明显高于华南块体.

     

甘肃西秦岭新生代钾霞橄黄长岩中的球状分凝体及地幔流体反演

地幔流体在地质过程中的作用日益受到人们的重视,成为地球科学研究的一个前缘课题。提供了甘肃西秦岭新生代钾霞橄黄长岩中各种形态分凝体详细的岩相学、矿物学和矿物化学的资料,对分凝体的性质、深部地幔流体的成分及成因机制进行了讨论。研究表明,钾霞橄黄长岩中分凝体是软流圈地幔流体活动的记录,其成因机制与岩浆作用对软流圈的开放和软流圈上涌的条件下,原生钾霞橄黄长岩浆的分异作用（特别是液态不混熔作用）,以及岩浆的抽提作用、动态熔融作用等综合作用有关。     

Bulk-rock Major and Trace Element Compositions of Abyssal Peridotites: Implications for Mantle Melting, Melt Extraction and Post-melting Processes Beneath Mid-Ocean Ridges

This paper presents the first comprehensive major and traceelement data for 130 abyssal peridotite samples from the Pacificand Indian ocean ridge–transform systems. The data revealimportant features about the petrogenesis of these rocks, mantlemelting and melt extraction processes beneath ocean ridges,and elemental behaviours. Although abyssal peridotites are serpentinized,and have also experienced seafloor weathering, magmatic signaturesremain well preserved in the bulk-rock compositions. The betterinverse correlation of MgO with progressively heavier rare earthelements (REE) reflects varying amounts of melt depletion. Thismelt depletion may result from recent sub-ridge mantle melting,but could also be inherited from previous melt extraction eventsfrom the fertile mantle source. Light REE (LREE) in bulk-rocksamples are more enriched, not more depleted, than in the constituentclinopyroxenes (cpx) of the same sample suites. If the cpx LREErecord sub-ridge mantle melting processes, then the bulk-rockLREE must reflect post-melting refertilization. The significantcorrelations of LREE (e.g. La, Ce, Pr, Nd) with immobile highfield strength elements (HFSE, e.g. Nb and Zr) suggest thatenrichments of both LREE and HFSE resulted from a common magmaticprocess. The refertilization takes place in the ‘cold’thermal boundary layer (TBL) beneath ridges through which theascending melts migrate and interact with the advanced residues.The refertilization apparently did not affect the cpx relicsanalyzed for trace elements. This observation suggests grain-boundaryporous melt migration in the TBL. The ascending melts may notbe thermally ‘reactive’, and thus may have affectedonly cpx rims, which, together with precipitated olivine, entrappedmelt, and the rest of the rock, were subsequently serpentinized.Very large variations in bulk-rock Zr/Hf and Nb/Ta ratios areobserved, which are unexpected. The correlation between thetwo ratios is consistent with observations on basalts that D_Zr/D_Hf< 1 and D_Nb/D_Ta < 1. Given the identical charges (5⁺ forNb and Ta; 4⁺ for Zr and Hf) and essentially the same ionicradii (R_Nb/R_Ta = 1·000 and R_Zr/R_Hf = 1·006–1·026),yet a factor of 2 mass differences (M_Zr/M_Hf = 0·511 andM_Nb/M_Ta = 0·513), it is hypothesized that mass-dependentD values, or diffusion or mass-transfer rates may be importantin causing elemental fractionations during porous melt migrationin the TBL. It is also possible that some ‘exotic’phases with highly fractionated Zr/Hf and Nb/Ta ratios may existin these rocks, thus having ‘nugget’ effects onthe bulk-rock analyses. All these hypotheses need testing byconstraining the storage and distribution of all the incompatibletrace elements in mantle peridotite. As serpentine containsup to 13 wt % H₂O, and is stable up to 7 GPa before it is transformedto dense hydrous magnesium silicate phases that are stable atpressures of 5–50 GPa, it is possible that the serpentinizedperidotites may survive, at least partly, subduction-zone dehydration,and transport large amounts of H₂O (also Ba, Rb, Cs, K, U, Sr,Pb, etc. with elevated U/Pb ratios) into the deep mantle. Thelatter may contribute to the HIMU component in the source regionsof some oceanic basalts. KEY WORDS: abyssal peridotites; serpentinization; seafloor weathering; bulk-rock major and trace element compositions; mantle melting; melt extraction; melt–residue interaction; porous flows; Nb/Ta and Zr/Hf fractionations; HIMU mantle sources