南海琼东南盆地深水区储层类型及研究意义

通过对琼东南盆地钻井及典型地震相分析,认为琼东南盆地深水区发育两种类型的储层:第一类为形成于浅水环境的储层,包括扇三角洲砂体、滨浅海相滩坝砂体和台地碳酸盐岩;第二类为形成于深水环境的储层,包括盆底扇和峡谷水道等低位砂体。其中,深水区广泛分布的海底扇、峡谷水道砂体和台地碳酸盐岩具有良好的深水油气勘探潜力。     

塔河油田6~7区孔洞型碳酸盐岩储层建模

塔河油田6~7区奥陶系碳酸盐岩储层受岩溶作用影响,非均质性极强。因此,准确地刻画储集体的形态及三维空间展布对油气田的勘探开发至关重要。在对研究区奥陶系缝洞型碳酸盐岩储层纵向发育规律的认识的基础上,首次提出采用"多点统计学"进行储集相建模的基本思路。根据地震属性与孔洞型储层之间的对应关系优选"特征属性",建立基于"特征属性"的"训练图像";以钻井、地震识别以及测井解释成果作为硬数据,地震波阻抗的溶洞发育概率体作为软数据,进行"储集相"模拟。结果表明:该方法不仅实现了对孔洞型储集体形态的模拟,而且再现了孔洞型储集体的复杂结构及空间分布,同时模拟结果与该类型储集体的纵向发育规律相符。     

花岗岩型热液铀矿床C、O同位素研究---以甘肃省龙首山芨岭矿区为例

龙首山地区是西北重要的花岗岩型热液铀矿产区之一,区内控矿条件复杂。研究选取甘肃省龙首山芨岭矿区内的矿床和部分矿点的热液碳酸盐样品并测定其C、O同位素组成：δ13C VPDB的值在-1.50‰～-6.33‰之间,δ18OSMOW值为-2.577～5.051‰之间。进一步研究结果表明,成矿流体中矿化剂ΣCO2主要来源于与区域深大断裂有关的幔源脱气作用,同时伴有海相碳酸盐来源;成矿同时期伴随的强烈流体脱气(CO2)作用对矿质沉淀至关重要。成矿热液的水源主要为岩浆热液与大气降水混合特征,但以大气降水形成为主。     

Sea-level Eustatic Cycles and Potash Formation Event:A Case Study of Triassic Sichuan Basin

正Identification of the favorable salt-and potash-forming layer,we still mainly rely on logging interpretation and coring verification.However,we both know that the continuously carbonate platform is cyclical growing.It has recorded valuable information about the phase transition of carbonate rocks,which were synchronized with the relative sea-level cycles.This paper presents a fast and     

A Fresh Look at the Geobiology & Sedimentary Environments of the Hypersaline Great Salt Lake,USA

正1 Introduction The Great Salt Lake(GSL)is the defining hydrological feature of the Great Basin,North America’s largest desert--and it is the largest waterbody in the western USA.Despite the early(Eardley,1938)recognition of"bioherms,"algal layers,and mats covering hundreds of square km of lake area,these features have not been the     

Study on the Isothermal Evaporation Process at 5℃ with the Brine of Laguocuo Salt Lake

正1 Introduction Tibet has nurmerous salt lakes.Laguocuo is one of the salt lakes,which is located to the sorthern of Ali Plateau,31°59′02″N-32°04′08″N,84°02′03″E-84°12′03″E.Its lake water is rich in potassium,magnesium,lithium,boron,rubidium,cesium and other resources.The study of     

Petrological constraints on the formation conditions and retrograde P–T path of the Kotsu eclogite unit, central Shikoku

A largely undocumented region of eclogite associated with a thick blueschist unit occurs in the Kotsu area of the Sanbagawa belt. The composition of coexisting garnet and omphacite suggests that the Kotsu eclogite formed at peak temperatures of around 600 °C synchronous with a penetrative deformation (D1). There are local significant differences in oxygen fugacity of the eclogite reflected in mineral chemistries. The peak pressure is constrained to lie between 14 and 25 kbar by microstructural evidence for the stability of paragonite throughout the history recorded by the eclogite, and the composition of omphacite in associated eclogite facies pelitic schist. Application of garnet‐phengite‐omphacite geobarometry gives metamorphic pressures around 20 kbar. Retrograde metamorphism associated with penetrative deformation (D2) is in the greenschist facies. The composition of syn‐D2 amphibole in hematite‐bearing basic schist and the nature of the calcium carbonate phase suggest that the retrograde P–T path was not associated with a significant increase or decrease in the ratio of P–T conditions following the peak of metamorphism. This P–T path contrasts with the open clockwise path derived from eclogite of the Besshi area. The development of distinct P–T paths in different parts of the Sanbagawa belt shows the shape of the P–T path is not primarily controlled by tectonic setting, but by internal factors such as geometry of metamorphic units and exhumation rates.     

Deepwater Ventilation and Stratification in the Neogene South China Sea

Combined data of physical property, benthic foraminifera, and stable isotopes from ODP Sites 1148, 1146, and 1143 are used to discuss deep water evolution in the South China Sea (SCS) since the Early Miocene. The results indicate that 3 lithostratigraphic units, respectively corresponding to 21-17 Ma, 15-10 Ma, and 10-5 Ma with positive red parameter (a*) marking the red brown sediment color represent 3 periods of deep water ventilation. The first 2 periods show a closer link to contemporary production of the Antarctic Bottom Water (AABW) and Northern Component Water (NCW), indicating a free connection of deep waters between the SCS and the open ocean before 10 Ma. After 10 Ma, red parameter dropped but stayed higher than the modern value (a*=0), the CaCO3 percentage difference between Site 1148 from a lower deepwater setting and Site 1146 from an upper deepwater setting enlarged significantly, and benthic species which prefer oxygen-rich bottom conditions dramatically decreased. Coupled with a major negative excursion of benthic δ13C at ~10 Ma, these parameters may denote a weakening in the control of the SCS deep water by the open ocean. Probably they mark the birth of a local deep water due to shallow waterways or rise of sill depths during the course of sea basin closing from south to east by the west-moving Philippine Arc after the end of SCS seafloor spreading at 16-15 Ma. However, it took another 5 Ma before the dissolved oxygen approached close to the modern level. Although the oxygen level continued to stabilize, several Pacific Bottom Water (PBW) and Pacific Deep Water (PDW) marker species rapidly increased since ~6 Ma, followed by a dramatic escalation in planktonic fragmentation which indicates high dissolution especially after ~5 Ma. The period of 5-3 Ma saw the strongest stratified deepwater in the then SCS, as indicated by up to 40% CaCO3 difference between Sites 1148 and 1146. Apart from a strengthening PDW as a result of global cooling and ice cap buildup on northern high latitudes, a deepening sea basin due to stronger subduction eastward may also have triggered the influx of more corrosive waters from the deep western Pacific. Since 3 Ma, the evolution of the SCS deep water entered a modern phase, as characterized by relative stable 10% CaCO3 difference between the two sites and increase in infaunal benthic species which prefer a low oxygenated environment. Thesubsequent reduction of PBW and PDW marker species at about 1.2 Ma and 0.9 Ma and another significant negative excursion of benthic δ13C to a Neogene minimum at ~0.9 Ma together convey a clear message that the PBW largely disappeared and the PDW considerably weakened in the Mid-Pleistocene SCS. Therefore, the true modern mode SCS deep water started to form only during the "Mid-Pleistocene climatic transition" probably due to the rise of sill depths under the Bashi Strait.     

地震属性分析在块碳酸盐岩储层研究中的应用

通过对也门1区块地层特征及电测资料的分析,从目的层段精细层位标定入手,确定属性提取的时窗大小,沿层提取1区块西北部盐上、盐下两套碳酸盐岩储集层地震属性.综合应用地震属性技术研究碳酸盐储层的剖面和平面分布特征,预测碳酸盐储层"孔-洞-缝"发育区.