鄂尔多斯盆地中生界低幅度构造岩性圈闭油气储层预测技术

鄂尔多斯盆地天环向斜中生界油气储层为低幅度构造背景下的砂岩岩性圈闭储层,与围岩波阻抗差小,常规的地震储层预测方法精度低。针对储层的地质地球物理特征,提出了地震地层分析与物性反演的储层预测技术方案,提高了储层预测精度。     

基于模糊神经网络(FNN)的赤潮预警预测研究

为研究各种理化因子与赤潮藻类浓度间的非线性对应规律和有效预测赤潮藻类浓度,构建了基于BP 算法的一个四层模糊神经网络模型。将模糊神经网络(FNN)技术引入赤潮预测研究,并与普通 BP 网络、RBF 网络的结果作比较,结果表明,该模型能够较好地反演出各种理化因子与夜光藻密度的非线性对应变化规律,有更好的预测功能。     

北戴河近岸海域表层沉积物重金属分布特征及污染评价

分析了北戴河近岸海域表层沉积物重金属含量和空间分布特征,利用修正综合指数法和潜在生态风险指数法对其污染程度进行了评价。结果表明,该区表层沉积物重金属平均含量较低,高值区主要分布在西南角和东北角河口,低值区主要分布在中部;区内重金属污染程度总体上处于较低至中等等级,污染相对明显的为人造河口、石河口和秦皇岛城区近岸海域。相对而言,Hg是主要的致污元素。     

一种统计技术结合动力释用的沿海海雾预报方法

提出了一种利用历史相似个例查询技术,结合WRF模式输出释用的Gultepe沿海大雾业务预报方法。该方法可以较好的计算近地面大气中的液态水含量(LWC)和云滴粒子数密度(Nd)参数。利用该方法对2011—2013年的3—6月的历史沿海海雾个例进行试报,结果表明,恰当的结合统计方法和动力模式可以一定程度上克服目前数值模式不成熟的缺陷,从而提高WRF模式在大雾业务预报方面的释用水平。     

东昆仑夏日哈木镁铁质-超镁铁质岩体岩石成因与拉张型岛弧背景

赋存超大型镍矿床的夏日哈木Ⅰ号岩体位于东昆仑造山带西段之东昆中早古生代岛弧带。锆石U-Pb年龄为439Ma,由分属橄榄岩相、辉石岩相、辉长-苏长岩相的多种岩石类型组成。堆晶结构与堆晶层理发育,属岩床状层状岩体。不平衡结晶作用在岩浆演化过程中居于主导地位。矿物结晶顺序为尖晶石/橄榄石→斜方辉石→单斜辉石→单斜辉石+斜长石→褐色普通角闪石。各种岩石均富集轻稀土元素和大离子亲石元素,亏损Nb、Ta、Ti、P,显示了岛弧环境岩浆岩的地球化学特征。Nd、Sr同位素组成均属富集型地幔范畴和EMⅡ型趋势。矿区内的Ⅲ号与Ⅳ号岩体属蛇绿岩套,证明在昆中岛弧带内部存在岩石圈破裂带。区域构造格局与演化历史以及区域地球物理场的研究表明,东昆中岛弧带属拉张型岛弧带。据此,可以认定拉张型岛弧环境是全球范围内第五种有利于形成镍矿床的构造环境,中古生代是我国第三个镍矿主成矿期。     

催化臭氧化降解有机废水及影响因素

主要论述了自制的V-O型催化荆催化臭氧化降解有机废水的研究。试验表明，以TiO2，SiO2，ZrO2作栽体，在氮气或氧气中焙烧，而制得的6种催化荆中，V-O／SiO2／N2显示了较好的催化性能和活性；通过催化荆吸附试验和在反应体系中加入一定量的自由基猝灭荆，初步探讨了其催化机理，即催化荆和臭氧反应，生成了氧化性极强的羟基自由基；催化臭氧化时间、催化荆用量、进气臭氧浓度、体系pH值等因素均对降解产生一定的影响。     

测绘地理信息类专业双语课程评价体系构建

中国高校"双一流"建设要求培养兼备专业能力与国际竞争力人才,而双语教学则是一条有效途径.以CIPP(context,input,process,product)课程评价模型为理论依据,根据测绘地理信息类专业双语教学的特点,从背景评估、输入评估、过程评估、成果评估4个方面构建了测绘地理信息类专业双语课程评价指标体系,为提...     

海底管道水下气体扩散FLUENT仿真分析

海底管道气体扩散到自由表面的半径及泉涌高度是进行水下气体泄漏风险分析的关键因素。利用FLUENT软件中的VOF模型和DPM模型耦合方式,对海底管道气体竖向扩散进行了仿真。模拟了水气两相交界面的行为,研究了气泡粒子扩散过程,分析了气泡粒子的扩散半径及轴向位移,讨论了不同泄漏速率对水下气体上升时间及水气两相交界面中泉涌高度的影响。通过模型中的水气两相交界面中泉涌高度和上升时间与实验结果的比较,验证了模型在一定条件下的正确性。     

中国南海区1992-2012年的中尺度涡旋演化过程表达与统计分析

Automated identification and tracking of mesoscale ocean eddies has recently become one research hotspot in physical oceanography. Several methods have been developed and applied to survey the general kinetic and geometric characteristics of the ocean eddies in the South China Sea（SCS）. However, very few studies attempt to examine eddies＇ internal evolution processes. In this study, we reported a hybrid method to trace eddies＇ propagation in the SCS based on their internal structures, which are characterized by eddy centers, footprint borders, and composite borders. Eddy identification and tracking results were represented by a GIS-based spatiotemporal model. Information on instant states, dynamic evolution processes, and events of disappearance, reappearance, split, and mergence is stored in a GIS database. Results were validated by comparing against the ten Dongsha Cyclonic Eddies（DCEs） and the three long-lived anticyclonic eddies（ACEs） in the northern SCS, which were reported in previous literature. Our study confirmed the development of these eddies. Furthermore, we found more DCE-like and ACE-like eddies in these areas from 2005 to 2012 in our database. Spatial distribution analysis of disappearing, reappearing, splitting, and merging activities shows that eddies in the SCS tend to cluster to the northwest of Luzon Island, southwest of Luzon Strait, and around the marginal sea of Vietnam. Kuroshio intrusions and the complex sea floor topography in these areas are the possible factors that lead to these spatial clusters.     

Research Progress of Geophysical Exploration in Karatungk Mine in Northern Xinjiang, China

Karatungk Mine in northern Xinjiang, China, which is a large-scale magmatic Cu-Ni sulfide mine in the Central Asian orogenic belt, has a long history of mining. The mine is located at the merging belt between Altay orogenic belt and Junggar Basin, and has strong tectonic activities. In recent years, mining source detection has become an important target for mineral exploration due to the difficulties in ore body exploitation. In this paper,we systematically summarize the achievements of the geophysical explorations in Karatungk Mine from various aspects, including tectonic backgrounds of the mine, dynamic mechanisms, geophysical characteristics and scientific challenges in the future. Because of the restrictions of observation density and analysis methods, the fine geometrical structure of the mine cannot be completely characterized yet. Therefore,in order to obtain the high-resolution structure and detailed spatial distribution of orebodies, researchers should focus on combining multiple geophysical methods, developing high-resolution imaging methods, and improving petro physical experiments in the future.