河北丰宁招兵沟铁磷矿浮选选磷影响因素分析

通过对河北丰宁招兵沟铁磷矿浮选选磷工艺7年的生产实践总结,对原矿石性质,浮选粒度、浓度,浮选泡沫层动态,浮选机充气量,浮选温度,浮选水质等影响因素分别进行探讨和研究,找出影响浮选工艺的因素,为选矿厂生产提供依据。     

南海北部深水区沉积物稀土元素特征及其物源指示意义

对南海北部白云深水区沉积物稀土元素的研究表明,渐新世至中新世的物源发生较大变化。渐新世时期,白云深水区不同区域稀土元素的分布特征差异明显,表明沉积物物源不同。深水区北部沉积物主要来自古珠江物源区,深水区东、西部沉积物中含有较多中基性火山物质,南部则主要包含基性火山物质,说明当时南海北部地区构造活动较强,存在较多火山活动,火山活动由北向南基性成分增多。渐新世末的白云运动使南海北部深水区产生强烈持续沉降,造成陆架坡折带北移,白云深水区从渐新世浅海陆架环境演化为中新世陆坡深水环境,中新世期间沉积物主要来自深水区北部的珠江三角洲物源,深水区东部存在东沙隆起源区,而深水区南部沉积物在中新世仍受到基性火山活动的影响。     

峨边老金岩铅锌矿区成矿地质特征及成因

老金岩铅锌矿为四川峨边一马边成矿带上规模较大的矿区之一。通过对该矿区的区域地质背景、成矿地质条件、主要控矿因素进行总结,认为灯影组上部的深灰色不纯白云岩是该区带主要容矿岩石,近南北向的峨边一雷坡断裂和北东向的汉源一峨眉凹陷控制着区内容矿岩石的出露及矿床分布。通过矿床成因的初步探讨,总结了找矿标志,并对找矿前景进行了预测。     

南海北部沉积物特征及其对珠江演变的响应

采用沉积地球化学、沉积物矿物成分分析等手段研究发现,自渐新世以来,南海北部沉积物成分具有阶段性改变的特征.在早渐新世,沉积物反映出其母岩以花岗岩和区域变质岩为主;到晚渐新世,母岩中区域变质岩类型消失,而以花岗岩、沉积岩和接触变质岩为特征;进入中新世,沉积物主要反映出碳酸盐岩等沉积岩为主的源区特点.这种沉积物成分演变特征与南海北部盆地基底及珠江流域不同区域物质组成特征极为一致,反映出珠江流域演化与南海北部沉积充填之间的对应关系.因此,通过这种研究方法,可以更好地理解32Ma以来南海北部沉积物成分发生改变的原因.同时,可以通过对比南海北部古珠江来源沉积物各时期的成分特点,建立珠江流域的侵蚀-搬运-沉积过程,探讨珠江流域演化历史.     

Rock skeleton models and seismic porosity inversion

By substituting rock skeleton modulus expressions into Gassmann approximate fluid equation, we obtain a seismic porosity inversion equation. However, conventional rock skeleton models and their expressions are quite different from each other, resuling in different seismic porosity inversion equations, potentially leading to difficulties in correctly applying them and evaluating their results. In response to this, a uniform relation with two adjusting parameters suitable for all rock skeleton models is established from an analysis and comparison of various conventional rock skeleton models and their expressions including the Eshelby-Walsh, Pride, Geertsma, Nur, Keys-Xu, and Krief models. By giving the two adjusting parameters specific values, different rock skeleton models with specific physical characteristics can be generated. This allows us to select the most appropriate rock skeleton model based on geological and geophysical conditions, and to develop more wise seismic porosity inversion. As an example of using this method for hydrocarbon prediction and fluid identification, we apply this improved porosity inversion, associated with rock physical data and well log data, to the ZJ basin. Research shows that the existence of an abundant hydrocarbon reservoir is dependent on a moderate porosity range, which means we can use the results of seismic porosity inversion to identify oil reservoirs and dry or water-saturated reservoirs. The seismic inversion results are closely correspond to well log porosity curves in the ZJ area, indicating that the uniform relations and inversion methods proposed in this paper are reliable and effective.     

Joint observation results of Na layer and ionosphere in Wuhan during the Total Solar Eclipse

During the total solar eclipse on July 22, 2009 in Wuhan, the joint observation test of Na layer and ionosphere was conducted by using the daytime observation atmospheric lidar and the GPS ionosphere detector. The results show that the full width at half maximum (FWHM) of Na layer density slightly narrowed during the total solar eclipse and broadened after the eclipse, while the height of Na peak slightly decreased in the eclipse and increased after the eclipse. These implying that Na layer changes reflect the rapid process of sunrise and sunset. The ionosphere total electron content (TEC) and the sky background light noise also presented an obvious fluctuation characteristic with the changes of solar irradiation during the process of total solar eclipse. The difference lies in that the changes of FWHM of Na layer atoms are much slower than that of ionosphere, the reason for this might be that the Na layer, after being disturbed by the total solar eclipse, will generate a series of complicated photochemical reactions and momentum transport processes, and then recombine the Na atoms. The Na atoms to be detected by the lidar need a lag process, which rightly conforms to the theoretical simulated results.     

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