TBP—（X—5）反相色谱分离m—NPF分光光度法测定铀

本文研究了以磷酸三丁酯为固定相，大孔聚乙烯笨（Ｘ－５型）为担体的浸渍树脂、垂直型反相色谱柱，对铀分离富集的基本性能，以及铀（Ⅵ）－间硝基苯基萤光酮（ｍ－ＮＰＦ）一氨三乙酸（ＮＴＡ）－吐温－８０显色体系的反应条件，提出了ＴＢＰ－（Ｘ－５）分离，ｍ－ＮＰＦ－ＮＴＡ－吐温－８０光度法测定铀，经标准样品验证，结果满意。     

钪－4，5－二溴苯基荧光酮－CTMAB－吐温－60多元配合物的分光光度法研究

研究结果表明，在混合表面活性剂ＣＴＭＡＢ－吐温－６０存在下的ｐＨ５．７～６．５的缓冲介质中，Ｓｃ（Ⅲ）与４，５－二溴苯基荧光酮（ＤＢＰＦ）形成高灵敏的多元配合物，其ε＿（５９０）＝２．２６×１０￣５Ｌ·ｍｏｌ￣（－１）·ｃｍ￣（－１），组成比为：Ｓｃ：ＤＢＰＦ：ＣＴＭＡＢ＝１：２：４。采用混合表面活性剂使增溶增敏作用更为显著，并加速了显色反应，增强了配合物的稳定性。而Ｎａ＿２ＳＯ＿４的加入能显著地提高体系的灵敏度。Ｓｃ量在０～０．３６ｕｇ／ｍｌ范围内遵守比尔定律。方法可直接测定合成混合稀土中的Ｓｃ，回收率在９８％～１０５％；结合沉淀分离和ＰＭＢＰ萃取分离，实现了地质试样中痕量Ｓｃ的测定。     

1，5－二（2－羟基－5－磺基苯基）－3－氰基甲■分光光度法测定煤矸石中微量镓

常温下在ｐＨ４的ＨＡｃ－ＮａＡｃ缓冲体系中，Ｇａ与１，５－二（２－羟基－５－磺基苯基）－３－氰基甲　（ＤＳＰＣＦ）形成稳定的蓝色配合物。该配合物在波长６３０ｎｍ处有最大吸收，其表观摩尔吸光系数为３．８×１０￣４Ｌ·ｍｏｌ￣－１·ｃｍ￣－１，配合比为ｎ（Ｇａ）：ｎ（ＤＳＰＣＦ）＝１：２，显色反应在２０ｍｉｎ内完成，稳定时间至少２４ｈ，Ｇａ量在０～１．８ｍｇ／Ｌ时遵守比尔定律。采用ＴＢＰ萃淋树脂分离干扰元素后可实现煤矸石中Ｇａ的测定。     

钼－3，4－二甲氧基苯基荧光酮－吐温－80的显色反应及其应用

在０．１８～０．３２ｍｏｌ／ＬＨＣｌ介质中，Ｍｏ（Ⅵ）与３，４－二甲氧基苯基荧光酮（ＤＭＯＰＦ）和Ｔｗｅｅｎ－８０形成三元胶束配合物，最大吸收峰在５２６ｎｍ处，摩尔吸光系数为１．１６×１０￣５Ｌ·ｍｏｌ￣－１·ｃｍ￣－１，Ｍｏ（Ⅵ）含量在０～０．５３μｇ／ｍｌ范围内符合比耳定律。所建立的方法用于矿样中Ｍｏ的测定，结果较为满意。     

2-[2-(5-甲基苯并噻唑)偶氮]-5-二乙氨基苯甲酸的离解平衡及其与铁的显色反应

研究了新显色剂２－［２－（５－甲基苯并噻唑）偶氮］－５－二乙氨基苯甲酸（５－Ｍｅ－ＢＴＡＥＢ）的离解平衡及与Ｆｅ２＋形成配合物的条件。在十二烷基硫酸钠的存在下,５－Ｍｅ－ＢＴＡＥＢ与Ｆｅ２＋形成稳定的蓝紫色２∶１配合物,其最大吸收波长为６４０ｎｍ,表观摩尔吸光系数为１．０３×１０５Ｌ·ｍｏｌ－１·ｃｍ－１。Ｆｅ２＋的质量浓度在０～４８０μｇ／Ｌ时服从比尔定律。方法用于部级铝合金标样中微量铁的测定,结果与推荐值相符,对ｗ（Ｆｅ）为０．１％～０．５％的样品测定１０次,ＲＳＤ在０．８５％～１．９５％,用于测定矿泉水中ｗ（Ｆｅ）／１０－６铁的测定,ＲＳＤ＜１．５％（ｎ＝７）,加标回收率９８．９％～９９．４％     

钼－氨三乙酸－溴邻苯三酚红－溴化十六烷基三甲基铵体系的显色反应及其应用

在ｐＨ２．５的氯乙酸缓冲介质中，有溴化十六烷基三甲基铵（ＣＴＭＡＢ）存在下，Ｍｏ（Ⅵ）与氨三乙酸（ＮＴＡ）及溴邻苯三酚红（ＢＰＲ）形成胶束混配配合物，该配合物最大吸收波长在６００ｎｍ，摩尔吸光系数为７．２７×１０￣４Ｌ·ｍｏｌ￣（－１）·ｃｍ￣（－１），配合物组成为Ｍｏ（Ⅵ）：ＮＴＡ：ＢＰＲ：ＣＴＭＡＢ＝１：１：２：４。Ｍｏ（Ⅵ）量在０～１．０ｇ／ｍｌ范围内符合比尔定律。由于ＮＴＡ的存在，改善了方法的选择性，可直接分光光度测定矿石及钢中微量Ｍｏ。     

SPC－600系列钻机在使用中的几个技术问题

ＳＰＣ－６００系列钻机在使用中的几个技术问题天津探矿机械总厂尚书泉８０年代初，我厂试制成功了设计钻深为６００ｍ的车装水文水井钻机。第一台钻机装在“罗曼”（ＲＯＭＡＮ）大型卡车上，定型为ＳＰＣ－６００Ｒ。后来生产的钻机装在ＴＡＴＲＡ－８１５大型卡车上，...     

二安替比林基—（3—溴）苯基甲烷与铈（Ⅳ）显色反应的研究

合成了二安替比林基－（３－溴）苯基甲烷。在Ｍｎ和吐温－８０存在下，Ｃｅ与ＤＡｍＢＭ反应生成有色化合物，λｍａｘ为３８０ε为３．０×１０＾５Ｌ．ｍｏｌ＾－１，ｃｍ＾－１。Ｃｅ量在（０－１０）μｇ／２５ｍｌ间符合比尔定律。     

钪－4，5－二溴苯基荧光酮－CTMAB－吐温－60多元配合物的分光光度法研究

研究结果表明，在混合表面活性剂ＣＴＭＡＢ－吐温－６０存在下的ＰＨ５．７－６．５的缓冲介质中，Ｓｃ（Ⅲ）与４，５－二溴苯基荧光酮形成高灵敏的多元配合物，其ε５９０＝２．２６×１０＾５Ｌ．ｍｏｌ＾－１．ｃｍ＾－１，组成比为：Ｓｃ：ＤＢＰＦ：ＣＴＭＡＢ＝１：２：４。采用混合表面活性剂使增溶增敏作用更为显著，并加速了显色反应，增强了配合物的稳定性。而Ｎａ２ＳＯ４的加入能显著地提高体系的灵敏度，Ｓｃ量在０－     

用2－（2－噻唑偶氮）－5－二甲氨基苯甲酸作络合滴定铜的指示剂

用２－（２－噻唑偶氮）－５－二甲氨基苯甲酸作络合滴定铜的指示剂李秀玲，凌永萍，张瑾山东建材学院应化系济南２５００２２铜合金中Ｃｕ的测定常用方法有碘量法、ＥＤＴＡ容量法。ＥＤＴＡ容量法常用的指示剂有ＰＡＮ和二甲酚橙，但ＰＡＮ在使用过程中水溶性差、变色不...     

Définition d'une limite multicritère ; stratigraphie du passage Campanien–Maastrichtien du site géologique de Tercis (Landes,SW France)Definition of a multi-criteria boundary; stratigraphy of the Campanian–Maastrichtian interval of the geological site at Tercis (Landes,SW France)

Lithostratigraphy, physicochemical stratigraphy, biostratigraphy, and geochronology of the 77–70 Ma old series bracketing the Campanian–Maastrichtian boundary have been investigated by 70 experts. For the first time, direct relationships between macro- and microfossils have been established, as well as direct and indirect relationships between chemo-physical and biostratigraphical tools. A combination of criteria for selecting the boundary level, duration estimates, uncertainties on durations and on the location of biohorizons have been considered; new chronostratigraphic units are proposed. The geological site at Tercis is accepted by the Commission on Stratigraphy as the international reference for the stratigraphy of the studied interval. To cite this article: G.S. Odin, C. R. Geoscience 334 (2002) 409–414.     

Late Wuchiapingian (Late Dzhulfian,early Late Permian) limestone olistolites within the Tertiary flysch of Glypia Unit (Mount Parnon,central–eastern Peloponnesus,Greece)

Some olistolites reworked in a Tertiary flysch of Mount Parnon (Peloponnesus, Greece) exhibit a Late Permian assemblage, dominated by Paradunbarula (Shindella) shindensis, Hemigordiopsis cf. luquensis and Colaniella aff. minima. This association corresponds to the Late Wuchiapingian (=Late Dzhulfian), a substage whose algae and foraminifera are generally little known. Contemporaneous limestones crop out in the middle part of the Episkopi Formation in Hydra, but they are rather commonly reworked in Mesozoic and Cainozoic sequences. The palaeobiogeographical affinities shared by the foraminiferal markers of Greece, southeastern Pamir, and southern China, are very strong (up to the specific level), and are congruent with the Pangea B reconstructions. To cite this article: E. Skourtsos et al., C. R. Geoscience 334 (2002) 925–931.     

PALEONTOLOGY

正20141596 Liu Yunhuan(School of Earth Sciences and Resources,Chang’an University,Xi’an 710054,China);Shao Tiequan Early Cambrian Quadrapyrgites Fossils of Xixiang Boita in Southern Shaanxi Province(Journal of Earth Sciences and Environment,ISSN1672-6561,CN61-1423/P,35(3),2013,p.39-43,3 illus.,20 refs.)     

GEOCHEMICAL EXPLORATION

正20141719 Chen Zhijun(State Key Laboratory of Geological Processes and Mineral Resources,China University of Geosciences,Wuhan 430074,China);Chen Jianguo Automated Batch Mapping Solution for Serial Maps:A Case Study of Exploration Geochemistry Maps(Journal of Geology,ISSN1674-3636,CN32-1796/P,37(3),2013,p.456-464,2 illus.,2 tables,10 refs.)     

MICROPALAEONTOLOGY

正20140962 Chen Fenning(Xi’an Institute of Geology and Mineral Resources,Xi’an710054,China);Chen Ruiming Late Miocene-Early Pleistocene Ostracoda Fauna of Gyirong Basin,Southern Tibet(Acta Geologica Sinica,ISSN0001-5717,CN11-1951/P,87(6),2013,p.872-886,6illus.,56refs.)     

PETROLOGY

正1.IGNEOUS PETROLOGY20142008Cai Jinhui(Wuhan Center,China Geological Survey,Wuhan 430205,China);Liu Wei Zircon U-Pb Geochronology and Mineralization Significance of Granodiorites from Fuzichong Pb-Zn Deposit,Guangxi,South China(Geology and Mineral Resources of South China,ISSN1007-3701,CN42-1417/P,29(4),2013,p.271-281,7illus.,     

ENVIRONMENTAL GEOLOGY

正20141205Cheng Weiming(State Key Laboratory of Resources and Environmental Information System,Institute of Geographic Sciences and Natural Resources Research,CAS,Beijing 100101,China);Xia Yao Regional Hazard Assessment of Disaster Environment for Debris Flows:Taking Jundu Mountain,Beijing as an     

PROSPECTING EXPLORATION

正20141266Fan Chaoyan(Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes,Guangzhou 510275,China);Wang Zhenghai On Error Analysis and Correction Method of Measured Strata Section with Wire Projection Method(Journal of     

OCEANOGRAPHY & MARINE GEOLOGY

正20140582 Fang Xisheng(Key Lab.of Marine Sedimentology and Environmental Geology,First Institute of Oceanography,State Oceanic Administration,Qingdao 266061,China);Shi Xuefa Mineralogy of Surface Sediment in the Eastern Area off the Ryukyu Islands and Its Geological Significance(Marine Geology Quaternary Geology,ISSN0256-1492,CN37     

ENVIRONMENTAL GEOLOGY

正20141810 Bian Yumei(Geological Environmental Monitoring Center of Liaoning Province,Shenyang 110032,China);Zhang Jing Zoning Haicheng,Liaoning Province,by GeoHazard Risk and Geo-Hazard Assessment(Journal of Geological Hazards and Environment Preservation,ISSN1006-4362,CN51-1467/P,24(3),2013,p.5-9,2 illus.,tables,refs.)