柴达木盆地西部新生代气候与地形演变

从孢粉植物分异及演变，干旱碎屑及膏盐沉积分布等方面，对柴达木盆地西部新生代气候与地形的演变进行了探讨。结果表明，盆地西部新生代两个极端干燥气候期（膏盐发育期）分别出现在始新世至渐新世及上新世至第四纪。前者与老第三纪行星环流控制下的副热带干燥带有关，而后者与青藏高原的隆升有关。早第三纪盆地西部及周围地区的地势不象以前所认为的那么低平。在第三纪，昆仑山比祁连山低。晚新生代盆地向北推移了７－１１个纬距。     

阿尔泰诺尔特地区地层—岩浆—构造轮廓初析

新疆阿尔泰北部诺尔特地区的地质轮廓主要形成于海西期，地层主要由上泥盆统和下石炭统组成，岩石以沉积碎屑岩为主，夹火山碎屑岩和熔岩。沉积厚度较大，并且具粗砂岩、细砂岩和粉砂岩反复出现的韵律特征。诺尔特地区的火山岩为海西早、中期形成，早期形成岩屑、晶屑凝灰岩和英安岩，海西中期形成石英斑岩和凝灰岩，前者以中性为主，后者则偏酸性；在构造分区图上投点表明，前者落在Ａ区，属非造山带火山岩，后者落在Ｂ区，属造山带及岛弧火山岩区；稀土配分型式表明，海西早期火山岩的铕异常明显，海西中期火山岩的铕异常不明显。诺尔特地区花岗岩属海西晚期产物，数量不多，通过ＡＲ─ＳｉＯ２图、Ｋ—Ｎａ─Ｃａ图、ＡＣＦ图等图解的分析表明，它们属碱性岩浆成因的Ｓ型花岗岩，稀土元素配分型式显示花岗岩分界明显，但曲线平缓，分异不彻底。诺尔特地区地质构造演化的基本轮廓：早期是一种类似坳拉谷的环境；中期逐步闭合并抬升；晚期裂谷完全闭合，整个地区露出水面接受剥蚀。     

中国西部地区全新世自然环境演变序列与特征

根据湖泊、山地冰川、黄土与古土壤序列、泥炭及沙漠演变等多种地质记录的综合对比分析，重建和恢复了我国酉部地区全新世以来的自然环境演变序列及特征。全新世期间我国西部地区环境演变存在着以水热配置关系不同为突出特征的两种不同的演变模式：即以新疆北部地区为代表的西风型和以青海湖及青藏高原为代表的季风型模式。其成因同区域性特征及大气环流形势密切相关。并划分出我国西部地区全新世自然环境演变过程中的几个重要时间界线，即距今１２ｋａ或１０ｋａ、９ｋａ、３ｋａ和０．５ｋａ。众多地质记录间良好的对比关系对于深入理解我国西部全新世气候环境的演变过程，预测其变化趋向具有十分重要的意义。     

河北唐山—卢龙地区寒武－奥陶系界线地层的牙形刺及其重要属种的演化

本文对唐山和卢龙地区寒武－奥陶系界线地层中的牙形刺再次进行研究，厘定了过去报道的一些重要属种，并对最具地层意义的Ｃｏｒｄｙｌｏｄｕｓ的几个种的演化进行了分析。指出了该属的两个进化系列，第一支进化系列是Ｅｏｃｏｎｏｄｏｎｔｕｓｎｏｔｃｈｐｅａｋｅｎｓｉｓ－Ｃｏｒｄｙｌｏｄｕｓｐｒｉｍｉｔｉｖｕｓ－Ｃ．ｐｒｏａｖｕｓ－Ｃ．ｃａｂｏｔｉ－Ｃ．ｉｎｔｅｒｍｅｄｉｕｓ－Ｃ．ａｎｇｕｌａｔｕｓ；而另一支则是Ｅｏｃｏｎｏｄｏｎｔｕｓｎｏｔｃｈｐｅａｋｅｎｓｉｓ－Ｃ．ｃａｂｏｔｉ－Ｃ．ｐｒｏｌｉｎｄｓｔｒｏｍｉ－Ｃ．ｌｉｎｄｓｔｒｏｍｉ－Ｃ．ｐｒｉｏｎ。本文对寒武－奥陶系界线的几个划分方案也进行了简单的讨论     

阿尔泰造山带构造演化研究中的几个关键问题剖析

对阿尔泰山地区的构造格局、构造变质、岩浆岩时代、动力热事件和构造区类型归属等几个地学基础问题进行深入细致研究的基础上，反演了阿尔泰地槽造山带形成和演化的递进历程。     

华北中北部高级变质岩区的构造区划及其晚太古代构造演化

通过区域构造编图及重点地段的详细研究，在华北克拉通中北部识别出一条ＮＮＥ向的构造带——龙泉关－桑干带，它以大规模的韧性剪切带网络、重熔钾质花岗岩带、数量众多的高压麻粒岩构造透镜体或岩片为特征。剪切带以低角度逆冲为主，矿物拉伸线理指示运动方向为ＮＷ－ＳＥ向。这些剪切带造成东西两侧基底杂岩与表壳岩系包括孔兹岩系的广泛构造叠置，以及高压麻粒岩的近等温减压上隆。从更大的范围看，龙泉关－桑干带处于鄂尔多斯克拉通和阜平－赞皇克拉通之间，并且被五台－吕梁裂谷型绿岩带截切或不整合覆盖。该带应形成于晚太古代，记录了上述两个克拉通斜向拼合的构造过程     

豫南中温榴辉岩中角闪石的变质演化

在该区中温榴辉岩的各个演化阶段中，出现了不同成分的角闪石。石榴石环带及其核部的闪石等矿物包囊体记录了前榴辉阶段及其进变质演化的特征。在榴岩阶段晚期，蓝闪石稳定出现，其成分环带反映了压力降低的连续过程；角闪石－斜长石后成合晶为石榴石和绿辉石的退变质产物；退变质后期，钙质闪石大量出现。角闪石的矿物组合及其成分变化，反映了中温榴辉岩的顺时针变质演化过程。     

鄂北—豫南地区榴辉岩相岩石变质作用演化特征

鄂北－豫南地区榴辉岩相变质岩石类型多样，其野外产状和岩石化学特征反映了原地变质成因。根据区域地质及榴辉岩相变质岩石的野外产状，结合榴辉岩中石榴石绿辉石的Ｆｅ２＋－Ｍｇ互换温度计所计算出的峰期变质温度，将本区榴辉岩分为两类，一类为中温榴辉岩，产于晚太古界—早元古界大别群，为Ｂ类榴辉岩，由绿帘角闪岩相岩石进变质形成。榴辉岩相变质作用分为两阶段，首先为柯石英榴辉岩相阶段，其峰期变质条件为Ｔ＝６００℃～７００℃，Ｐ＝２．７～３．０ＧＰａ，然后近等温降压，出现蓝闪石等含水矿物，为蓝闪石榴辉岩相阶段，此时水活度在榴辉岩相变质过程中起着重要作用；另一类为低温榴辉岩，产于中元古界七角山组，为Ｃ类榴辉岩，由蓝片岩相岩石进变质形成，其峰期变质条件为Ｔ＝４９０℃～５６０℃，Ｐ＜１．５ＧＰａ。中温榴辉岩与低温榴辉岩具有不同的变质作用特征。最后讨论了本区高压变质带的成因演化。     

A model study on the decay of volcanic aerosol layer and verification with Pinatubo and El Chichon data

The time evolution of stratospheric aerosol layer formed after a volcanic eruption is studied taking into account the aerosol microphysical processes of growth, coagulation and sedimentation. Using a simple model we could explain the observed evolution of the Pinatubo volcanic layer which decayed in about 3 years. The experimental data obtained by Nd:YAG backscatter lidar over Ahmedabad further supports this finding. The data obtained after the El Chichon volcanic eruption also showed that the El Chichon aerosol layer decayed in about 3 years time. Thus, though the amount of SO₂ injected has been higher, in the case of Pinatubo, about two to three times more than El Chichon, it has resulted in the production of larger aerosol particles due to faster growth and coagulation processes, and subsequently a faster removal rate, to give more or less a similar background aerosol amount at the stratosphere in about 3 years time.     

Groundwater acidification in Triassic sandstones: prediction with MAGIC modelling

 Acidification of groundwater lags behind acid deposition due to the relatively long water residence time in conjunction with various buffering processes in the soil zone and deeper aquifer (chemical weathering, cation exchange, sulfate sorption, and N uptake by the biomass). Extensive field data from eight forested catchments in the Bunter Sandstone of the Black Forest, including results from water budget studies and hydrochemical analysis of stream and spring waters, were used to simulate the future evolution of ground-water acidification with the MAGIC model. The present acid deposition exceeds the “critical load” (here meaning buffering due to chemical weathering and protonation of organic acids) in six of eight catchments. Two catchments are well buffered because they contain carbonate-bearing layers in the Upper Bunter sandstone. Transient buffering (i.e., cation exchange, N uptake, the sulfate sorption) thus far prevents worse acidification, but this effect will decline in the future. For one of the poorly buffered catchments (Seebach), a two-layer simulation was carried out, based on extensive data from 10 years of measurements. Validation of the long-term simulations by hydrochemical and soil data was hampered by strong annual variations but generally supported by paleolimnological studies. In the future, reductions in the S deposition by 20% and the N deposition by 10% up to the year 2030 are assumed as the most probable scenario. N uptake through soil and vegetation will come to an end as suggested by decreasing C/N ratios of the organic matter. This process is arbitrarily included in the simulations. In the periglacial soil layer, acidification will decrease until the year 2030 and then approach a steady-state condition. In the fractured aquifer, acidification will also proceed at a decreasing rate; however, sulfate desorption up to the year 2130, the end of simulated period, will prevent earlier remediation. Despite a significant reduction in S deposition since the mid-1980s, further efforts are necessary to reduce the emission of acidifying substances. Liming in the recharge area is partially effective to ameliorate “shallow” groundwater but largely fails to ameliorate “deeper” groundwater in the sandstone aquifer. Received: 30 July 1996/Accepted: 23 January 1997