沙漠边缘地区果园幼树越冬技术措施的研究

调控２年生苹果树灌水次数、时期和土壤管理试验，使７月下旬１００ｃｍ上层含水量为土壤田间持水量的５０％左右，促进幼树根系向下生长、新梢适时停止生长、提早进入休眠准备；１０月上旬冬灌，下旬耕翻土壤、提高地温和降低冻土厚度，下旬耕翻土壤、提高地温和降低冻土厚度，使苹果幼树正常越冬率由对照的５２．４％提高到９７．１％，差异极显著。     

塔里木盆地西北缘中奥陶统、下志留统的空间分布特征及其相变的遥感分析

根据塔里木盆地西北缘中奥陶统和下志留统各组岩石的光谱特征分析，选择了ＴＭ３/１（Ｙ）２/３（Ｍ）７/５（Ｃ）减色比值合成影像对研究区岩石地层层序进行划分和对比，划分出Ｏ1₂、Ｏ2₂、Ｏ3₂、Ｓ1₁和Ｓ2₁等５个影像岩石地层单元，它们与研究区的岩性组一致，但其精度高于研究区１:２０万地质图。通过影像岩石地层的对比研究发现，研究区西部皮羌断裂以西在中奥陶世几乎未接受沉积，皮羌断裂以东出现了坎岭组，再往东至研究区东部，中奥陶统沉积较全；早志留世早期研究区西部沉积了海相红层，往研究区东部则相变为海相绿色地层。尤其是通过ＴＭ比值图像的分析，发现前人认为分布很局限，但具有很大生油潜力的印干组在研究区分布范围较广，并推断其沉积中心位于与研究区相邻的塔北隆起和北部坳陷一带。这为塔里木盆地油气评价和勘探提供了新的资料，并表明ＴＭ遥感数据的应用是沉积盆地油气勘探研究中的一种很有潜力技术方法。     

软流圈

大多数金属矿床的形成直接或间接与岩浆活动有关。岩浆在不同的深度产生,因而带来不同的有用矿物组合。例如,金、银、锡、铜、金刚石、铂族元素等矿床的形成与地幔成因的岩浆有关。有岩浆熔融体产于其中的那一个层称为软流圈。软流圈里发生的过程控制着全球的构造现象、岩浆现象和变质现象。本文用各种方法证实了软流圈的存在。根据最新的观点,软流圈是低粘滞度、低速度、低密度、低质量因数、高塑性、高流动性、高电导性和高地震波能吸收性的一个层。这些特性的异常习性是由于100-300公里深处地幔温度与地幔物质熔化温度互相接近所致。软流圈虽然在全球各地都有记录,但其分布极不均匀。在老构造(如加拿大地盾、波罗的地盾和北美地台)之下,软流圈表现微弱,或者完全缺失。在加拿大地盾和波罗的地盾之下,软流圈厚约加公里。但在现代构造活动区(如贝加尔裂谷带、亚洲-太平洋活动边缘、帕米尔-兴都库什地区)之下,软流圈发育良好,厚约100—200公里。 从贝加尔湖到太平洋的地区是软流圈构造变化最大的地区之一。这里软流圈顶部的深度从,10—20变化到200公里,厚度则达200—400公里。软流圈顶部的最小深度和软流圈的最大厚度见于贝加尔裂谷带和亚洲-太平洋活动边缘。这两处是现代构造活动区。介于其间的地区由?     

地层含金银性评价的地球化学准则——以扬子地台北缘中段中上元古界为例

金银丰度的高低不是控制金银矿化的决定性因素。有利于金矿化的因素包括:较高的金银丰度;全银的几何平均值与算术平均值比较;金分布及银分布均为多峰偏态,对数分布为正态-正偏;易释放金比例高;地层中金银形成的元素组合同区域金银矿床的矿化元素组合接近。     

华北地台南缘燕山期板内花岗斑岩类地球化学特征及成分空间变化规律

华北地台南缘燕山期花岗斑岩类小岩体形成于大陆板内环境,它具有类似岛弧—活动大陆边缘钙碱系列岩石地球化学特征,其成分在空间上呈现极性特征。本文探讨了这种成分极性与中、新生代俯冲带花岗岩类的可比性,并根据锶、钕同位素资料揭示成岩物质的可能来源及造成成分空间变化的可能原因。     

郯庐断裂系研究的新进展─—兼论东亚北东向走滑断裂系统

对郯庐断裂系研究的最新进展作了介绍。郯庐断裂是多期活动、性质多次转换的巨型断裂。最初的启动时间在晚三叠世末，与南北大陆的碰撞有着直接的关系。早期以走滑（左行）运动为主，伴随挤压和拉伸，范围限于华北地块内部。断裂纵向伸展的高峰期为白垩纪到早始新世，这一时期也是裂陷作用最强的时期。始新世以来以挤压作用为主。东亚走滑断裂系各组成断裂性质复杂，不能以中生代左行平移运动简单概括。走滑断裂系的发展和演化与同时期大陆边缘所处的地球动力学环境，也就是与南北大陆的碰撞和古大洋板块的持续俯冲关系密切。新生代以来的构造事件使中生代的构造发生强烈变形变位改造。     

闽东南大陆边缘构造特征及泉州海外大震构造环境分析

闽东南大陆边缘构造活动，自晚更新世以来，断裂活动以继承性差异升降作为主要特点，本文分析了１６０４年１２月２９日泉州海外８级大震与该区断裂活动的关系，并对该次大震震源断层面错动方式进行了讨论。     

Source mechanism and source parameters of May 28, 1998 earthquake,Egypt

On May 28, 1998, a moderate size earthquake of mb 5.5 occurred offshore the northwestern part of Egypt (latitude 31.45°N and longitude 27.64°E). It was widely felt in the northern part of Egypt. Being the largest well-recorded event in the area for which seismic data from the global digital network are available, it provides an excellent opportunity to study the tectonic process and present day stress field occurring along the offshore Egyptian coast. The source parameters of this event are determined using three different techniques: modeling of surface wave spectral amplitudes, regional waveform inversion, and teleseismic body waveform inversion. The results show a high-angle reverse fault mechanism generally trending NNW–SSE. The P-axis trends ENE–WSW consistently with the prevailed compression stress along the southeastern Hellenic arc and southwestern part of the Cyprean arc. This unexpected mechanism is most probably related to a positive inversion of the NW trending offshore normal faults and confirms an extension of the back thrusting effects towards the African margin. The estimated focal depth ranges from 22 to 25 km, indicating a lower crustal origin earthquake owing to deep-seated tectonics. The source time function indicates a single source with rise time and total rupture duration of 2 and 5 s, respectively. The seismic moment (M _o) and the moment magnitude (M _w) determined by the three techniques are 1.03 × 10¹⁷ Nm, 5.28; 1.24 × 10¹⁷ Nm, 5.33; and 1.68 × 10¹⁷ Nm, 5.42; respectively. The calculated fault radius, stress drop, and the average dislocation assuming a circular fault model are 7.2 km, 0.63 Mpa, and 0.11 m, respectively.     

Long‐term landscape evolution: linking tectonics and surface processes

Research in landscape evolution over millions to tens of millions of years slowed considerably in the mid‐20th century, when Davisian and other approaches to geomorphology were replaced by functional, morphometric and ultimately process‐based approaches. Hack's scheme of dynamic equilibrium in landscape evolution was perhaps the major theoretical contribution to long‐term landscape evolution between the 1950s and about 1990, but it essentially ‘looked back’ to Davis for its springboard to a viewpoint contrary to that of Davis, as did less widely known schemes, such as Crickmay's hypothesis of unequal activity. Since about 1990, the field of long‐term landscape evolution has blossomed again, stimulated by the plate tectonics revolution and its re‐forging of the link between tectonics and topography, and by the development of numerical models that explore the links between tectonic processes and surface processes. This numerical modelling of landscape evolution has been built around formulation of bedrock river processes and slope processes, and has mostly focused on high‐elevation passive continental margins and convergent zones; these models now routinely include flexural and denudational isostasy. Major breakthroughs in analytical and geochronological techniques have been of profound relevance to all of the above. Low‐temperature thermochronology, and in particular apatite fission track analysis and (U–Th)/He analysis in apatite, have enabled rates of rock uplift and denudational exhumation from relatively shallow crustal depths (up to about 4 km) to be determined directly from, in effect, rock hand specimens. In a few situations, (U–Th)/He analysis has been used to determine the antiquity of major, long‐wavelength topography. Cosmogenic isotope analysis has enabled the determination of the ‘ages’ of bedrock and sedimentary surfaces, and/or the rates of denudation of these surfaces. These latter advances represent in some ways a ‘holy grail’ in geomorphology in that they enable determination of ‘dates and rates’ of geomorphological processes directly from rock surfaces. The increasing availability of analytical techniques such as cosmogenic isotope analysis should mean that much larger data sets become possible and lead to more sophisticated analyses, such as probability density functions (PDFs) of cosmogenic ages and even of cosmogenic isotope concentrations (CICs). PDFs of isotope concentrations must be a function of catchment area geomorphology (including tectonics) and it is at least theoretically possible to infer aspects of source area geomorphology and geomorphological processes from PDFs of CICs in sediments (‘detrital CICs’). Thus it may be possible to use PDFs of detrital CICs in basin sediments as a tool to infer aspects of the sediments' source area geomorphology and tectonics, complementing the standard sedimentological textural and compositional approaches to such issues. One of the most stimulating of recent conceptual advances has followed the considerations of the relationships between tectonics, climate and surface processes and especially the recognition of the importance of denudational isostasy in driving rock uplift (i.e. in driving tectonics and crustal processes). Attention has been focused very directly on surface processes and on the ways in which they may ‘drive’ rock uplift and thus even influence sub‐surface crustal conditions, such as pressure and temperature. Consequently, the broader geoscience communities are looking to geomorphologists to provide more detailed information on rates and processes of bedrock channel incision, as well as on catchment responses to such bedrock channel processes. More sophisticated numerical models of processes in bedrock channels and on their flanking hillslopes are required. In current numerical models of long‐term evolution of hillslopes and interfluves, for example, the simple dependency on slope of both the fluvial and hillslope components of these models means that a Davisian‐type of landscape evolution characterized by slope lowering is inevitably ‘confirmed’ by the models. In numerical modelling, the next advances will require better parameterized algorithms for hillslope processes, and more sophisticated formulations of bedrock channel incision processes, incorporating, for example, the effects of sediment shielding of the bed. Such increasing sophistication must be matched by careful assessment and testing of model outputs using pre‐established criteria and tests. Confirmation by these more sophisticated Davisian‐type numerical models of slope lowering under conditions of tectonic stability (no active rock uplift), and of constant slope angle and steady‐state landscape under conditions of ongoing rock uplift, will indicate that the Davis and Hack models are not mutually exclusive. A Hack‐type model (or a variant of it, incorporating slope adjustment to rock strength rather than to regolith strength) will apply to active settings where there is sufficient stream power and/or sediment flux for channels to incise at the rate of rock uplift. Post‐orogenic settings of decreased (or zero) active rock uplift would be characterized by a Davisian scheme of declining slope angles and non‐steady‐state (or transient) landscapes. Such post‐orogenic landscapes deserve much more attention than they have received of late, not least because the intriguing questions they pose about the preservation of ancient landscapes were hinted at in passing in the 1960s and have recently re‐surfaced. As we begin to ask again some of the grand questions that lay at the heart of geomorphology in its earliest days, large‐scale geomorphology is on the threshold of another ‘golden’ era to match that of the first half of the 20th century, when cyclical approaches underpinned virtually all geomorphological work. Copyright © 2007 John Wiley & Sons, Ltd.