王乃樑先生对中国地貌学发展的主要贡献

王乃樑先生是中国著名的地貌学家。20世纪40年代至90年代初期,先后在清华大学和北京大学任教。他对中国黄土高原、华北、东北、西北、四川、湖北和广西等广大地区进行了地貌和新生代沉积研究,在新生代沉积与地貌演化历史、新构造活动与构造地貌学、地貌学与沉积学基本理论与方法等诸多领域取得了一系列创新性的成果。在地貌学学科建设、人才培养、科学研究和国内外学术交流诸方面,为中国地貌学的发展做出了卓越贡献。     

The Present Research and Prospect of Chinese Geosciences History

It has been over a hundred years since the birth of research on Chinese geosciences history, which was accompanied by the continuous progress of Chinese geosciences. For hundreds of years, it has grown out of nothing to brilliant performance by several generations of Chinese geologists committing their hearts and minds with the spirit of exert and strive without stop to promote the process of China's industrialization and to produce the significant impact on serving the society. The study of Chinese geosciences history reflects objectively and historically the history of geosciences in China, which has recorded, analyzed and evaluated the dynamic process sitting in the background and clue of the history of Chinese geosciences development. The study of the history of geological science has roughly experienced two stages in China. The first stage is the study of individual researchers. It spanned approximately 70 years from the early 20th century to the end of the 1970s. The research contents were mainly based on the evolution of geological organizations, the development and utilization of individual mineral species, the history of deposit discovery and the research of geological characters. The main representatives are Zhang Hongzhao, Ding Wenjiang, Weng Wenhao and Li Siguang, Ye Liangfu, Huang Jiqing, Yang Zhongjian, Xie Jiarong, Gao Zhenxi, Wang Bingzhang and etc. The most prominent feature of this period is the accumulation of a very valuable document for the study of the history of China's geological history and lays a foundation for the exchange of geological science between China and foreign countries. The second stage is organized group study. It took around 60 years from the 1920s to 1980s. It includes the history of Chinese geology, the history of geological organizations, the history of geological disciplines, the history of geological education, the history of geological philosophy, the history of Chinese and foreign geological science communication, the history of geologists and etc. The most chief feature of this stage is the birth of academic research institute―the establishment of the Commission on the History of Geology of the Geological Society of China.     

盾构地铁隧道区间在地震作用下的三维动力时程响应分析

地铁已成为城市地下空间结构和轨道交通网络的重要组成部分。为预估和降低地震灾害的影响,以西安盾构地铁区间隧道为例,建立了地铁隧道区间三维计算模型,进行三维抗震时程响应分析。采用粘弹性局部人工边界模拟地基结构的半无限性,利用不同超越概率水平下的地震动参数作为参考,考虑相位随机性影响,拟合地震动时程样本,建立了地基与结构相互作用的三维有限元模型。计算结果表明,地震发生时,顶部、底面、侧面、以及联络通道处虽产生变形影响,但均在规范规定范围内;位移时程曲线、位移分布云图、拉压应力云图清楚显示区间结构在地震持续时的抗震情况,数据表明结构最不利位置在联络通道处,而内力和变形均满足规范安全要求。     

Fashion and phases of late Pleistocene aggradation and incision in the Alaknanda River Valley, western Himalaya, India

We study the aggradation and incision of the Alaknanda River Valley during the late Pleistocene and Holocene. The morphostratigraphy in the river valley at Deoprayag shows the active riverbed, a cut terrace, and a fill terrace. The sedimentary fabric of the fill terrace comprises four lithofacies representing 1) riverbed accretion, 2) locally derived debris fan, 3) the deposits of waning floods and 4) palaeoflood records. The sedimentation style, coupled with geochemical analysis and Optically Stimulated Luminescence (OSL) dating, indicate that this terrace formed in a drier climate and the river valley aggraded in two phases during 21–18 ka and 13–9 ka. During these periods, sediment supply was relatively higher. Incision began after 10 ka in response to a strengthened monsoon and aided by increase of the tectonic gradient. The cut terrace formed at ~ 5 ka during a phase of stable climate and tectonic quiescence. The palaeoflood records suggest wetter climate 200–300 yr ago when the floods originated in the upper catchment of the Higher Himalaya and in the relatively drier climate ~ 1.2 ka when locally derived sediments from the Lesser Himalaya dominated flood deposits. Maximum and minimum limits of bedrock incision rate at Deoprayag are 2.3 mm/a and 1.4 mm/a.     

时空模型在宗地变更和历史回溯中的研究

地籍信息具有显著的时间特性,将地籍数据的时间、空间及属性三者合理地组织在地籍信息系统中的研究具有重要意义。本文借鉴目前TGIS和各种时空应用模型的优势,提出一种基于宗地变更的时空数据结构。针对地籍管理系统中宗地变更和历史回溯的需求,将数据库分为历史库和变更库,比较好的实现了宗地管理要求,有效弥补了一些时空数据库过于臃肿、系统运行效率低下等缺陷。     

济阳-临清东部地区石炭-二叠系煤系烃源岩二次生烃研究

济阳-临清东部地区上古生界石炭-二叠系煤系源岩是油气勘探的另一个重要领域。根据研究区沉积地层构造演化分析,不同的构造演化决定了不同的埋藏史演化;研究表明,中生代期间及新生代期间石炭-二叠系煤系烃源岩存在“二次生烃”过程,石炭系煤系烃源岩是研究区的主力烃源岩,二叠系的次之;济阳坳陷累计生烃量大于临清东部地区的累计生烃量。     

Volcanic and Tectonic Framework of the Hydrothermal Activity of the Izu–Bonin Arc

In the Izu–Bonin Arc, hydrothermal activities have been reported from volcanoes along present‐day volcanic front, a rear arc volcano and a back‐arc rift basin as well as a remnant arc structure now isolated from the Quaternary arc. It is widely known that characteristics of hydrothermal activity (mineralogy, chemistry of fluid etc.) vary depending upon its tectonic setting. The Izu–Bonin Arc has experienced repeated back‐arc or intra‐arc rifting and spreading and resumption of arc volcanism. These characteristics make this arc system a suitable place to study the tectonic control on hydrothermal activity. The purpose of the present paper is, therefore, to summarize volcanotectonic setting and history of the Izu–Bonin Arc in relation to the hydrothermal activity. The volcanotectonic history of the Izu–Bonin Arc can be divided into five stages: (i) first arc volcanism (boninite, high‐Mg andesite), 48–46 Ma; (ii) second arc volcanism (tholeiitic, calc‐alkaline), 44–29 Ma; (iii) first spreading of back‐arc basin (Shikoku Basin), 25–15 Ma; (iv) third arc volcanism (tholeiitic, calc‐alkaline), 13–3 Ma; and (v) rifting in the back‐arc and tholeiitic volcanism along the volcanic front, 3–0 Ma. Magmas erupted in each stage of arc evolution show different chemical characteristics from each other, mainly due to the change in composition of slab‐derived component and possibly mantle depletion caused by melt extraction during back‐arc spreading and prolonged arc volcanism. In the volcanotectonic context summarized here, hydrothermal activity recognized in the Izu–Bonin Arc can be classified into four groups: (i) present‐day hydrothermal activity at the volcanic front; (ii) active hydrothermal activity in the back arc; (iii) fossil hydrothermal activity in the back‐arc volcanoes; and (iv) fossil hydrothermal activity in the remnant arc. Currently hydrothermal activities occur in three different settings: submarine caldera and stratocones along the volcanic front; a back‐arc rift basin; and a rear arc caldera. In contrast, hydrothermal activities found in the back‐arc seamount chains were associated with rear arc volcanism in Neogene after cessation of back‐arc spreading of the Shikoku Basin. Finally, sulfide mineralization associated with boninitic volcanism in the Eocene presumably took place during forearc spreading in the initial stage of the arc. This type of activity appears to be limited during this stage of arc evolution.     

儒家文化对宋代测绘科技的驱动

世界著名的中国科技史专家李约瑟博士在其闻名于世的《中国科学技术史》一书中指出"每当人们研究中国文献中考察任何一种具体的科技史料,往往会发现它的焦点就在宋代。"宋代创造了领先世界的包括测绘科技在内的辉煌科技成就,其中中国四大发明的三大发明:印刷术、指南针和火药等都出现宋代。笔者认为,推动宋代测绘科技发展的一个重要原因就是宋代理学(新儒学)的繁荣和发展。     

Basin Modeling in the Kuqa Depression of the Tarim Basin (Western China): A Fully Temperature-dependent Model of Overpressure History

The fully temperature-dependent model of the effective pressure of the solid matrix and its related overpressure has been derived from the pressure balance equation, mass conservation, and Darcy’s law, and is directly useful in basin modeling. Application of the model in the Kuqa Depression of the Tarim Basin in western China proves that this overpressure model is highly accurate. The case of the present-day values of the calculated overpressure histories of Wells Kela2 and Yinan2 approach the field-measured data with mean absolute relative residuals of 3% and 5%, respectively. This indicates that the overpressure simulation is a practical alternative to using rock mechanics experiments for effective pressure measurement. Since calculation of the overpressure history uses the geohistory model and geothermal history model simulation outcomes, the relevant data used and the output of the two models of the Kela2 well are given as examples. The case studies show that the pore fluid density and viscosity used in the calculation of overpressures should be temperature-dependent, otherwise the calculation results would deviate far from the field-measured pressure data. They also show that the most sensitive parameter governing overpressure is permeability, and permeability can be calculated by using either the Kozeny–Carman formula or the porosity–power function. The Kozeny–Carman formula is better if accurate data for the specific surface area of the solid matrix (S _a ) exists, otherwise, the porosity–power function is used. Furthermore, it is vital for calculating an accurate overpressure history that one can calibrate S _a in the Kozeny–Carman formula, or index m in the porosity–power function by using field-measured pressure data as a constraint. In these specific case studies, the outcome found by using the Kozeny–Carman formula approaches the outcome found by using the porosity–power function with m=4, and both approach the field-measured pressure data.