基于嵌入式IPv6Web服务器的地震数据采集器参数管理系统

介绍嵌入式Web服务器goAhead移植到IPv6网络的方法,并介绍基于goAhead Web Server,实现地震数据采集器参数管理系统的关键技术.基于嵌入式IPv6 Web服务器设计开发的B/S结构的地震数据采集器参数管理系统,可实现仪器工作状态查询和系统参数管理.     

四维地震资料处理及其关键

四维地震利用时延三维地震资料的差异来解释地下储层流体的变化，时延地震资料的差异除了受地下储层流体因素的影响外，还受采集和处理因素的影响。为了尽可能的减少或消除由非储层因素所引起的差异，四维地震资料处理总的要求是相对振幅保持处理，高信噪比处理和一致性处理，一致性处理是四维地震资料特有的处理，其一般处理原则是：（１）调查影响四维地震资料非穗生的原因；（２）保持处理流程的一致性；（３）尽量保持相同的偏移     

气候变化和人类活动在沙漠化过程中相对作用评价综述(英文)

Climate change and human activities are the two kinds of driving forces in desertification,and assessing their relative role in desertification is of great significance to deeply understanding the driving mechanisms and preventing desertification expansion.This paper has systematically reviewed the progress of the researches on assessing the relative role of climate change and human activities in desertification from qualitative,semi-quantitative and quantitative aspects respectively.The authors found that there were still some problems in the previous researches.For example,the subjectivity in assessment was obvious,the assessment cannot be easily repeated,and the assessment and its results were always based on administrative regions and less taken and expressed in a continuous space.According to the progress of previous researches and the works conducted by the authors recently,we put forward a quantitative approach by selecting NPP as a common indicator to measure the relative role of climate change and human activities in desertification and dividing the ecological process of "driving force effect-dynamic response of desertified land" into several scenarios.Meanwhile,validation and scale of assessment should be taken into account when quantitative assessment of the relative role of climate change and human activities in desertification are carried out.     

欧盟"气候行动与可再生能源综合计划"建议草案: 核心要点与战略意义

概述了欧盟"气候行动与可再生能源综合计划"建议草案的出台背景、核心要点和主要内容,评价了各方反应及该建议草案的优点和缺点,分析了该建议草案与《京都议定书》第二承诺期气候谈判的联系及其对碳市场的影响。最后,针对中国参与清洁发展机制（CDM）活动,提出了个人的思考和建议。     

地面沉降时空形变场的构建方法研究

由于离散分布的精密水准测量数据只能对点状沉降信息进行监测分析,描述特定时间点的静态空间趋势,无法表达区域性地面沉降整体时空变化.该文提出一种地面沉降时空形变场的构建方法,在多项式拟合法构建形变场的基础上考虑时间项,通过探索地面沉降量与坐标、时间的关系,对区域地面形变的整体效果进行拟合,构建地面沉降时空形变场.该方法顾及...     

遗传算法在组分温度反演中的应用

介绍了遗传算法的主要内容和工作原理。在连续植被热辐射方向性模型的基础上,从热红外多角度遥感数据中,同时反演混合像元组分温度、土壤比辐射率以及叶面积指数。大量试验表明,利用遗传算法反演组分温度效果非常好。在宽松的先验知识条件下,该方法可以解决不确定性反演问题     

有机流体成矿作用与古油藏成藏作用相互耦合——以右江盆地微细浸染型金矿为例

右江盆地微细浸染型金矿与古油藏均产于二叠纪生物礁的核部或侧翼.流体包裹体拉曼光谱分析和矿石抽提物色质谱分析均发现了大量的有机质官能团, 暗示金矿成矿过程与古油藏的形成、演化密切相关.金矿与古油藏的物质均来源于盆地裂陷期和凹陷早期的沉积地层, 流体来源于沉积地层中封存的建造水, 形成年龄 > 172 Ma.在随后约40 Ma(172~130 Ma)的时间里, 流体向盆地中生物礁及其他构造部位运移聚集.由于盆地中烃源岩逐渐成熟, 这一过程是油气运移成藏的过程, 也是有机流体萃取成矿物质, 最终演变为有机成矿流体并聚集的过程.燕山运动是金矿成矿作用的主要构造营力(130~46 Ma), 同时也是古油藏破坏的主要原因.正是古油藏的破坏打破了流体的动态平衡, 导致流体中成矿物质沉淀形成矿床.右江盆地的金矿和古油气藏是同一种流体体系在其发展演化过程中不同阶段的产物.      

地震计远程监控功能接口的实现

提出了一种适用于地震计远程监控功能接口的实现方式,扩充了地震数据采集器的应用。     

基于拉格朗日拟序结构的吕宋海峡表层水交换研究

黑潮通过吕宋海峡入侵南海呈现明显的瞬态特征。以往的研究通常将黑潮在吕宋海峡附近的流态分为几种不同类型。本文基于表层地转流计算得到的有限时间李雅普诺夫指数场（FTLE）,展示了拉格朗日视角下的吕宋海峡上层水交换特征。从FTLE场提取的拉格朗日拟序结构（LCSs）很好地识别了吕宋海峡附近的典型流态和旋涡活动。此外,这些LCSs还揭示了吕宋海峡周围复杂的输运路径和流体域,这些特征得到了卫星跟踪浮标轨迹的验证,且从流速场中是无法直接识别的。FTLE场显示,吕宋海峡附近表层水体的输运形态主要可分为四类。其中,黑潮直接向北流动的“跨越”形态和顺时针旋转的“流套”形态的发生频次明显高于直接进入南海的黑潮分支“渗入”形态和南海水流出至太平洋的“外流”形态。本文还进一步分析了黑潮在吕宋海峡处的涡旋脱落事件,突出强调了LCSs在评估涡旋输运方面的重要性。反气旋涡旋的脱落个例表明,这些涡旋主要源自黑潮“流套”,涡旋脱落之前可有效地俘获黑潮水。LCS所指示的输运通道信息有助于预测最终被反气旋涡所挟卷水体在上游的位置。而在气旋涡的形成过程中,LCS的分布特征表明,大部分气旋涡并未与黑潮水的输运路径相连通。因此,气旋涡对从太平洋到南海的上层水交换的贡献较小。     

Major contribution to carbon neutrality by China’s geosciences and geological technologies

In the context of global climate change, geosciences provide an important geological solution to achieve the goal of carbon neutrality, China’s geosciences and geological technologies can play an important role in solving the problem of carbon neutrality. This paper discusses the main problems, opportunities, and challenges that can be solved by the participation of geosciences in carbon neutrality, as well as China’s response to them. The main scientific problems involved and the geological work carried out mainly fall into three categories: (1) Carbon emission reduction technology (natural gas hydrate, geothermal, hot dry rock, nuclear energy, hydropower, wind energy, solar energy, hydrogen energy); (2) carbon sequestration technology (carbon capture and storage, underground space utilization); (3) key minerals needed to support carbon neutralization (raw materials for energy transformation, carbon reduction technology). Therefore, geosciences and geological technologies are needed: First, actively participate in the development of green energy such as natural gas, geothermal energy, hydropower, hot dry rock, and key energy minerals, and develop exploration and exploitation technologies such as geothermal energy and natural gas; the second is to do a good job in geological support for new energy site selection, carry out an in-depth study on geotechnical feasibility and mitigation measures, and form the basis of relevant economic decisions to reduce costs and prevent geological disasters; the third is to develop and coordinate relevant departments of geosciences, organize and carry out strategic research on natural resources, carry out theoretical system research on global climate change and other issues under the guidance of earth system science theory, and coordinate frontier scientific information and advanced technological tools of various disciplines. The goal of carbon neutrality provides new opportunities and challenges for geosciences research. In the future, it is necessary to provide theoretical and technical support from various aspects, enhance the ability of climate adaptation, and support the realization of the goal of carbon peaking and carbon neutrality.