基于GRID的坡耕地退耕压力模型研究

坡耕地退耕还林还草作为保护生态环境的重要措施,已于2000年在长江上游及黄河中上游等地区进行大面积试点。然而,坡耕地退耕还林还草也引发一系列局域性和阶段性的复杂问题,如粮食安全保障、生态移民安置等。这些问题产生的重要根源是坡耕地空间分布差异导致的人口压力状况的空间差异。文章设计了4个基于GRID的坡耕地退耕人口压力指数模型,并以三峡库区的奉节县为例进行了模拟。     

深部天然核反应堆——一种可能的山脉隆升动力源

板块碰撞造山模式难以解释造山作用在时间上的“滞后”和在空间上的“差位”现象，大量研究表明山脉隆升的动力来自深部，因此，探索深部地质过程的物理和化学机制及其导致的能量再分配是认识山脉隆升动力学机制的关键，若干线索表明地幔中的核反应中可能在岩石圈动力学演化过程中起过不可忽视的作用，通过分析U，Th等元素的地球化学性质及其在深变质过程中的行为，认为伴随板块俯冲发生的陆壳物质向地幔的再循环有可能在办流圈顶部形成富含U，Th,K等放射性亲石元素和碳质（石墨）的地质体，通过理论上的论证和对Oklo天然核反应堆遗迹的反演表明这些地质体可能有一部分具备了形成石墨核反应堆的条件。这种反应堆在亚临界状态下的断续运行有可能为其上方岩石圈中的岩浆作用提供热源，进入超临界状态时将可能导致深部核爆炸，成为地震，火山爆发和岩石圈破裂的动力来源，据此建立的山脉隆升的动力学初步模式，可以解释造山带的形成，高原的隆升，深源地震及其前兆的成因和金刚石及其相关岩石地壳浅部置位的机制。     

Smooth constraint inversion technique in genetic algorithms and its application to surface wave study in the Tibetan Plateau

IntroductionThe dispersion phenomena, which can be observed when surface wave travels through the Earth interior, has been extensively applied in investigating the velocity structure of the Earth interior. Usually, the dispersion curve is a nonlinear function of the thickness, S and P wave velocities and density of each layer. Because surface wave inversion is a multiple-minima problem, the result strongly depends on the initial model in traditional linear inversion. Genetic algorithm (GA) …     

黑北公路冻土路基设计原则及病害特征

依据位于小兴安岭地区的黑北公路沿线退化多年冻土特征，以及地质、水文、气候等工程环境条件，分析了黑北公路路基可能会发生的病害和发展过程，提出了适合于黑经公路的路基设计与病害防治措施，以便比选与优化退化型多年冻土地区的路基稳定性设计原则及结构形式，同时在路基设计形式和病害处理上提出了一些初步设想和建议。     

小兴安岭黑大公路沿线多年冻土分布及退化状态

黑大公路沿线多年土主要分布于黑河－北安段，属小兴安岭岛状多年冻土区，该区存在的多年冻土是晚全新世寒冷时期的产物，现处于欧亚多年冰土南界边缘，多年冻土发育在低洼、地表积水、塔头草生长茂密、草炭和泥炭发育的沼泽化湿地当中，沼泽湿地独特的热交换特性决定了其中发育的多年冻土处于退化的最晚阶段，冻土的退化在自然条件下可能依赖于由于至上的地下热流。多年冻土的地温剖面表现为零梯度曲且冰土温度接近于0℃，由此决定了多年冻土对人为活动干扰的敏感性。     

小兴安岭地区黑河-北安段多年冻土分布特征

对于寒区公路工程，查清冻土工程地质条件是至关重要的，利用地质雷达和探孔来研究多年冻土的分布，为路基设计和处理提供依据，研究结果表明，黑北段分布有17段岛状年冻土，总长度为3．165km，主要分布于沼泽化湿地、泥炭层和草炭层极为发育低洼地带、多年冻土上限约1．5－2．0m，多年冻土厚度3－6m，主要发育有多冰冻土、富冰冻土、饱冰冻土，多年冻土地温较高，热稳定性较差，多年冻土处于强烈的退化状态。     

地球物质演变的能源问题

地球发展历史是地球物质运动的过程。核转变更新着地球的化学元素与同位素组成;它影响着地球发展过程中各特殊矛盾的发展与转化。地球的能源有外来能与内生能,这两种近于相互独立而又统一的能源体系组成了地球的演化能源。我们研究和计算了各种外来能与内生能的产生方式、能量大小及对地球演化的影响,而地球演化的主要内能源是核转变能。天然核转变有两种,一种是在地球发展过程中自发产生的(核衰变、自发裂变等),一种是受外因条件所激发而产生的(诱发裂变,核反应等)。     

从岩石组合特征分析库-满坳拉谷的发育史

由于地幔柱的作用,新元古代晚期至古生代早期在塔里木板块东北部曾发育一个坳拉谷,称之为库—满坳拉谷。在库鲁克塔格和满加尔凹陷地区,从早震旦世到奥陶纪发育中酸性和基性双峰火山岩建造、深水碳酸盐岩和复理石沉积体系,具坳拉谷盆地沉积特征;志留系—石炭系具有坳陷盆地沉积特征;上石炭统—二叠系缺失;中生代发育陆相沉积体系,标志着强烈造山运动盆地隆起消亡。这些地层层序构成了典型的坳拉谷盆地沉积体系,完整地记录了库—满坳拉谷从产生至消亡的构造发育史。     

Fluxes of CO<Subscript>2</Subscript>, CH<Subscript>4</Subscript> and N<Subscript>2</Subscript>O from alpine grassland in the Tibetan Plateau

Using static chamber technique,fluxes of CO2,CH4 and N2O were measured in the alpine grassland area from July 2000 to July 2001,determinations of mean fluxes showed that CO2 and N2O were generally released from the soil,while the alpine grassland accounted for a weak CH4 sink.Fluxes of CO2,CH4 and N2O ranged widely.The highest CO2 emission occurred in August,whereas almost 90?of the whole year emission occurred in the growing season.But the variations of CH4 and N2O fluxes did not show any clear patterns over the one-year-experiment.During a daily variation,the maximum CO2 emission occurred at 16:00,and then decreased to the minimum emission in the early morning.Daily pattern analyses indicated that the variation in CO2 fluxes was positively related to air temperatures(R^2=0.73)and soil temperatures at a depth of 5 cm(R^2=0.86),whereas daily variations in CH4 and N2O fluxes were poorly explained by soil temperatures and climatic variables.CO2 emissions in this area were much lower than other grasslands in plain areas.     

CO<Subscript>2</Subscript> processes in an alpine grassland ecosystem on the Tibetan Plateau

In this paper, the CO2 concentrations profile from 1.5 m depth in soil to 32 m height in atmosphere were measured from July 2000 to July 2001 in an alpine grassland ecosystem located in the permafrost area on the Tibetan Plateau, which revealed that CO2 concentrations varied greatly during this study period. Mean concentrations during the whole experiment in the atmosphere were absolutely lower than the CO2 concentrations in soil, which resulted in CO2 emissions from the alpine steppe soil to the atmosphere. The highest CO2 concentration was found at a depth of 1.5 m in soil while the lowest CO2 concentration occurred in the atmosphere. Mean CO2 concentrations in soil generally increased with depth. This was the compositive influence of the increasing soil moistures and decreasing soil pH, which induced the increasing biological activities with depth. Temporally, the CO2 concentrations at different layers in air remained a more steady state because of the atmospheric turbulent milking. During the seasonal variations, CO2 concentrations at surface soil interface showed symmetrical patterns, with the lowest accumulation of CO2 occurring in the late winter and the highest CO2 concentration in the growine seasons.