砂岩型铀矿找矿中土壤氢气测量方法影响因素研究

放射性元素衰变过程中水辐解会产生大量氢气,而氢气质量轻、迁移快的特点使其在地表就能够被探测到异常,进而能够指导铀矿找矿工作。在已知的巴音戈壁盆地塔木素砂岩型铀矿床、二连盆地巴润砂岩型铀矿床和图门勘探区开展了土壤氢气测量试验研究,从测孔深度、孔闲置时间、测量点距、气体动态平衡情况、最佳采集时间等方面分析了土壤氢气测量方法对铀矿勘查的影响,经与已知地质资料和钻孔资料对比分析得出结论:铀矿化程度、厚度及埋深情况与地表氢气浓度异常呈正相关关系,矿化程度越高、厚度越大、埋深越浅则土壤氢气浓度越高;断裂构造上方均有较好的土壤氢气异常显示,且土壤氢气浓度异常受断裂宽度、断裂含矿或不含矿等因素影响较大;总结了一套有效可行的土壤氢浓度采集方案和工作方法,为铀矿找矿工作提供了新思路和新方法。

断层带土壤氢气浓度测量及其影响因素

利用ATG-300H型便携式测氢仪,分别在昌平地区、海原断裂带、北轮台断裂开展土壤氢气浓度测量。基于气体扩散方程,从采样器类型、测孔深度、土壤特性、断层作用等方面探讨氢气浓度测量的影响因素与机理。结果显示:1)土壤氢气浓度值受测孔闲置时间、测孔深度和采样器形状的影响较大;2)氢气浓度测值与气体扩散方程的理论解曲线吻合较好,其曲线形态主要与土壤中氢气的富集程度和土壤疏松程度密切相关;3)断层带上的氢气浓度受构造作用、断层滑动速率、断层闭锁程度、上下盘裂隙发育程度、裂隙开启或闭合状态等因素影响较大,这些因素主要影响深部氢气的向上迁移通道和在地表的富集程度。

断层土壤氢气的特征

随着利用地表土壤气体组分特征研究活断层方法的兴起，笔者在黄土覆盖层巨厚的陕西关中盆地几条断裂上，进行了土壤气测试特别是测氢的尝试，测试的结果表明：氢气醒目地分布在断裂带的两侧或微裂缝区，远离时则尖灭．因此用测试断层土壤氢气法来寻找隐伏断裂、判断活断层的位置及走向是一种行之有效的方法。

松辽盆地主要发震构造土壤氢气地球化学特征

松辽盆地中部地质构造发育、断裂纵横交错,历史上曾发生多次强烈地震,其中扶余-肇东断裂、呼兰河断裂是松辽盆地内部主要发震构造.气体地球化学对地下物理化学条件改变响应灵敏,是指示地震和构造活动的有效指标,在地震短临预测、地震前兆研究以及构造活动分析中占据着重要的地位.通过在扶余-肇东断裂、呼兰河断裂的次级断裂——绥化-蒙古山断裂开展土壤氢气测量,发现活动断裂破碎带附近土壤氢气出现显著变化特征.结果表明:①扶余-肇东断裂各测线氢气异常阈值浓度比为1.8~2.3,异常峰值浓度比为3.0~6.4.②绥化-蒙古山断裂各测线氢气异常阈值浓度比为1.8~2.5,异常峰值浓度比为3.5~5.7.③对比异常衬度曲线发现,扶余-肇东断裂背景浓度、异常阈值、峰值浓度均明显高于绥化-蒙古山断裂,这与扶余-肇东断裂近年来地震活动显著活跃有关,可能包含了地震前构造活动增强的信息.④活动断裂破碎带附近土壤氢气显著变化,可能与两条断裂性质、地质构造单元、局部应力环境和断裂构造活动强弱等有关.

黑龙江中西部跨断层土壤氢气初步分析

地质构造运动多伴随地下气体的逸出,观测并研究地下逸出气体,会抓住某些地下构造活动信息。作为地球化学观测的灵敏指标之一,地下逸出的氢气能够指示断裂活动的过程。地处松辽盆地黑龙江中西部地区多年来已开展多期跨断层土壤氢气野外测量工作,利用积累的观测数据,初步分析该地区跨断层土壤氢气背景动态变化及构造活动、地震活动特征,以便为地震孕育过程中断层氢气演化异常判定提供依据,为建立区域地震短期预测动态方法提供思路。

Effects of Elevated CO_2 and Drought on Plant Physiology, Soil Carbon and Soil Enzyme Activities

Global climate models have indicated high probability of drought occurrences in the coming future decades due to the impacts of climate change caused by a mass release of CO2. Thus, climate change regarding elevated ambient CO2 and drought may consequently affect the growth of crops. In this study, plant physiology, soil carbon, and soil enzyme activities were measured to investigate the impacts of elevated C02 and drought stress on a Stagn[c Anthrosol planted with soybean （Glycine ma,z）. Treatments of two CO2 levels, three soil moisture levels, and two soil cover types were established. The results indicated that elevated CO2 and drought stress significantly affected plant physiology. The inhibition of plant physiology by drought stress was mediated via prompted photosynthesis and water use efficiency under elevated CO2 conditions. Elevated CO2 resulted in a longer retention time of dissolved organic carbon （DOC） in soil, probably by improving the soil water effectiveness for organic decomposition and mineralization. Drought stress significantly decreased C：N ratio and microbial biomass carbon （MBC）, but the interactive effects of drought stress and CO2 on them were not significant. Elevated CO2 induced an increase in invertase and catalase activities through stimulated plant root exudation. These results suggested that drought stress had significant negative impacts on plant physiology, soil carbon, and soil enzyme activities, whereas elevated CO2 and plant physiological feedbacks indirectly ameliorated these impacts.