四川黄龙沟天然水中的深源CO_2与大规模的钙华沉积

在有大规模钙华沉积的四川黄龙沟中,使用化学成分数据以及碳氧稳定同位素组成对其水文地球化学特征进行了分析研究。研究区钙华沉积的地表溪流水质基本上受到两种水混合的制约,即断层泉水和山区的融雪(冰)水。泉水中含有高浓度的经由断层提供的CO2,结果高浓度的溶解CO2使得其溶解的碳酸盐岩比普通的岩溶泉溶解的碳酸盐岩高得多,同时也导致硅酸盐岩的溶解。黄龙沟中上游的泉水相对于方解石接近于平衡。溶解无机碳(DIC)的浓度和它们的δ13C值是大约由c=0.02mol·L1δ13C=-3‰的CO2(aq)与含有δ13C=+3‰的碳酸盐岩在封闭系统条件下反应的结果。估计这些CO2中约有70%来自上地幔。所有泉水的水化学数据均落在高岭石稳定域内,但对Na长石和Ca长石具有侵蚀性。由于这些长石矿物的溶解速率太慢,所以水中的化学成分远离长石稳定域。地表溪流的DIC种类之间达到同位素平衡,在不同观测点发现的δ13CDIC变化主要是由于从水中释放出的CO2的程度不同引起的。水样的δ18O值与其采集点的海拔高度之间存在线性关系;研究区的地表溪流的氧同位素组成受到蒸发的制约。在流经钙华沉积物的地表溪流中白天和夜晚的水化学及pH的日变化表明生物作用促进了碳酸盐的沉积,尽管作用不显著。据估计研究区碳酸钙的日沉积速率是4778kg·km2,即约1mm·a1。     

新疆清水泉铜金铂钯贵金属矿床的发现及其地球化学找矿效果

在1∶500000区域化探扫面的基础上,结合景观地球化学特征,筛选出Hs 19号异常,进行1∶100000水系沉积物及1∶10000岩石测量,再经地质工程验证,最终圈定了清水泉铜金铂钯矿床。新疆阿尔金地区铜金铂钯贵金属找矿的实践证明,重视区域化探异常的筛选,进行系统的异常查证,选择最佳异常区进行地质追踪和工程揭露等,能有效缩短勘查周期及节省勘查资金。     

农桐间作的养分循环

对农桐间作（以桐为主间作型）的养分循环规律进行了研究。结果表明，泡桐各器官营养元素的含量随季节而变化。对营养元素的年吸收量为４７１．９５９５ｋｇ／ｈｍ￣２，其中氮１５５．１４２９ｋｇ／ｈｍ￣２，磷８０．０８２１ｋｇ／ｈｍ￣２，钾８７．０３９４ｋｇ／ｈｍ￣２，钙１１９．４６０３ｋｇ／ｈｍ￣２，镁３０．２３４８ｋｇ／ｈｍ￣２。营养元素的年归还量为３３１．６１５５ｋｇ／ｈｍ￣２，其中氮１０２．５７２１ｋｇ／ｈｍ￣２，磷４３．２９２２ｋｇ／ｈｍ￣２．钾６３．６４９７ｋｇ／ｈｍ￣２，钙９７．３５８６ｋｇ／ｈｍ￣２，镁２４．７４２９ｋｇ／ｈｍ￣２。营养元素的循环率为７０、２６％，其中氮６６．１１％，磷５４．０６％，钾７３．１３％，钙８１．５０％，镁８１．８４％。     

Direct-push geochemical profiling for assessment of inorganic chemical heterogeneity in aquifers

Discrete-depth sampling of inorganic groundwater chemistry is essential for a variety of site characterization activities. Although the mobility and rapid sampling capabilities of direct-push techniques have led to their widespread use for evaluating the distribution of organic contaminants, complementary methods for the characterization of spatial variations in geochemical conditions have not been developed. In this study, a direct-push-based approach for high-resolution inorganic chemical profiling was developed at a site where sharp chemical contrasts and iron-reducing conditions had previously been observed. Existing multilevel samplers (MLSs) that span a fining-upward alluvial sequence were used for comparison with the direct-push profiling. Chemical profiles obtained with a conventional direct-push exposed-screen sampler differed from those obtained with an adjacent MLS because of sampler reactivity and mixing with water from previous sampling levels. The sampler was modified by replacing steel sampling components with stainless-steel and heat-treated parts, and adding an adapter that prevents mixing. Profiles obtained with the modified approach were in excellent agreement with those obtained from an adjacent MLS for all constituents and parameters monitored (Cl, NO(3), Fe, Mn, DO, ORP, specific conductance and pH). Interpretations of site redox conditions based on field-measured parameters were supported by laboratory analysis of dissolved Fe. The discrete-depth capability of this approach allows inorganic chemical variations to be described at a level of detail that has rarely been possible. When combined with the mobility afforded by direct-push rigs and on-site methods of chemical analysis, the new approach is well suited for a variety of interactive site-characterization endeavors.     

Nitrogen and Phosphorus Cycling in Shrimp Ponds and the Measures for Sustainable Management

Six ponds of age 3 were selected 45 km north from Suzhou in the Tailake region, and research conducted on nitrogen and phosphorus cycling in P. vannanmei(Penaeus vannanme) ponds and M. nipponense(Macrobrachium nipponense) hatchery ponds under normal management. Two treatments each had three replications. The results confirmed that feed was the major path of nitrogen and phosphorus input, each accounted for 61.24%(193.81 kg ha^–1) and 81.08%(45.20 kg ha^–1) of the total nitrogen and phosphorus input for P. vannanme ponds; the values for M. nipponense ponds were 43.93%(86.31 kg ha^–1) and 57.67%(14.61 kg ha^–1), respectively. Water pumped into ponds contributed on average 83.57 kg ha^–1 nitrogen and 8.48 kg ha^–1 phosphorus for P. vannanmei ponds, and 87.48 kg ha^–1 nitrogen and 7.00 kg ha^–1 phosphorus for M. nipponense hatchery ponds. Shrimp harvest recovered 102.81 kg ha^–1 nitrogen (32.94% of the total nitrogen input) and 7.94 kg ha^–1phosphorus (14.23% of the total phosphorus input) for P. vannanme ponds; and 43.94 kg ha^–1 nitrogen and 4.46 kg ha^–1phosphorus for M. nipponense hatchery ponds. The sum of nitrogen losses through volatilization, denitrification and sedimentation was 173.62 and 122.39 kg ha^–1, 54.86% and 62.29% of the total nitrogen input for P. vannanme ponds and M. nipponense hatchery ponds, respectively. Sediment accumulated 41.46 and 14.63 kg ha^–1 phosphorus, 74.37% and 64.85% of the total phosphorus input for P. vannanm ponds and M. nipponense hatchery ponds. Draining and seeping caused 40.06 kg ha^–1 nitrogen (12.66% of total nitrogen input) and 6.36 kg ha^–1 phosphorus (11.40% of total phosphorus input) loss to the surrounding water from P. vannanme ponds in 114 days; 30.14 kg ha^–1nitrogen (15.34% of the total input) and 4.45 kg ha^–1 phosphorus (17.57% of the total input) to channel water from M. nipponense hatchery ponds in 87 days, respectively. Countermeasures for sustainable pond management include improving feeds and feeding, sediment treatments, machine aerating, chemicals with no pollution, and integrated fish-shrimp cultivation. Management of water resources for pond and methods to reduce nitrogen and phosphorus loading into surrounding water from drainage are elucidated.     

星星峡地区构造地球化学特征的初步研究

对位于板块构造边缘的星星峡地区的基本构造单元进行了构造地球化学分带，研究了该地区不同类型岩浆岩微量元素的演化规律和所展构遣对元素空间分布的控制，发现矿床规模与断裂构造复合组数具有正相关关系。     

中国环境中氮循环的动态模式

对中国960万km~2范围内氮的生物地球化学循环作了初步探讨。该工作建立在对大气、土、生物及水圈界面氮的流通量的研究基础上,以数学方式模拟氮的生物地球化学循环规律,并预测各圈中氮的库存量和流通量的变化趋势。经过验证,模式的收敛性、稳定性及可信度均是好的。     

银山多金属矿床成矿流体稀土元素地球化学

对江西银山矿床规模不同的矿体、蚀变围岩及其原岩的稀土元素特征进行了对比研究。结果表明 ,成矿流体的稀土元素以轻稀土富集型 ,无Ce异常 ,强烈的Eu正异常而显著地区别于赋矿围岩。热液蚀变作用造成围岩的稀土总量升高 12 .1%～ 5 2 .4%,轻重稀土比值降低 ,但紧邻矿体的稀土含量则低于原岩。导致围岩稀土总量升高有两个因素 :(1)通过热液蚀变作用带入了稀土元素 ;(2 )体系主元素 (Si)质量迁移而造成稀土元素出现表观浓缩。其中以前者为主导因素。矿体的接触带及其紧邻处的蚀变围岩的REE含量明显偏低 ,主要因出现大量石英或石英 +硫化物等矿物的显微脉体 (脉幅 3～ 8μm)而被稀释 ,是一种表观亏损现象。研究结果表明 ,矿体越大 ,其围岩REE被“稀释”越明显 ,涉及的范围越大 ,REE特征可能是一种潜在有效的找矿勘探地球化学指标。     

煤炭开发影响地下水资源环境研究一例--平顶山市石龙区贫水化的原因分析

研究了石龙区大规模煤炭开发40余年来地下水水位和水化学场的变化及其原因。从地下水资源量和地下水水质两个方面探讨煤矿开采对本区水资源环境的破坏机理，为矿区生态环境综合整治提供依据。