北江流域水化学时空变化及化学风化特征

为了研究我国南方湿润地区河流水化学时空变化特征及控制因素,选择珠江流域第二大水系的北江为研究对象,通过分析2015年6月（汛期）和12月（非汛期）干流和支流河水基本水质参数及主量离子,利用化学计量法及质量守恒法定量评估了自然过程及人类活动共同影响下的流域化学风化特征及其通量.结果表明:①北江河水主量离子浓度非汛期高于汛期.岩石的区域分布和矿山活动构成了河水离子浓度和水化学类型的空间异质性,其中北江干流和支流连江为Ca-HCO₃型,而支流滃江则以Ca-SO₄型为主.②岩石对北江流域化学风化贡献率依次为碳酸岩（78.44%）>硅酸岩（14.43%）>降水源（5.42%）>蒸发岩（1.71%）.基于碳酸岩是北江径流水化学的主要控制因素,滃江流域的矿山开采活动加速了碳酸岩的风化,其对北江流域化学风化的贡献为7%.③汛期与非汛期的碳酸岩风化速率分别为7.49和5.29 t/（km2·月）,年化学风化速率为87.63 t/（km2·a）.研究显示,由于受水热条件、流域面积以及岩性的影响,北江流域年化学风化速率略大于西江流域,远高于东江以及全球流域化学风化平均值,北江对整个珠江流域的风化贡献较大.      

有机物料对土壤中水溶性氟环境效应的影响

土壤是固、液、气三相共存体,氟在土-水-植物、动物界面的转化可通过土壤水溶性氟含量表征。试验选用典型贵州黄壤和石灰土,运用有机质进行土壤污染修复的机理,通过向模拟高氟污染土壤中添加有机物料泥炭和风化煤,采用两因素最优设计,研究两种有机物料对土壤中水溶性氟含量的影响。结果表明,泥炭和风化煤都能降低土壤中水溶性氟含量,且泥炭的处理效果更好,最佳添加量是1.258g·kg-1。同时表明,黄壤和石灰土环境下氟形态转化的化学机理不同,运用有机质修复氟污染黄壤添加适量就可达到理想效果,而氟污染石灰土还存在其它更直接有效的方法改变氟在石灰土环境下的形态及其活性。     

东南沿海中生代安山岩的地质意义

在中国东部大陆边缘中生代火山岩带中 ,东南沿海火山岩岩性岩相出露最全 ,火山地质调查研究程度较高。以往的研究主要集中于大面积酸性火山岩和与之共生的玄武岩 ,而对安山岩注意不够。作为过渡性岩类 ,安山岩的成因研究对于探讨中生代火山岩带物质来源、岩浆分异演化、大地构造背景等具有不可替代的作用。近年来在东南沿海新生代玄武岩中陆续发现了一些基性麻粒岩包体 ,为研究底侵作用与壳幔作用过程提供了珍贵的实物材料。结合基性麻粒岩包体的研究 ,进行系统的安山岩成因研究 ,对于研究中生代火山岩带成因、进而探讨东部大陆边缘形成演化动力学过程 ,具有重要意义     

Precipitation and aerosol studies in India

In India, rain water and atmospheric aerosols are observed to bealkaline in nature due to the influence of soil-derivedparticles which are rich in components like Ca and Mg. Thesecomponents increase the neutralization potential of rain waterand have a greater influence at rural site compared to urbansite. However, if there are continuous rains, the concentrationof crustal components becomes lower resulting in lower pH ofrain water. Unlike the characteristics of rain water oncontinent, the pH of rain water has been observed to be acidicin all the events over the Indian Ocean during Pre-campaigns ofIndian Ocean Experiment (INDOEX). The possible reason for acidicrains over Indian Ocean could be the anthropogenic contributionfrom continent transported by NE winds coming towards the oceanduring this period.     

Towards Real‐Time Continental Scale Streamflow Simulation in Continuous and Discrete Space

The National Weather Service (NWS) forecasts floods at approximately 3,600 locations across the United States (U.S.). However, the river network, as defined by the 1:100,000 scale National Hydrography Dataset‐Plus (NHDPlus) dataset, consists of 2.7 million river segments. Through the National Flood Interoperability Experiment, a continental scale streamflow simulation and forecast system was implemented and continuously operated through the summer of 2015. This system leveraged the WRF‐Hydro framework, initialized on a 3‐km grid, the Routing Application for the Parallel Computation of Discharge river routing model, operating on the NHDPlus, and real‐time atmospheric forcing to continuously forecast streamflow. Although this system produced forecasts, this paper presents a study of the three‐month nowcast to demonstrate the capacity to seamlessly predict reach scale streamflow at the continental scale. In addition, this paper evaluates the impact of reservoirs, through a case study in Texas. Validation of the uncalibrated model using observed hourly streamflow at 5,701 U.S. Geological Survey gages shows 26% demonstrate PBias ≤ |25%|, 11% demonstrate Nash‐Sutcliffe Efficiency (NSE) ≥ 0.25, and 6% demonstrate both PBias ≤ |25%| and NSE ≥ 0.25. When evaluating the impact of reservoirs, the analysis shows when reservoirs are included, NSE ≥ 0.25 for 56% of the gages downstream while NSE ≥ 0.25 for 11% when they are not. The results presented here provide a benchmark for the evolving hydrology program within the NWS and supports their efforts to develop a reach scale flood forecasting system for the country.     

LDPE/EPDM Multilayer Films Containing Recycled LDPE for Greenhouse Applications

In this paper the reuse of recycled LDPE in combination with the incorporation of EPDM modifier in the production of greenhouse films has been investigated. A three-layer film (60-100-40 micron thickness) containing recycled LDPE in the middle layer and a high UV-stabilized 40-micron outer layer was developed and proven to be commercially successful. Films with 25% and 50% recycled material content were produced. The effect of natural weathering on the film properties over a period of 15 months has been observed. Changes in physical and mechanical property were determined. The addition of EPDM to the raw resin was found to improve the extrudability of the compound and improve the weather resistivity of the film. The EPDM-modified films containing 25% to 50% recycled material retained approximately 95% and 75%, respectively, of their original extensibility after 9 months' exposure to natural weathering. Optimization of EPDM and UV stabilizer concentration was carried out to develop a balanced film with excellent mechanical and physical properties and resistance to weathering conditions. The use of UV stabilizer concentrations slightly higher than commercial practice in the outer layer of the multilayer film can be justified by the cost reduction by the incorporation of recycled LDPE materials.     

乌江流域沉积岩风化过程中铀的富集与释放

以乌江流域石灰岩、白云质灰岩、白云岩、硅质岩、黑色页岩和紫色砂岩等典型岩石的13条风化剖面为对象,运用相关分析和质量平衡计算方法,研究了这些岩石风化过程中铀(U)的富集与释放及其对河水U分布的影响,旨在增进对U生物地球化学循环的了解,也为流域U污染防治提供依据.结果表明,①乌江流域风化物和土壤中U的富集程度基本上高于上陆壳(upper continental crust,UCC)、中国土壤(China soil,CS)和世界土壤(world soil,WS);②U的富集和释放能力与母岩U含量以及风化剖面中粘土矿物和铁氧化物/氢氧化物含量及吸附能力有关;③石灰岩以及少量白云岩和碎屑岩风化过程中U的释放对河水U的分布特征具有重要的控制作用.     

黔中白云岩风化剖面微量元素的地球化学特征

本研究是为了探讨微量元素在化学风化作用下的迁移特征及分布规律并讨论碳酸盐岩地区红色风化壳的物源问题。我们选择了贵州省遵义市新浦镇的一处发育完好的原生白云岩上覆红土剖面作为研究的对象。以Zr作为不活化元素,我们得到以下的认识:1)该白云岩上覆红土剖面是原地形成的淋滤剖面,微量元素的迁移系数在红土剖面中的变化都具有很好的规律性。元素对Nb-Ta、Zr-Hf和Y-Yb的相关性很强,其可以作为上覆土层物质非多来源的证据,而单一物源与下伏岩石高度相关,那么可以推断所研究的土壤来源于下覆碳酸盐岩的风化。2)在整个剖面中,大部分微量元素在风化过程中都表现出富集的特性,尤其在岩-土界面处达到最大化,这显示出了风化淋滤的过程。Nb、Ta、V和Hf是相对不活化的元素。3)轻稀土元素在岩土界面的富集系数是大于重稀土元素的,这表明轻稀土元素在淋滤过程中更易于迁移。此外,铁质壳对相关微量元素有着富集的作用。总之,本次的研究结果对探讨喀斯特地区红土型风化壳的物质来源问题有着重要的指示意义。     

环境污染加剧石质文物风化:机理、过程及防护措施

石质文物的风化问题由来已久,在影响石质文物风化的各类因素中,环境恶化对石质文物的风化影响日益严重,但现有研究大多忽略了环境污染加剧的影响。在此背景下,本文从酸性气体排放、温度效应和水体污染三个方面阐述了环境污染加剧对石质文物风化的影响和作用机理,并对现有石质文物的防护措施进行综合比较分析,提出石质文物的保护建议和措施,为新形势下石质文物的保护研究提供新的思路。     

韩江流域河水地球化学特征与硅酸盐岩风化——风化过程硫酸作用

流域岩石化学风化是全球碳循环的重要环节之一,硅酸盐岩风化过程消耗大气CO_2,是在地质时间尺度上调节大气CO_2浓度的重要机制。本工作在对我国东南花岗岩地区流经典型的硅酸盐岩地质背景河流——韩江流域河流水化学组成研究的基础上,分析和定量计算了河流水体主要物质来源,并对硫酸参与岩石风化和碳循环过程的作用进行了分析,进而对韩江流域岩石风化速率及其大气CO_2消耗通量进行了估算。结果表明,韩江流域河流主离子组成主要来源于硅酸盐岩和碳酸盐岩风化,并计算得出约41%的硫酸根离子来自于大气降水;流域碳酸盐岩的风化速率为21.7 t/(km~2·a),硅酸盐岩为18.9 t/(km~2·a)。硫酸参与岩石风化提供的离子贡献占流域岩石风化提供总离子量的65.9%;流域风化带来的CO_2消耗速率被高估了约61%。