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1.
The generation of acid rock drainage (ARD) is a biogeochemical process that causes severe ecological impacts, threatening human health worldwide. Microbes involved in acid drainage reactions are generally considered autotrophic but heterotrophic and mixotrophic microorganisms have often been identified at ARD sites. This raises questions about the role of organic matter naturally present at these sites, such as mature hydrocarbons, in promoting the microbial processes underpinning ARD generation. To investigate this, aerobic microcosm experiments were carried out using ARD samples collected at a well-characterised site in northern England (Mam Tor, Derbyshire). Organic analyses indicated the presence of substantial amounts of mature, petroleum-derived hydrocarbons and microbial analyses indicated that the sediment hosts acidophilic bacteria with the capability of degrading petroleum-derived compounds. However, the aerobic microcosm experiments indicated that these petroleum-derived hydrocarbons were not used by the bacterial community and, therefore, are not involved in the reactions that ultimately lead to ARD generation. These observations support a primary role for autotrophs in ARD generation. 相似文献
2.
Potential application of oxygen-18 and deuterium in mining effluent and acid rock drainage studies 总被引:2,自引:0,他引:2
Oxygen-18 (18O) and deuterium (D, or 2H) are routinely used in hydrologic, climatologic and geothermal studies. In hydrology, stable isotopes provide information
on the type and topology (altitude and latitude) of the recharge waters and the historical effects on water, related to such
physical processes as evaporation (in ponds), melting (of snow or ice), condensation, evapotranspiration and mixing. In geothermal
studies, stable isotopes provide key information related to recharge and the various temperature-dependent water/rock isotope
exchange reactions. The latter is assessed through the oxygen shift in the 18O/D correlation. At acid rock drainage (ARD) sites, water/rock interactions are primarily controlled by pH and oxidation potential.
Using the isotopic characteristics of the rocks and the recharge waters as a basis, the relative oxygen shift of the ARD effluent
can provide information on: (1) the residence time, (2) the rate of water/rock reactions, and (3) the actual pH at the rock/water
interface. This paper offers a methodology for conducting oxygen and hydrogen isotope studies related to ARD and other mineral
effluent problems. The methodology is based on: (1) comprehensive sampling of regional waters, ARD effluent and major contributing
minerals and rocks, (2) isotopic and elemental analysis, and (3) data interpretation on the basis of a zero-dimensional (mass
balance), multi-component mixing model.
Received: 15 January 1999 · Accepted: 3 May 1999 相似文献
3.
Sampling acid mine drainage (AMD) or natural acid rock drainage (ARD)-impacted sediments is complex, requiring appropriate
field sampling techniques to ensure representative samples that are both repeatable and reproducible. The important factors
affecting sampling of riverine sediments are examined. These include sample site location, field observations, representative
sampling, sample collection techniques, and sample preservation. A recommended sampling and processing protocol is presented
for AMD- and ARD-impacted riverine sediments, which includes sediment sampling, Fe hydroxide floc sampling, chemical analysis,
interstitial (pore) water collection, sediment elutriates, sediment fractionation, and physical analysis. The importance of
bioassay testing is discussed, as is quality assurance and assessment approaches to define sediment quality criteria.
Received: 18 September 1995 · Accepted: 23 October 1995 相似文献
4.
The determination of neutralization potential (NP) of mining wastes is an essential part of waste characterization for acid
rock drainage (ARD) prediction. Interpretation of NP values requires consideration of the mineralogical composition of the
waste. Different minerals can neutralize acid drainage at different rates and in different pH ranges. The test conditions
of widely used laboratory procedures to determine NP do not distinguish between such differences and overestimation of NP
can often result. A simple procedure is proposed in which the effective NP is calculated based on mineralogical composition
and the relative reactivities of component minerals. Mineralogical composition is calculated from easily determined analytical
values using a CIPW normative procedure. Comparison of calculated NP values for 92 samples with experimentally determined
values from tests designed to prevent the overestimation of NP indicates that the method is successful in predicting an effective
NP value in most cases. The procedure is considered to be a cost-effective means of providing confident routine ARD prediction
when used in combination with other tests and analyses.
Received: 1 August 1996 / Accepted: 11 November 1996 相似文献
5.
Prediction of acid mine drainage generation potential in selected mines in the Ashanti Metallogenic Belt using static geochemical methods 总被引:1,自引:1,他引:1
Acid mine/rock drainage (AMD/ARD) is the biggest environmental threat facing the mining industry. This study investigates
AMD/ARD possibilities in three mines in the Ashanti Belt, using acid base accounting (ABA) and net acid generation pH (NAGpH)
tests. Twenty-eight samples of rock units and mine spoil from these mines were collected for ABA and NAGpH tests. Two tailing
dumps at Prestea and Nsuta were confirmed by both methods as acid generating with NAGpH of 4.5 and 4.6 and neutralization
potential ratio values of 4.38 and 4.60, respectively. Six other samples are classified as potentially acid generating using
a variety of established classification criteria. The rest of the samples either exhibited very low sulphur and carbonate
content or had excess carbonate over sulphur. Consistency between results from ABA and NAGpH tests validates these tests as
adequate tools for preliminary evaluation of AMD/ARD possibilities in any mining project in the Ashanti Belt. 相似文献
6.
Sang Woo Ji Young Wook Cheong Gil Jae Yim Jayanta Bhattacharya 《Environmental Geology》2007,52(6):1033-1043
Acid rock drainage (ARD) is a longstanding problem often associated with the resulting corrosion due to the acidity generated
from sulfidic oxidation. To evaluate characteristics of ARD and corrosion, samples from the road side rock mass of Boeun and
Mujoo were analysed using X-ray diffraction, acid/base accounting and Leaching tests. The results indicated that many samples
had a pyritic origin and can be regarded as acid-generating rocks. The Leaching test showed that the average pH of the leachates
of samples from both Boeun and Mujoo were moderately acidic, ranging from 3 to 4. Interestingly, as acidity increases from
pH 4, the SO4−, Fe, Al and Mg concentrations increase abnormally. Samples from roadside slope of Mujoo showed high corrosive potential.
Maximum sulfide oxidation rate of a sample taken from Mujoo was as high as 5,166 mg/kg/week. 相似文献
7.
Dissolution of jarosite [KFe3(SO4)2(OH)6] at pH 2 and 8: Insights from batch experiments and computational modelling 总被引:1,自引:0,他引:1
Adrian M.L. Smith Karen A. Hudson-Edwards William E. Dubbin 《Geochimica et cosmochimica acta》2006,70(3):608-621
Jarosite [KFe3(SO4)2(OH)6] is a mineral that is common in acidic, sulphate-rich environments, such as acid sulphate soils derived from pyrite-bearing sediments, weathering zones of sulphide ore deposits and acid mine or acid rock drainage (ARD/AMD) sites. The structure of jarosite is based on linear tetrahedral-octahedral-tetrahedral (T-O-T) sheets, made up from slightly distorted FeO6 octahedra and SO4 tetrahedra. Batch dissolution experiments carried out on synthetic jarosite at pH 2, to mimic environments affected by ARD/AMD, and at pH 8, to simulate ARD/AMD environments recently remediated with slaked lime (Ca(OH)2), suggest first order dissolution kinetics. Both dissolution reactions are incongruent, as revealed by non-ideal dissolution of the parent solids and, in the case of the pH 8 dissolution, because a secondary goethite precipitate forms on the surface of the dissolving jarosite grains. The pH 2 dissolution yields only aqueous K, Fe, and SO4. Aqueous, residual solid, and computational modelling of the jarosite structure and surfaces using the GULP and MARVIN codes, respectively, show for the first time that there is selective dissolution of the A- and T-sites, which contain K and SO4, respectively, relative to Fe, which is located deep within the T-O-T jarosite structure. These results have implications for the chemistry of ARD/AMD waters, and for understanding reaction pathways of ARD/AMD mineral dissolution. 相似文献
8.
《Applied Geochemistry》2004,19(7):1075-1084
The biogeochemical cycling of Fe in acid rock drainage (ARD) streams has presented ongoing challenges to reactive solute transport modeling. Previous studies have relied on the pH-dependent solubility of Fe oxides as the main control of the mid-day Fe(II) maxima concentration in ARD streams. In this study, the authors assess the potential for Fe(II)-oxidizing reactions, including the Fenton and microbial oxidation reactions, to constrain the mid-day Fe(II) maxima concentration. At mid-day, pseudo-equilibrium between Fe(II) oxidizing reactions and photoreduction was assumed in order to evaluate the observed Fe(II) maxima and develop an equation to represent this steady state scenario. This steady state condition is assumed only while light intensity, reactivity of oxides and dissolved organic matter (DOM), and microbial populations remain approximately constant. Three Rocky Mountain ARD streams with known values for Fe(II) were evaluated and average photoreduction rates ranging from 5.56×10−4 to 1.39×10−3 μM/s were found during mid-day steady state Fe(II) maxima. Application of Fe redox biogeochemistry to reactive solute transport modeling may improve predictive capabilities of various trace metal and solute interactions incorporated with the cycling of Fe within ARD streams. Further, model improvement of Fe cycling may enable more accurate remediation predictions for ARD streams. 相似文献
9.
《Applied Geochemistry》2002,17(5):633-648
Acid rock drainage (ARD) solution from an abandoned ore mine (pH 2.7, SO2−4 concentration 411 mmol/l, Fe concentration 93.5 mmol/l) was investigated by photon correlation spectroscopy, centrifugation, filtration, ultrafiltration, scanning electron microscopy, ICP–MS, AAS, ion chromatography, TOC analysis, and extended X-ray absorption fine structure (EXAFS) spectroscopy. A colloid concentration of ⩾1 g/l was found. The prevailing particle size was <5 nm. Iron, As and Pb were the metal constituents of the colloidal particles. The most probable mineralogical composition of the particles is a mixture of hydronium jarosite and schwertmannite. A small amount of a relatively coarse precipitate was formed in the ARD solution during the months after sampling. The colloid particles are obviously an intermediate in the precipitate formation process. The results suggest that the arsenate is bound to the colloids by the formation of a bidentate binuclear inner-sphere surface complex. However, the transformation of the colloidal material to the more aggregated long-term precipitate results in the incorporation of the arsenate into the interior of the Fe hydroxy sulfate crystal structures. Lead seems to occur as anglesite. 相似文献
10.
In earth and environmental sciences applications, uncertainty analysis regarding the outputs of models whose parameters are spatially varying (or spatially distributed) is often performed in a Monte Carlo framework. In this context, alternative realizations of the spatial distribution of model inputs, typically conditioned to reproduce attribute values at locations where measurements are obtained, are generated via geostatistical simulation using simple random (SR) sampling. The environmental model under consideration is then evaluated using each of these realizations as a plausible input, in order to construct a distribution of plausible model outputs for uncertainty analysis purposes. In hydrogeological investigations, for example, conditional simulations of saturated hydraulic conductivity are used as input to physically-based simulators of flow and transport to evaluate the associated uncertainty in the spatial distribution of solute concentration. Realistic uncertainty analysis via SR sampling, however, requires a large number of simulated attribute realizations for the model inputs in order to yield a representative distribution of model outputs; this often hinders the application of uncertainty analysis due to the computational expense of evaluating complex environmental models. Stratified sampling methods, including variants of Latin hypercube sampling, constitute more efficient sampling aternatives, often resulting in a more representative distribution of model outputs (e.g., solute concentration) with fewer model input realizations (e.g., hydraulic conductivity), thus reducing the computational cost of uncertainty analysis. The application of stratified and Latin hypercube sampling in a geostatistical simulation context, however, is not widespread, and, apart from a few exceptions, has been limited to the unconditional simulation case. This paper proposes methodological modifications for adopting existing methods for stratified sampling (including Latin hypercube sampling), employed to date in an unconditional geostatistical simulation context, for the purpose of efficient conditional simulation of Gaussian random fields. The proposed conditional simulation methods are compared to traditional geostatistical simulation, based on SR sampling, in the context of a hydrogeological flow and transport model via a synthetic case study. The results indicate that stratified sampling methods (including Latin hypercube sampling) are more efficient than SR, overall reproducing to a similar extent statistics of the conductivity (and subsequently concentration) fields, yet with smaller sampling variability. These findings suggest that the proposed efficient conditional sampling methods could contribute to the wider application of uncertainty analysis in spatially distributed environmental models using geostatistical simulation. 相似文献
11.
基于组合核函数的高斯过程边坡角智能设计 总被引:2,自引:0,他引:2
高斯过程(GP)是近年来发展迅速的一种全新学习机。与支持向量机(SVM)相比,该方法有着容易实现、超参数可自适应获取及预测输出具有概率意义等优点。结合边坡工程中的边坡角设计,编写了在多种因素影响下边坡角设计的GP程序,为克服单一核函数预测精度和网络泛化能力差的缺点,采用单一核函数相加作为GP的组合核函数,将自动关联性测定参数(ARD)引入其中,建立了关于超参数的GP回归网络模型,使用共轭梯度下降算法导出最优超参数,用ARD超参数进行输入属性相关性分析和特征选取,并以此网络对测试样本进行学习预测,结合支持向量回归方法给出了在回归问题上的应用和对比分析。结果表明:在边坡角智能设计应用中,采用组合核函数的GPR网络ARD参数具有明确的物理意义,预测回归性能优于SVM,且预测输出的概率解释能更好的体现预测值的代表性,为边坡角设计开辟新径。 相似文献
12.
Stephen A. Bortone 《Estuaries and Coasts》2006,29(6):1062-1066
Scientists along the Gulf of Mexico and southeastern United States inevitably are asked to investigate the environmental effects
of such extreme natural events as hurricanes. Since the usual post-event sampling strategy is often based upon the application
of a pre-event study design that was not originally intended to evaluate disturbance effects, a hurricane evaluation strategy
is needed that establishes sampling coverage through a broad network. Coupling this evaluation strategy with the refinement
of serval estuarine indicators to assess environmental change will facilitate the evaluation of hurricane effects. Establishing
the sampling network and concomitant protocols requires cooperation among scientists and agencies. Fortunately, the number
and location of existing laboratories and investigations into establishing estuarine indicators is at hand. Developing a sampling
network and protocols will better enable scientists to evaluate the effects of short-term, focused, and intense environmental
disruptions. 相似文献
13.
The net result of acid-generating and-neutralizing reactions within mining wastes is termed acid rock drainage (ARD). The oxidation of sulfide minerals is the major contributor to acid generation. Dissolution and alteration of various minerals can contribute to the neutralization of acid. Definitions of alkalinity, acidity, and buffer capacity are reviewed, and a detailed discussion of the dissolution and neutralizing capacity of carbonate and silicate minerals related to equilibium conditions, dissolution mechanism, and kinetics is provided. Factors that determine neutralization rate by carbonate and silicate minerals include: pH, PCO
2, equilibrium conditions, temperature, mineral composition and structure, redox conditions, and the presence of foreign ions. Similar factors affect sulfide oxidation. Comparison of rates shows sulfides react fastest, followed by carbonates and silicates. The differences in the reaction mechanisms and kinetics of neutralization have important implications in the prediction, control, and regulation of ARD. Current static and kinetic prediction methods upon which mine permitting, ARD control, and mine closure plans are based do not consider sample mineralogy or the kinetics of the acid-generating and-neutralizing reactions. Erroneous test interpretations and predictions can result. The importance of considering mineralogy for site-specific interpretation is highlighted. Uncertainty in prediction leads to difficulties for the mine operator in developing satisfactory and cost-effective control and remediation measures. Thus, the application of regulations and guidelines for waste management planning need to beflexible. 相似文献
14.
The presence of fecal coliform bacteria in many watersheds is often linked to septic system effluent. Fluorescent whitening agents (FWA) are part of most laundry detergent formulations and previously have been used for fingerprinting anthropogenic sewage waters. This study was carried out to investigate the fate of FWA in spring water downstream from a well-monitored septic system in a small forest watershed. Samples for FWA were collected at the spring and along the flow path downstream and analyzed fluorometrically. Selected sampling events were scheduled at night and daytime and after rainstorms to investigate possible changes in the spring water composition. In addition, reference fluorescence spectra were prepared for humic and tannic acid and for the laundry detergent used exclusively in the household discharging into the test septic system. The results indicate that FWA can be detected in spring water, but interference with increasing humic acid concentration downstream limits the fingerprinting value of the method to the vicinity of the spring. Also, sampling for FWA after rainstorms only yielded results if at least 4 days had passed. Otherwise, dissolved organic substances transported into the spring water interfered with the FWA spectrum. No significant differences between night and daytime sampling were found. Overall, the method, as used at this study site, is of limited value for fingerprinting FWA in natural waters. 相似文献
15.
Lead- and Pb-As-jarosites are minerals common to acidic, sulphate-rich environments, including weathering zones of sulphide ore deposits and acid rock or acid mine drainage (ARD/AMD) sites, and often form on or near galena. The structures of these jarosites are based on linear tetrahedral-octahedral-tetrahedral (T-O-T) sheets, comprised of slightly distorted FeO6 octahedra and SO42− (-AsO43− in Pb-As-jarosites) tetrahedra. To better understand the dissolution mechanisms and products of the break down of Pb- and Pb-As-jarosite, preliminary batch dissolution experiments were conducted on synthetic Pb- and Pb-As-jarosite at pH 2 and 20 °C, to mimic environments affected by ARD/AMD, and at pH 8 and 20 °C, to simulate ARD/AMD environments recently remediated with slaked lime (Ca(OH)2). All four dissolutions are incongruent. Dissolution of Pb-jarosite at pH 2 yields aqueous Pb, Fe and SO42−. The pH 8 Pb-jarosite dissolution yields aqueous Pb, SO42− and poorly crystalline Fe(OH)3, which does not appear to resorb Pb or SO42−, possibly due to the low solution pH (3.44-3.54) at the end of the experiment. The pH 2 and 8 dissolutions of Pb-As-jarosite result in the formation of secondary compounds (poorly crystalline PbSO4 for pH 2 dissolution; poorly crystalline PbSO4 and Fe(OH)3 for pH 8 dissolution), which may act as dissolution inhibitors after 250 to 300 h of dissolution. In the pH 2 dissolution, aqueous Fe, SO42− and AsO43− also form, and in the pH 8 dissolution, Fe(OH)3 precipitates then subsequently resorbs aqueous AsO43−. The dissolutions probably proceed by preferred dissolution of the A- and T-sites, which contain Pb, and SO42− and AsO43−, respectively, rather than Fe, which is sterically remote, within the T-O-T Pb- and Pb-As-jarosite structures. These data provide the foundation necessary for further, more detailed investigations into the dissolution of Pb- and Pb-As-jarosites. 相似文献
16.
Using sewage sludge as a sealing layer to remediate sulphidic mine tailings: a pilot-scale experiment, northern Sweden 总被引:1,自引:0,他引:1
At the Kristineberg mine, northern Sweden, sulphidic mine tailings were remediated in an 8-year pilot-scale experiment using sewage sludge to evaluate its applicability as a sealing layer in a composite dry cover. Sediment, leachate water, and pore gas geochemistry were collected in the aim of determining if the sludge was an effective barrier material to mitigate acid rock drainage (ARD) formation. The sludge was an effective barrier to oxygen influx as it formed both a physical obstruction and functioned as an organic reactive barrier to prevent oxygen to the underlying tailings. Sulphide oxidation and consequential ARD formation did not occur. Sludge-borne trace elements accumulated in a reductive, alkaline environment in the underlying tailings, resulting in an effluent drainage geochemistry of Cd, Cu, Pb and Zn below 10 μg/L, high alkalinity (810 mg/L) and low sulphate (38 mg/L). In contrast, the uncovered reference tailings received a 0.35-m deep oxidation front and typical ARD, with dissolved concentrations of Cd, Zn and sulphate, 20.8 μg/L, 16,100 μg/L and 1,390 mg/L, respectively. Organic matter degradation in the sludge may be a limiting factor to the function of the sealing layer over time as 85 % loss of the organic fraction occurred over the 8-year experimental period due to aerobic and anaerobic degradation. Though the cover may function in the short to medium term (100 years), it is unlikely to meet the demands of a long-term remedial solution. 相似文献
17.
Mathematical Geosciences - Geological sampling data often need to be regionally segmented to mark blocks with different geological properties in mathematical geosciences. This paper uses the... 相似文献
18.
Using Field-Portable XRF to Assess Geochemical Variations Within and Between Dolerite Outcrops of Preseli, South Wales 总被引:1,自引:0,他引:1
Michael C. Jones Olwen Williams-Thorpe Philip J. Potts Peter C. Webb 《Geostandards and Geoanalytical Research》2005,29(3):251-269
Eight dolerite outcrops in Preseli, south Wales were measured in situ using field-portable XRF analysis, in order to compare two different analysis ("sampling") strategies, and to investigate geochemical variability within and between outcrops. A sampling strategy of two (neighbouring but independent) measurements at each of a maximal number of locations dispersed over an outcrop was the more effective in indicating the overall chemical variance of that outcrop. Analysis of variance indicated that much of the observed variance within individual outcrops stems from real geochemical variability rather than from sampling and analytical factors. Standard ANOVA F tests showed that several of the studied outcrops are heterogeneous at the 5% significance level for one or more elements. Geochemical distinctions between some outcrops were demonstrated using discriminant analysis. PXRF analysis offers an alternative approach to conventional characterisation of outcrops, which is often based on laboratory analysis of small numbers of samples. However, PXRF data are affected by rock weathering and may require correction for this if they are to be compared with analyses of fresh rock. 相似文献
19.
Robert J. Livingston 《Estuaries and Coasts》1987,10(3):194-207
The spatial/temporal scaling problem (i.e., fitting a given research question to the dimensions of variability of the study area) is particularly pronounced in highly variable systems such as estuaries. Long-term, multidisciplinary studies in the Apalachicola Bay system were used to evaluate variation of different physical, chemical, and biological factors. Specific limitations of weekly, monthly, and quarterly sampling intervals were directly related to the efficiency of the sampling gear, the range of variation in the study parameters, and specific biological features (motility, recruitment, natural history) of infaunal macroinvertebrates and epibenthic organisms. There are families of spatial and temporal scaling phenomena that should be considered when establishing a given field sampling program. The dimensions of variation change along spatial/temporal gradients of salinity, habitat complexity, and productivity and among different levels of biological organization. The limits of variation define the needed sampling effort for a given level of estimation. Without an adequate evaluation of such variation, representative samples cannot be taken; the resulting inadequate sampling effort often precludes reliable comparisons and robust generalization. There is a continuum of scaling dimensions (and sampling problems) that ranges from small-scale experimental approaches to system-wide analyses. Misapplication of such scaling estimates has led to overgeneralization of experimental results. Currently, there is widespread misapplication of combinations of unrelated, limited sampling efforts to broad-scale resource problems. The loss of valuable estuarine resources is favored by the lack of adequate scientific databases that are consistent with the dimensions of the individual study areas. Unless experimental studies and field sampling programs are scaled to the dimensions of the research problem and the study area in question there will be a continued proliferation of trivial studies at one end of the continuum and the progressive deterioration of estuarine resources at the other. 相似文献
20.
Yu-Jia Chiu Kang-Tsung Chang Yi-Chin Chen Jiunn-Hsing Chao Hong-Yuan Lee 《Natural Hazards》2011,59(1):271-284
The formulation of watershed management strategies to protect water resources threatened by soil erosion and sedimentation requires a thorough understanding of sediment sources and factors that drive soil movement in the watershed. This paper describes a study of medium-term water-driven soil erosion rates in a mountainous watershed of the Shihmen Reservoir in Taiwan. A total of 60 sampling sites were selected along a hillslope. At each sampling site, the inventory 137Cs activity was determined and then calculated with the diffusion and migration model to derive soil erosion rates. The rates are one to two orders of magnitude lower than estimates using the Universal Soil Loss Equation, a soil erosion model often used in Taiwan. Results of multiple regression analysis indicate that the spatial variability of soil erosion rates is associated with the relative position of a sampling site to the nearest ridge and soil bulk densities (r 2 = 0.33, p < 0.01). Finally, the patterns of soil redistribution rates on the hillslope follow the 137Cs hillslope model as soil erosion increases in the downslope direction. No deposition site is found at footslope because soil deposition is swept away by regular flooding along the stream channel. This study is an important first step in using 137Cs as a tracer of soil redistribution in mountainous watersheds of Taiwan. 相似文献