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1.
施威特曼石(schwertmannite)已被证实是一种具特异性能的重(类)金属吸附新材料,生物方法合成的施威特曼石由于具备较好的表面吸附性能而受到更多关注。本文通过接种有嗜酸性氧化亚铁硫杆菌(Acidithiobacillusferrooxidans)的FeSO4-H2O矿物合成体系,研究了不同初始Fe2+浓度对Fe生物转化成施威特曼石效率的影响。结果表明,在Fe(Ⅱ)浓度(FeSO4.7H2O配制)设计为20、40、80和160 mmol/L,接种A.ferrooxidans菌密度达到6.0×107个/mL时,本实验条件下矿物重量y(g)与初始Fe2+浓度x(mmol/L)的关系为y(g)=0.036 67+0.008 520x-8.602.10-6x2;溶液TFe沉淀率y(%)与初始Fe2+浓度x(mmol/L)的关系为y(%)=39.68-0.221 0x+6.653.10-4x2。反应后期溶液中大量残留Fe3+在满足饱和指数SI>0的条件下不能析出矿物沉淀,进一步分析表明,Fe3+水解形成施威特曼石的可能机制是利用了Acidithiobacillus ferrooxidans菌氧化Fe2+释放的能量才得以实现,当Fe2+完全氧化不再供应能量时,Fe生物转化成施威特曼石的反应也达到了最大限度。 相似文献
2.
采用H2O2氧化Fe2+并供应4种不同浓度葡聚糖的方法,探讨在H2O2氧化体系中葡聚糖对次生铁矿物形成的影响。结果表明:葡聚糖对次生矿物的形成具有明显的抑制作用;随着葡聚糖浓度的提高,次生矿物内的Fe含量降低,而S含量没有显著变化,且所有处理的K含量均较低;没有葡聚糖处理的次生矿物XRD特征峰与黄钾铁矾吻合,而添加葡聚糖后形成的次生矿物的特征峰与施氏矿物吻合,但是所有处理的次生矿物的结晶度都不高;随着葡聚糖浓度的提高,次生矿物的颗粒尺寸降低,比表面积增加。因此,葡聚糖能够抑制次生矿物的合成,并且阻止次生矿物由施氏矿物向黄钾铁矾的转变。 相似文献
3.
一价阳离子和水溶性有机质对生物沥浸中次生铁矿物形成的影响 总被引:2,自引:0,他引:2
在嗜酸性氧化亚铁硫杆菌(Acidithiobacillus ferrooxidans)作用下,污泥生物沥浸体系中常会有次生铁矿物形成,这些矿物对污泥脱水和重金属溶出有重要影响。本研究模拟生物沥浸体系,考察了一价阳离子(K+、NH4+、Na+)和污泥DOM(dissolved organic matter)对次生铁矿物形成的影响。结果表明,一价阳离子生成次生黄铁矾类矿物的能力迥异,其中K+的成矾能力最强,120 mmol/L NH4+和80 mmol/L Na+会抑制体系中黄钾铁矾形成。在1.6 mmol/L K+-120 mmol/L NH4+-40 mmol/L Na+和1.6 mmol/L K+-80 mmol/L NH4+-80 mmol/L Na+两个处理所得矿物的结晶度均低于1.6 mmol/L K+-80 mmol/L NH4+-40 mmol/L Na+处理所得矿物的结晶度。另外,在50 mg/L DOM(以DOC计)存在的生物氧化体系,Fe2+最大氧化速率为4.96 h-1,比没有DOM存在时降低48.1%,矿物结晶度也明显低于后者。可见,过高的一价阳离子和DOM含量会影响A.ferrooxidans菌生理生化活性,降低Fe2+氧化速率,继而影响Fe3+供应,使微环境中的黄铁矾形成动力发生改变,最终在一定程度上影响了次生铁矿物的形成。 相似文献
4.
As(Ⅴ)对嗜酸性氧化亚铁硫杆菌混合培养物氧化性能的影响 总被引:2,自引:1,他引:1
通过对pH、Eh、溶液中Fe2+浓度的定期监测以及对实验结束时生成沉淀的XRD、SEM和元素能谱扫描等手段,对比研究了不同初始浓度的As(Ⅴ)对Fe2+的化学氧化和嗜酸性氧化亚铁硫杆菌(Acidithiobacillus ferrooxidans)氧化的影响, 同时就As(Ⅴ)在实验体系中固液相之间的分配行为进行了分析.结果表明,Fe2+的化学氧化速率极低,最终氧化率低于8%,As(Ⅴ)的浓度对Fe2+的化学氧化没有影响.有A. ferrooxidans的实验体系,100 mg/L As(Ⅴ)对Fe2+的氧化具有一定的促进作用.当As(Ⅴ)浓度为500 mg~1 g/L时,Fe2+的氧化率在约60 h左右即可达到100%;但4g/L的As(Ⅴ)则会明显抑制Fe2+的氧化,Fe2+的完全氧化大约需要106 h.体系中初始的100 As/(As+S)(摩尔比)会对沉淀物的物相及结晶程度造成一定影响.As(Ⅴ)浓度为0 g/L时,微生物体系中生成的固体沉淀物黄钾铁矾的特征峰明显,随着As(Ⅴ)浓度的提高,沉淀物的结晶程度逐步下降,至4 g/L时沉淀物全部为无定形.元素能谱扫描检测到有大量的As(Ⅴ)存在于固体沉淀物中,表明在Fe2+的氧化过程中,As(Ⅴ)可能会以吸附或共沉淀的形式被固定在固相沉淀物中,这为酸性矿坑水(AMD)地区As(Ⅴ)污染的治理提供了重要的参考. 相似文献
5.
选取酸性矿坑水环境中常见的次生含铁硫酸盐矿物———黄钾铁矾[KFe3(SO4)2(OH)6]为研究对象,用硫酸盐还原菌
Desulfovibriovulgaris 和异化铁还原菌Shewanellaputrefaciens CN32对其进行还原实验,探讨作为重金属治理潜在材料的
黄钾铁矾的微生物稳定性.实验采用非增长型培养基,在中性、厌氧、30℃的条件下进行.采用湿化学方法测量水溶液及还原产
生的总Fe2+ ,利用X射线衍射(X-raydiffraction,简称XRD)来分析反应后残余固体物质的矿物组成,用扫描电镜(scanning
electronicmicroscopy,简称SEM)观察固体残余物的形貌特征.结果表明,没有微生物的参与,黄钾铁矾的稳定性较好.异化铁
还原菌S.putrefaciens CN32和硫酸还原菌D .vulgaris 在营养极其匮乏的中性厌氧条件下均能还原黄钾铁矾晶格中的
Fe3+ ,显示出黄钾铁矾被微生物还原的可能性.S.putrefaciens CN32还原黄钾铁矾晶格中Fe3+ 的最大还原速率和最终Fe3+
还原率分别为0.001mmol·L-1·h-1和0.37%.与S.putrefaciens CN32不同,D .vulgaris 对黄钾铁矾的还原能力较强,不
含有电子穿梭体(Anthraquinone-2,6-disulfonate,简称AQDS)的实验体系中Fe3+ 的最大还原速率和最终Fe3+ 还原率分别为
0.017mmol·L-1·h-1和16.80%,而添加了AQDS的实验体系的则分别达到了0.026mmol·L-1·h-1和24.30%,这可能与
黄钾铁矾中含有SO42- 有关.D .vulgaris 优先还原黄钾铁矾晶格中的SO42- 产生的H2S是强还原剂,也可促进Fe3+ 的还原,
微生物以及H2S的双重作用可能是导致D .vulgaris 体系中Fe3+ 还原率较高的原因.XRD分析表明,黄钾铁矾经过S.putrefaciens
CN32的作用,物相没有发生变化;而经过D .vulgaris 作用后,黄钾铁矾的特征峰消失,固相残余物中出现了菱铁
矿(FeCO3)、蓝铁矿[Fe3(PO4)2·8H2O]等次生矿物.由于培养基中没有添加任何的磷酸盐,因此蓝铁矿的出现可能是由于培
养基中添加的少量酵母浸膏降解后产生的磷酸根与D .vulgaris 还原黄钾铁矾产生的Fe2+ 相互作用的结果.这些认识对深入
理解地球表层铁的生物地球化学循环具有重要意义,为矿山环境重金属的污染治理提供了实验依据. 相似文献
6.
利用电子探针检测安徽凤阳石英岩中的含铁矿物,测量由相同矿区的石英岩加工而成的不同粒度石英砂的Fe2O3质量分数(w(Fe2O3))与磁化率。结果表明:石英岩中有磁铁矿、黄铁矿、黑云母与白云母等多种含铁矿物。这些含铁矿物主要充填在石英颗粒孔隙中,粒度大多小于0.1 mm。而石英砂中的w(Fe2O3)普遍很低(小于0.1%),其磁化率主要受磁铁矿控制。并且不同粒度的石英砂中w(Fe2O3)与磁化率存在较大差异,当石英砂中的w(Fe2O3)大于0.01%时,由Fe2+、Fe3+磁性离子含量决定磁化率大小,两者存在强正相关关系。这也反映出了石英岩的铁含量与磁化率之间的关系。因此,磁化率可作为石英岩铁含量的替代性指标。 相似文献
7.
Fe(Ⅲ)供应速率对无定型施氏矿物形成的影响 总被引:2,自引:0,他引:2
施氏矿物(schwertmannite)已被证实是一种具特异性能的重(类)金属吸附新材料。但在直接由Fe3+或用强氧化剂氧化Fe2+合成该矿物时,常因夹有黄铁矾类物质而降低产品纯度。通过模拟FeSO4-K2SO4-H2O临界成矾体系,发现在嗜酸性氧化亚铁硫杆菌(Acidithiobacillus ferrooxidans)作用下存在无定型施氏矿物和晶型黄钾铁矾的合成反应竞争,其中Fe3+供应速率是一个影响铁矿物形成的重要因素,较低的Fe3+供应可以抑制K+的利用,这种变化趋势对无定型施氏矿物合成是有利的。当存在少量K+等成矾导向离子时,可通过合理调低Fe3+供应速率,有利于溶液中Fe3+平缓释放,改善施氏矿物纯度,这为A.ferroxidans菌生物法中直接使用无机盐培养基合成施氏矿物提供了可能。 相似文献
8.
研究石灰岩包壳作用有助于深入了解酸性矿山废水(AMD)在富含石灰岩的金属硫化物尾矿中的释放机制。采用AMD滞留浸泡石灰岩颗粒试料的实验方法,研究在酸水饱和条件下石灰岩次生包壳的形成作用。研究表明,AMD的Fe含量是影响石灰岩包壳作用的主因之一。在高Fe浓度(如1 029~1 033 mg/L)的AMD中,石灰岩颗粒表面可依次沉淀富Al相、石膏、纤铁矿(吸附Zn、Cu及As等),发生石灰岩包壳/钝化作用,使溶液维持酸性;而在低Fe浓度(6.71~74.8 mg/L)的AMD中,次生包壳难以生成,石灰岩得以大量溶解释碱并充分中和溶液中的H~+,使溶液达到中性。因此,Fe硫化物含量较高(如Fe含量10.62%、S含量5.70%)的石灰岩尾矿,由于其氧化后可生成高Fe浓度的酸性水而导致石灰岩包壳作用,具有释放AMD(及重金属)的危险,应注意防控。 相似文献
9.
北戴河红色风化壳地球化学特征及气候环境意义 总被引:2,自引:0,他引:2
风化壳地球化学特征具有环境指示意义。用X射线荧光光谱法(XRF)和X射线衍射法(XRD)分别测试了秦皇岛北戴河燕山大学北侧红色风化壳(简称燕大风化壳)主量元素和粘粒粘土矿物。结果表明:除Ca外,Si、Al、Fe、Na、K的含量在风化壳上均有不同程度的波动,其中Si、Na、K波动轨迹基本一致,Al、Fe则与其相反,相关性分析显示SiO2与Al2O3、TFe、Fe2O3,Al2O3与TFe、Fe2O3,Na2O与CaO具有较好相关性;粘土矿物组合为1·4nm过渡矿物(25%~45%)+伊利石(10%~20%)+伊蒙混层矿物(20%~35%)+高岭石(15%~30%),矿物演化系列是长石、黑云母→(蛭石→1·4nm过渡矿物)→(伊利石)→高岭石。与粘土矿物以1∶1型高岭石为主的富铝化南方红色风化壳相比,燕大风化壳Si淋失度,Fe、Al富集度,矿物演化程度都较低,属硅铝化风化壳。燕大风化壳是上新世暖温带到北亚热带过渡型气候的风化产物,与现代秦皇岛暖温带半湿润型气候不同,这反映第四纪以来该区气候干旱因子增多。CIA、S/A等指示的风化强度异常表明,燕大风化壳形成后至少遭受过两次构造抬升,为剥蚀型风化壳,反映该区新构造运动间歇式上升的特点。 相似文献
10.
由于无机环境下不能沉淀白云石,该矿物的成因一直是学术争论的焦点。柴达木盆地西部钻孔SG-1(长938 m)中出现了大量白云石和铁白云石,白云石主要分布在钻孔下部500 m,而铁白云石主要分布在下部418 m。结合湖泊从淡水湖、咸水湖、盐湖至干盐湖的演化过程,文章分析了白云石和铁白云石的成因。白云石是盐类矿物的一种、且无机环境下不能沉淀,蒸发作用和微生物介导是白云石矿物形成的两个重要影响因素。蒸发作用为白云石的形成提供了足够浓度的Mg2+,微生物的介导作用帮助Mg2+克服动力学障碍进入碳酸钙晶格形成白云石。白云石是湖泊演化早期析出的一种碳酸盐类矿物,主要在咸水湖环境中沉淀,盐湖环境中主要沉淀硫酸盐类和氯化物矿物,在盐湖这种高盐度环境下能够生存的微生物非常少,白云石含量明显降低。铁白云石是白云石矿物的一种,是Fe2+替代白云石中的Mg2+形成的次生矿物。Fe2+有两种来源:粘土矿物转换过程中的释放和深部热液来源。Fe2+进入白云石的过程主要是在无机、高温环境下完成的,但不排除微生物的介导作用。 相似文献
11.
酸性矿山废水中生物成因次生高铁矿物的形成及环境工程意义 总被引:10,自引:1,他引:9
酸性矿山废水(acid mine drainage,AMD)是一类pH低并含有大量有毒金属元素的废水。AMD及受其影响的环境中次生高铁矿物类型主要包括羟基硫酸高铁矿物(如黄铁矾和施威特曼石等)和一些含水氧化铁矿物(如针铁矿和水铁矿等),而且这些矿物在不同条件下会发生相转变,如施氏矿物向针铁矿或黄铁矾矿物相转化。基于酸性环境中生物成因次生矿物的形成会"自然钝化"或"清除"废水中铁和有毒金属这一现象所获得的启示,提出利用这些矿物作为环境吸附材料去除地下水中砷,不但吸附量大(如施氏矿物对As的吸附可高达120mg/g),而且可直接吸附As(III),还几乎不受地下水中其他元素影响。利用AMD环境中羟基硫酸高铁矿物形成的原理,可将其应用于AMD石灰中和主动处理系统中,构成"强化微生物氧化诱导成矿-石灰中和"的联合主动处理系统,以提高AMD处理效果和降低石灰用量。利用微生物强化氧化与次生矿物晶体不断生长的原理构筑生物渗透性反应墙(PRB)并和石灰石渗透沟渠耦联,形成新型的AMD联合被动处理系统,这将有助于大幅度增加处理系统的寿命和处理效率。此外,文中还探讨了上述生物成因矿物形成在AMD和地下水处理方面应用的优点以及今后需要继续研究的问题。 相似文献
12.
《Journal of Geochemical Exploration》2005,85(2):55-62
Concern about arsenic is increasing throughout the world, including areas of the United States. Elevated levels of arsenic above current drinking-water regulations in ground and surface water can be the result of purely natural phenomena, but often are due to anthropogenic activities, such as mining and agriculture. The current study correlates arsenic speciation in acid mine drainage and mining-influenced water with the important water-chemistry properties Eh, pH, and iron(III) concentration. The results show that arsenic speciation is generally in equilibrium with iron chemistry in low pH AMD, which is often not the case in other natural-water matrices. High pH mine waters and groundwater do not always hold to the redox predictions as well as low pH AMD samples. The oxidation and precipitation of oxyhydroxides deplete iron from some systems, and also affect arsenite and arsenate concentrations through sorption processes. 相似文献
13.
《International Journal of Mineral Processing》2005,76(3):149-162
Acid mine drainage (AMD), of which iron is a substantial component, is a potential by-product in the mining industry. Conventional neutralization is a common approach to treat AMD, although it creates a major disposal problem due to the generation of voluminous sludge. Sludge recirculation improves solid density by slowing down the rate of neutralization and allowing the growth of precipitates, while existing solids act as seed particles by providing necessary surface area for precipitation. The mechanisms of iron sludge densification are not fully understood, mainly because of the complex nature of iron chemistry, and the variety of amorphous, polymeric oxides that could be formed. In this work, the effects of alkaline reagents, flocculant addition, and dosing sequence, on the precipitation of iron (III) hydroxide and densification of the recycled sludge were investigated. Slowly dissolving lime (Ca(OH)2) was found to be more effective than caustic (NaOH) in producing sludge with higher solid contents. Polymers addition created stronger aggregates that could withstand shearing without significant size reduction, but the overall sludge density was lower than those produced without flocculant. Conditioning the sludge at pH between 3.5 and 4.5 by adding fresh lime in a specific dosing manner appeared to be conducive to the growth of large agglomerates. The final sludge solid content of ∼15 wt.% was considerably higher than others produced under different conditions. The plate-like structures of precipitates generated with more recycles in this instance, possibly helped ease the release of entrapped water between solids during shearing, thus producing sludge with higher solid density. 相似文献
14.
Rio Marina mining district (Elba Island) is characterised by hematite + pyrite ore association and was exploited for iron till 1981, leaving waste rock dumps of several millions m3. The effect of open pit mining activity in this site is to produce acid mine drainage (AMD) processes leading to environmental pollution, testified by all the sampled waters (Giove stream, drainage channels, superficial pools and settling basin) which have pH values ranging from 2.08 to 3.35 and heavy metal concentrations that reach 903.16 mg/l for Fe, 45.02 mg/l for Mn, 10.08 mg/l for Zn and 1.75 mg/l for Cu. In the present work a space and time related approach to geochemical hazard evaluation was applied. The geochemical hazard is mainly related to high heavy metal concentration, acid mine drainage processes development and topographic setting. As all these parameters are related in space, hazard evaluation was performed by geostatistical methods. Fifty-four earth material samples (residual soils, waste rocks or debris materials) were collected in a central aligned 100 m mesh square grid. These were analysed for major elements by XRF, for Cu, Pb, Zn by ICP-AES and for AMD potential following the AMIRA procedure. The concentration of heavy metals was compared with Italian law limits. The overlap of Cu, Pb and Zn content maps show that at least one of these heavy metals exceed law limits in all the area. The AMD test results show that more than 50% of samples have a positive NAPP (Net Acid Producing Potential) that could reach 258.9 kg H2SO4/t. According to the obtained data, three main geochemical hazard classes were established and their distribution in the mining area was assessed. About 51% of the mining area surface belongs to the major hazard class, where AMD process occurs, about 49% belongs to an intermediate hazard class, where AMD process could occur only if certain conditions are met. Finally, the persistence of the AMD process in the Rio Marina area was evaluated on the basis of yearly rainfall, mining waters pH and NAPP values. A complete leaching of the first 0.25 m of the earth materials can retain the current environmental conditions for several centuries. 相似文献
15.
Limestone drains are often implemented in the treatment of acid mine drainage (AMD), but when the AMD contains high levels of dissolved Fe their lifetime is dependent on the rate of precipitation of Fe hydroxide on the limestone surface. This study used a small-scale laboratory experiment to define the longevity of a limestone drain by determining the thickness of the Fe coating encapsulating the limestone particles when the system lost its maximum neutralising potential. Synthetic AMD (100 mg/L Fe, pH 4–4.8) was pumped through a column containing limestone particles for 1110 h, when the effluent pH had dropped from a maximum of 6.45–4.9. The decline in neutralisation during the experiment was due to the formation of Fe hydroxide coatings on the limestone grains. These coatings are composed of lepidocrocite/goethite in three distinct layers: an initial thick porous orange layer, overlain by a dense dark brown crust, succeeded by a layer of loosely-bound, porous orange globules. After 744 h, a marked increase in the rate of pH decline occurred, and the system was regarded as having effectively failed. At this time the Fe hydroxide crust effectively encapsulated the limestone grains, forming a diffusion barrier that slowed down limestone dissolution. Between the coating and the limestone substrate was a 60 μm wide void, so that agitation of the limestone sample would readily remove the coating from the limestone surface. 相似文献
16.
Thomas Genty Bruno Bussière Robin Potvin Mostafa Benzaazoua Gérald J. Zagury 《Environmental Earth Sciences》2012,66(8):2387-2401
Oxidation of sulphide mining waste can generate acid mine drainage (AMD) that has the potential to seriously affect the ecosystems. Acid mine drainage is characterised by a high acidity, high concentrations of sulphates and metals. To reduce the environmental impacts due to AMD, neutralisation using limestone drains is an option proposed in the literature and used around the world. The present study focuses on the influence of the carbonate rock mineralogy and their particle size on the neutralising capacity. The tests were performed in two different anoxic conditions: in batch reactors, and in columns having a hydraulic retention time of 15?h. The results showed that the neutralisation capacity of calcite was more important than for dolomitic rock, and smaller particle size gave higher alkalinity production (fine calcite dissolved faster in contact with AMD). A characterization of metal precipitate in sludge and in limestone coating was performed and demonstrated that gypsum, lepidocrocite and goethite were the predominant secondary minerals to be formed. Finally, this study underlines that anoxic limestone drain cannot be used alone to treat high iron concentrated AMD. 相似文献
17.
煤矿酸性水水化学特征及其环境地球化学信息研究 总被引:19,自引:0,他引:19
以水化学数据为依据,应用相关分析,结合地质、水文勘探资料,对煤矿酸性矿排水 (AMD)的水化学特点及其成因进行了研究。煤矿AMD在一定的物质条件和环境条件下形成,只要条件适宜,不管是高硫煤还是低硫煤均可产生酸性水;低pH、高Eh、高TDS及高硬度是煤矿AMD的重要特征,水中的SO32-与其EC之间以及Fe3+/Fe2+比值与其Eh值走势具有良好的一致性,水中微量元素及重金属来源较复杂,如Ni、Cu、Co、Zn等来源于黄铁矿的氧化溶解,但Pb、Sr等主要来自AMD对煤系地层中煤及岩石中矿物的淋滤作用。 相似文献
18.
Thuro Arnold Nils Baumann Sina Brockmann Udo Zimmermann Stephan Weiß 《Geochimica et cosmochimica acta》2011,75(8):2200-3065
The subsurface acid mine drainage (AMD) environment of an abandoned underground uranium mine in Königstein/Saxony/Germany, currently in the process of remediation, is characterized by low pH, high sulfate concentrations and elevated concentrations of heavy metals, in particular uranium. Acid streamers thrive in the mine drainage channels and are heavily coated with iron precipitates. These precipitates are biologically mediated iron precipitates and related to the presence of Fe-oxidizing microorganisms forming copious biofilms in and on the Fe-precipitates. Similar biomineralisations were also observed in stalactite-like dripstones, called snottites, growing on the gallery ceilings.The uranium speciation in these solutions of underground AMD waters flowing in mine galleries as well as dripping from the ceiling and forming stalactite-like dripstones were studied by time resolved laser-induced fluorescence spectroscopy (TRLFS). The fluorescence lifetime of uranium species in both AMD water environments were best described with a mono-exponential decay, indicating the presence of one major species. The detected positions of the emission bands and by comparing it in a fingerprinting procedure with spectra obtained for acid sulfate reference solutions, in particular Fe(III) - SO42− - UO22+ reference solutions, indicated that the uranium speciation in the AMD environment of Königstein is dominated in the pH range of 2.5-3.0 by the highly mobile aquatic uranium sulfate species UO2SO4(aq) and formation of uranium precipitates is rather unlikely as is retardation by sorption processes. The presence of iron in the AMD reduces the fluorescence lifetime of the UO2SO4(aq) species from 4.3 μs, found in iron-free uranium sulfate reference solutions, to 0.7 μs observed in both AMD waters of Königstein and also in the iron containing uranium sulfate reference solutions.Colloids were not observed in both drainage water and dripping snottite water as photon correlation spectroscopy analyses and centrifugation experiments at different centrifugal accelerations between 500g and 46000g revealed. Thus transport and uranium speciation at the investigated AMD sites is neither influenced by U(IV) or U(VI) eigencolloids nor by uranium adsorbed on colloidal particles.This study shows that TRLFS is a suitable spectroscopic technique to identify the uranium speciation in bulk solutions of AMD environments. 相似文献
19.
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
20.
黄钾铁矾是酸性矿山废水(AMD) 中常见的次生矿物,能有效吸附AMD中Cu、Pb、Zn、Gd、As等重金属元素。不
同条件下形成的黄钾铁矾微形貌不同,其吸附能力也不同。文章通过化学法和微生物法合成了黄钾铁矾,并在粤北大宝山
矿酸性矿山废水中采集了含黄钾铁矾的泥样。利用扫描电镜-能谱分析(SEM) 和X光衍射(XRD),对三种不同条件下形
成的黄钾铁矾进行鉴定和微形貌特征观察,并分析黄钾铁矾的形成条件。结果表明,常温条件下,pH值2.0~2.5时能够化
学合成黄钾铁矾,其晶体粒径约2~10 μm,且晶形呈板状;而在65℃时,可在pH2.0~3.0之间化学合成黄钾铁矾,但晶形
差。微生物法合成黄钾铁矾pH范围是2.0~5.0,其晶形完好,呈菱面体且晶体大小比较均匀,而约为2~4 μm。酸性矿山废
水中的黄钾铁矾形成的pH值为2.5~3.5,晶形为菱面体形,单个晶体大小多为1~2 μm。根据其形成条件和微形貌特征,文
章推测酸性矿山废水中形成的黄钾铁矾可能是微生物成因。 相似文献