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1.
水钠锰矿是土壤与沉积物中最为常见的氧化锰矿物,依据其MnO6层对称特点分为六方和三斜两种亚结构类型.六方水钠锰矿在表生环境中可通过Mn2+的化学或生物氧化形成,而环境中三斜水钠锰矿的形成及进一步转化为钙锰矿的途径尚不清楚.以两种六方水钠锰矿(酸性水钠锰矿和水羟锰矿)为前驱物,采用X射线吸收光谱(EXAFS)、X射线衍射(XRD)、电镜(FESEM/TEM)及化学组成分析等技术方法模拟表生环境研究了水钠锰矿从六方向三斜的亚结构转化及生成钙锰矿的化学条件和矿物学机制.结果表明,适当Mn(Ⅱ)浓度和弱碱性条件(pH≥8)可使六方水钠锰矿逐渐转化为三斜水钠锰矿,继而经Mg2+交换、常压回流得到了长纤维状的钙锰矿,其晶体生长以溶解-结晶为主.Mn(Ⅱ)与六方水钠锰矿MnO6八面体层内的Mn(Ⅳ)反应生成Mn(Ⅲ)并填充层内空位,使水钠锰矿对称型由六方向三斜转变.与酸性水钠锰矿相比,水羟锰矿结晶弱、层状堆积混乱度高,与Mn(Ⅱ)反应迅速,层结构向三斜水钠锰矿转化快.pH升高,促进六方水钠锰矿对Mn(Ⅱ)的吸附和Mn(Ⅱ)与Mn(Ⅳ)间的反应,六方水钠锰矿转化为三斜水钠锰矿的速率加快."六方水钠锰矿→三斜水钠锰矿"可能是环境中三斜水钠锰矿的重要来源,及进一步形成钙锰矿的重要化学生成机制. 相似文献
2.
水钠锰矿、钙锰矿是土壤和沉积物中常见的氧化锰矿物。本文用改进的方法在碱性介质中合成了结晶度高的单相水钠锰矿 ,其平均化学组成为Na0 .2 5MnO2 .0 70 .6 6H2 O。合成在常温 2 5℃以及机械搅拌作用下进行 ,反应易于控制 ,没有黑锰矿、六方锰矿等其它矿相生成。合成的单相水钠锰矿经Mg2 + 交换、热液处理 ,完全转化为结晶良好、隧道构造为 3× 3的钙锰矿。生成的钙锰矿呈长短不一的纤维状 ,沿三个方向生长的晶体形成各交 12 0°角的三连晶结构 ,平均化学组成为Mg0 .1 6 MnO1 .570 .82H2 O 相似文献
3.
碱性介质中合成水钠锰矿的几个影响因素 总被引:8,自引:0,他引:8
水钠锰矿是土壤和沉积物中常见的氧化锰矿物。较系统地研究了碱性介质中合成水钠锰矿几个影响因素的作用规律。结果表明,在实验条件下,反应液的流动速率和氧气流量是合成水钠锰矿的主要影响因素,在反应中使用机械搅拌,可以使水钠锰矿的合成简单易行;而反应前通氮气处理和反应温度对水钠锰矿的合成没有影响;实验合成单相水钠锰矿的条件为:OH-/Mn摩尔比为13.7,O2的流量2L/min,在常温和机械搅拌下氧化5h;其平均化学组成为Na0.25MnO2.07·0.66H2O。 相似文献
4.
热液条件下钙锰矿的合成及其影响因素 总被引:5,自引:0,他引:5
钙锰矿具有3× 3的大隧道构造, 广泛分布于大洋锰结壳和锰结核等环境中, 其性质和成因倍受关注.以改进方法制备的水钠锰矿(birnessite)为前驱物, Mg2+交换后得到Mg-水钠锰矿(或称布塞尔矿, buserite), 经热液处理合成了结晶度高的单相钙锰矿(todorokite), 采用X-射线衍射(XRD)、透射电镜(TEM)和选区电子衍射(SAED)等技术探讨了热液温度、体系压力和处理时间等因素对钙锰矿合成的影响.结果表明: 合成的钙锰矿与天然钙锰矿有相同的形貌和生长特征, 呈纤维状, 沿120°三连晶生长, 平均化学组成为Mg0.16MnO2.07 0.82H2O.在实验条件下, 热液温度和处理时间是影响钙锰矿合成的主要因素; 而通过改变高压釜的填充度引起体系压力的变化对钙锰矿合成的影响较小, 体系压力并不是钙锰矿形成的主要影响因素.热液温度越高, Mg-水钠锰矿转化为钙锰矿的速率越快, 完全转化为钙锰矿所需的处理时间越短.热液温度分别为120℃、160℃和200℃时, Mg-水钠锰矿完全转化为钙锰矿所需的时间分别为6 h、4 h和2 h; 但热液温度高于160℃时, 易生成水锰矿杂质.延长处理时间与提高热液温度具有相似的影响规律.这进一步明确了钙锰矿的生成条件, 可为阐明钙锰矿的形成机制和促进其在材料科学中的应用提供理论依据. 相似文献
5.
水钠锰矿氧化硫化物的过程与动力学研究 总被引:1,自引:0,他引:1
水钠锰矿是表生环境中常见的氧化锰矿物之一,影响土壤溶液中硫化物的迁移、转化和归趋。本文考察了酸性水钠锰矿氧化硫化钠溶液的反应过程,采用分光光度法、离子色谱法分析S2-及其氧化产物的浓度和变化趋势,用XRD、SEM表征酸性水钠锰矿粉末反应前后的晶体结构和微观形貌,探讨了温度、pH值、矿物用量对S2-氧化速率的影响。结果表明,S2-的氧化产物主要为单质S,其氧化速率符合准一级动力学规律,且氧化速率随着温度升高、pH值降低和矿物用量增加而增大;酸性水钠锰矿首先被还原生成Mn(OH)2,Mn(OH)2在空气中与O2作用转化成Mn3O4,Mn3O4可进一步转化生成MnOOH。 相似文献
6.
采自中太平洋海山富钴结壳主要由水羟锰矿组成,在XRD衍射图谱上,该矿物缺少(001)和(002)底面衍射,其原因是水羟锰矿包含了两种对称型的八面体层,即三斜对称和六方对称的八面体层,它们沿c轴方向无序排列。部分样品中的水羟锰矿在低角度区具有d>2.0nm的超结构衍射峰,它在实质上反映了矿物结构层的长程有序性,即两种层片的排列具有某种周期性或规律性。部分样品原先没有,但在加热后出现超结构衍射峰,可能是因为样品在空气中加热,使三斜层片中的Mn(III)被氧化成Mn(IV),从而转变为六方层片,继而改变了水羟锰矿的有序性。富钴结壳中水羟锰矿的超结构,在一定程度上反映了矿物形成环境的变化。 相似文献
7.
钙锰矿是土壤、沉积物及海洋锰结核中常见的以3×3结构为主的一族大隧道构造氧化锰矿物.隧道中存在水分子和阳离子,形貌以片状、针状或纤维状为主.水钠锰矿→布塞尔矿→钙锰矿的转化是钙锰矿形成的一个重要途径.这种转化在常压条件下受体系温度、pH、共存粘土矿物、转化时间以及前驱物布塞尔矿亚结构特点,如层间交换离子类型、浓度、以水合离子形态或与MnO6八面体空穴上方键合的强弱、结晶度、Mn(Ⅲ)的含量与迁移特点等因素影响.钙锰矿独特的结构使其所具有的离子吸附、氧化与催化特性及分子级的隧道空间等有望作为特异的分子筛、二次电池正极材料、有机反应催化荆等在环境科学和材料科学等领域具有广阔的应用前景. 相似文献
8.
利用锰矿山现有初级产品MnSO4.H2O低成本制备锰钾矿型八面体分子筛。在液相环境中MnSO4和KOH反应生成Mn(OH)2沉淀后,在溶解氧和OH-的参与下,生成K型水钠锰矿,在高温下发生结构的调整转化为锰钾矿。通过实验获得的最佳条件为:在500mL反应体系中用0.2M的MnSO4.H2O与1M的KOH在室温环境中、通空气流量为30L/min、振荡搅拌转速为100r/min的条件下反应3h,离心洗涤至pH=12,样品干燥后在600℃下煅烧1h。为大规模开展锰矿山产品的深加工提供了重要的实验依据。 相似文献
9.
常压下pH对Cu-布塞尔矿向钙锰矿转化的影响 总被引:1,自引:1,他引:0
钙锰矿是表生环境中常见的隧道构造氧化锰矿物,常由层状构造的Na-布塞尔矿或水钠锰矿(Na-布塞尔矿脱水产物)经不同离子交换后在热液条件下转化而成.Na-布塞尔矿与离子交换过程中溶液pH对Me-布塞尔矿亚结构及常压下向钙锰矿的转化有重要影响.本文以Na-布塞尔矿为前驱物,探讨了pH对Cu-布塞尔矿形成及其在常压回流条件下向隧道构造钙锰矿转化的影响.结果表明,不控制pH值时,随着溶液中交换性Cu2+数量的增加,前驱物Na-布塞尔矿层间Na+离子的数量逐渐减少,直至被Cu2+离子完全交换.层间的Mn2+只有在加入的Cu2+达到一定量时才能被置换出来,体系pH值随着CuCl2加入量的增加而降低.随着进入Na-布塞尔矿层间Cu2+离子数量的增加,经回流转化后逐渐生成结晶度较好的钙锰矿相,但加入量超过一定量时,不能转化形成钙锰矿.在控制pH为4.5的体系中进行离子交换时,钙锰矿的形成随着Cu2+离子的增加而增加,并在高加入量时也可完全转化形成钙锰矿.上述两种转化的差异与pH变化所引起的Na-布塞尔矿亚结构变化及交换性Cu2+离子在其层间分布的形态密切相关. 相似文献
10.
水钠锰矿为自然界中常见的锰氧化物矿物,其离子交换作用及结构转变理解尚不深刻,矿物表征手段较为局限.为探究水钠锰矿的离子交换特性以及结构转变在拉曼光谱上的反映,利用MnSO4和NaOH合成了三斜晶系的Na型水钠锰矿,进行了NH4+、K+、Mg2+、Ca2+、Ba2+、Co2+、Zn2+的离子交换实验,使用ICP-OES、XRD、拉曼光谱等手段对离子交换水钠锰矿进行表征.拉曼光谱分析表明,570~585 cm-1与640~655 cm-1两个锰氧八面体伸缩振动模式的相对强度及570~585 cm-1附近拉曼峰峰位指示水钠锰矿的结构对称型;570~585 cm-1拉曼峰强度大、振动频率高指示三斜对称型.280 cm-1与500 cm-1附近的拉曼峰是层间离子种类的识别标志.水钠锰矿层间若为Na+、K+、Mg2+、Ca2+、Ba2+等碱金属、碱土金属离子,则在280 cm-1附近存在1个峰值,500 cm-1存在2个分立的峰值;其他种类的层间离子仅500 cm-1处有1个孤峰,指示层间离子排列无序. 相似文献
11.
Xiong Han Feng Mengqiang Zhu Chaoying Ni Donald L. Sparks 《Geochimica et cosmochimica acta》2010,74(11):3232-6063
Todorokite, as one of three main Mn oxide phases present in oceanic Mn nodules and an active MnO6 octahedral molecular sieve (OMS), has garnered much interest; however, its formation pathway in natural systems is not fully understood. Todorokite is widely considered to form from layer structured Mn oxides with hexagonal symmetry, such as vernadite (δ-MnO2), which are generally of biogenic origin. However, this geochemical process has not been documented in the environment or demonstrated in the laboratory, except for precursor phases with triclinic symmetry. Here we report on the formation of a nanoscale, todorokite-like phase from biogenic Mn oxides produced by the freshwater bacterium Pseudomonas putida strain GB-1. At long- and short-range structural scales biogenic Mn oxides were transformed to a todorokite-like phase at atmospheric pressure through refluxing. Topotactic transformation was observed during the transformation. Furthermore, the todorokite-like phases formed via refluxing had thin layers along the c∗ axis and a lack of c∗ periodicity, making the basal plane undetectable with X-ray diffraction reflection. The proposed pathway of the todorokite-like phase formation is proposed as: hexagonal biogenic Mn oxide → 10-Å triclinic phyllomanganate → todorokite. These observations provide evidence supporting the possible bio-related origin of natural todorokites and provide important clues for understanding the transformation of biogenic Mn oxides to other Mn oxides in the environment. Additionally this method may be a viable biosynthesis route for porous, nano-crystalline OMS materials for use in practical applications. 相似文献
12.
Caroline L. Peacock 《Geochimica et cosmochimica acta》2009,73(12):3568-6415
Sorption of Ni to birnessite is a fundamental control on the concentration of Ni in natural waters and associated sediments. Recent XAS work suggests the crystal-chemistry of Ni in birnessite is dependent on both structural and physiochemical factors. This work investigates the physiochemical controls on Ni crystal-chemistry in hexagonal birnessite with EXAFS of time series and pH series Ni-birnessite sorption experiments. At circumneutral pH Ni surface adsorbed above/below Mn octahedral vacancy sites in the phyllomanganate layers is progressively structurally incorporated into the vacancy sites with time (30% Ni incorporation after 408 h contact time). Ni structural incorporation into hexagonal birnessite occurs via rearrangement of surface adsorbed Ni with time rather than direct Ni incorporation from solution. At low pH (pH 4) Ni surface adsorbed at the vacancies is structurally incorporated into the vacancies upon increasing solution pH to circumneutral (∼20% Ni incorporation after 24 h contact time at circumneutral pH); newly incorporated Ni is stable with increasing contact time at pH circumneutral. However, upon decreasing solution pH from circumneutral back to pH 4, EXAFS shows a significant decrease in the proportion of Ni structurally incorporated; preliminary results indicate structural incorporation of Ni in hexagonal birnessite is reversible with decreasing pH. Time series results at circumneutral pH help explain the significant enrichment of Ni in marine ferromanganese precipitates; work here is combined with previous studies to provide a model correct at the molecular-level for Ni uptake by marine vernadite-rich ferromanganese precipitates. With Ni migrating from surface adsorbed to structurally incorporated, results suggest formation of a solid solution between an end-member vernadite and an end-member Ni-vernadite phase, with surface adsorption acting as a mechanism of transition from one composition to the other. pH series results call into question the viability of Ni crystal-chemistry in natural vernadite as a paleo-proxy for paleo-pH conditions in freshwater systems and challenge the traditional view that structurally incorporated trace-metals are stable within the Eh-pH field of the host mineral phase. Natural birnessite may not be as permanent a sink for Ni as first suggested by Ni crystal-chemistry. 相似文献
13.
探讨了人工合成的高价锰氧化物与紫外光(UV)联用时降解苯酚废水的特性。结果表明,氧化锰矿物在无UV时对苯酚的降解能力差异大,1 g/L的氧化锰4 h对200 mg/L苯酚废水的降解率和COD去除率分别为:锰钾矿97.51%、酸性水钠锰矿89.07%、碱性水钠锰矿11.36%、钙锰矿9.67%;锰钾矿87.79%、酸性水钠锰矿53.11%、碱性水钠锰矿6.42%、钙锰矿1.43%。UV光照下,氧化锰矿物对苯酚的降解率有不同程度的提高,且表现出显著的表面光催化性质,增加了苯酚的深度降解,COD去除率显著提高。UV下氧化锰4 h对苯酚的降解率分别为:锰钾矿99.48%、酸性水钠锰矿91.86%、碱性水钠锰矿40.15%、钙锰矿35.95%);COD的去除率分别为:锰钾矿98.11%、酸性水钠锰矿68.45%、钙锰矿27.57%、碱性水钠锰矿24.27%。MnO2-UV联用时降解苯酚可能包括两种主要作用机制:氧化锰矿物的直接化学氧化降解和UV下MnO2的表面光催化降解。 相似文献
14.
Results of thermic transformations of ore minerals from genetically different oceanic ferromanganese rocks in the course of their heating up to 1000°C are considered. Manganese minerals with various types of crystalline lattice have different grades of thermic stability. Layered manganese minerals (buserite I, asbolane-buserite, and birnessite) are stable up to 120–150°C; asbolane up to 180°C, vernadite, up to ~500°C; todorokite and pyrolusite (minerals of the tunnel group), up to 600 and 670°C, respectively. Sorbed cations of heavy metals govern the transformation temperature and mineral composition of products of the calcination of ferromanganese rocks. Study of birnessite and todorokite demonstrated that genesis of ferromanganese rocks do not affect thermic properties of minerals in them. 相似文献
15.
Mario Villalobos Brandy Toner Garrison Sposito 《Geochimica et cosmochimica acta》2003,67(14):2649-2662
Manganese oxides form typically in natural aqueous environments via Mn(II) oxidation catalyzed by microorganisms, primarily bacteria, but little is known about the structure of the incipient solid-phase products. The Mn oxide produced by a Pseudomonas species representative of soils and freshwaters was characterized as to composition, average Mn oxidation number, and N2 specific surface area. Electron microscopy, X-ray diffraction, and X-ray absorption near edge structure spectroscopy were applied to complement the physicochemical data with morphological and structural information. A series of synthetic Mn oxides also was analyzed by the same methods to gain better comparative understanding of the structure of the biogenic oxide. The latter was found to be a poorly crystalline layer type Mn(IV) oxide with hexagonal symmetry, significant negative structural charge arising from cation vacancies, and a relatively small number of randomly stacked octahedral sheets per particle. Its properties were comparable to those of δ-MnO2 (vernadite) and a poorly crystalline hexagonal birnessite (“acid birnessite”) synthesized by reduction of permanganate with HCl, but they were very different from those of crystalline triclinic birnessite. Overall, the structure and composition of the Mn oxide produced by P. putida were similar to what has been reported for other freshly precipitated Mn oxides in natural weathering environments, yielding further support to the predominance of biological oxidation as the pathway for Mn oxide formation. Despite variations in the degree of sheet stacking and Mn(III) content, all poorly crystalline oxides studied showed hexagonal symmetry. Thus, there is a need to distinguish layer type Mn oxides with structures similar to those of natural birnessites from the synthetic triclinic variety. We propose designating the unit cell symmetry as an addition to the current nomenclature for these minerals. 相似文献
16.
FENG Xionghan TAN Wenfeng LIU Fan Huada Daniel RUAN HE Jizheng 《《地质学报》英文版》2006,80(2):249-256
Oxidation of As^Ⅲ by three types of manganese oxide minerals affected by goethite was investigated by chemical analysis, equilibrium redox, X-ray diffraction (XRD) and transmission electron microscopy (TEM). Three synthesized Mn oxide minerals of different types, birnessite, todorokite, and hausmannite, could actively oxidize As^Ⅲ to Asv, and greatly varied in their oxidation ability. Layer structured birnessite exhibited the highest capacity of As^Ⅲ oxidation, followed by the tunnel structured todorokite. Lower oxide hansmannite possessed much low capacity of As^Ⅲ oxidation, and released more Mn^2+ than birnessite and todorokite during the oxidation. The maximum amount of Asv produced during the oxidation of As^Ⅲ by Mn oxide minerals was in the order: birnessite (480.4 mmol/kg) 〉 todorokite (279.6 mmol/kg) 〉 hansmannite (117.9 mmol/kg). The oxidation capacity of the Mn oxide minerals was found to be relative to the composition, crystallinity, and surface properties. In the presence of goethite oxidation of As^Ⅲ by Mn oxide minerals increased, with maximum amounts of Asv being 651.0 mmol/kg for birnessite, 332.3 mmol/kg for todorokite and 159.4 mmol/kg for hansmannite. Goethite promoted As^Ⅲ oxidation on the surface of Mn oxide minerals through adsorption of the Asv produced, incurring the decrease of Asv concentration in solutions. Thus, the combined effects of the oxidation (by Mn oxide minerals)-adsorption (by goethite) lead to rapid oxidation and immobilization of As in soils and sediments and alleviation of the As^Ⅲ toxicity in the environments. 相似文献
17.
Xiao Xuqi Institute of Mineral Deposits Chinese Academy of Geological Sciences Beijing Guo Shiqin China Ocean Mineral Researches Development Association 《《地质学报》英文版》1993,67(1):33-41
Manganese minerals in the polymetallic nodules from the Central Pacific Ocean were studied using electron microscopy. The principal Mn minerals, being vernadite and todorokite, exhibit different electron diffraction patterns and morphological features. According to its morphological feature, todorokite shows three phases: fibrous, lamellar and lath-shaped. Both vernadite and todorokite are authigenic minerals. While vernadite was mainly precipitated directly from the relevant solution by microbiological oxidation, todorokite was separated from the solution chemically without the help of microbe. Hence, these two minerals show a close genetic relation. 相似文献
18.
Manganese (Mn) oxides are among the strongest oxidants and sorbents in the environment, impacting the transport and speciation of metals, cycling of carbon, and flow of electrons within soils and sediments. The oxidation of Mn(II) to Mn(III/IV) oxides has been primarily attributed to biological processes, due in part to the faster rates of bacterial Mn(II) oxidation compared to observed mineral-induced and other abiotic rates. Here we explore the reactivity of biogenic Mn oxides formed by a common marine bacterium (Roseobacter sp. AzwK-3b), which has been previously shown to oxidize Mn(II) via the production of extracellular superoxide. Oxidation of Mn(II) by superoxide results in the formation of highly reactive colloidal birnessite with hexagonal symmetry. The colloidal oxides induce the rapid oxidation of Mn(II), with dramatically accelerated rates in the presence of organics, presumably due to mineral surface-catalyzed organic radical generation. Mn(II) oxidation by the colloids is further accelerated in presence of both organics and light, implicating reactive oxygen species in aiding abiotic oxidation. Indeed, the enhancement of Mn(II) oxidation is negated when the colloids are reacted with Mn(II) in the presence of superoxide dismutase, an enzyme that scavenges the reactive oxygen species (ROS) superoxide. The reactivity of the colloidal phase is short-lived due to the rapid evolution of the birnessite from hexagonal to pseudo-orthogonal symmetry. The secondary particulate triclinic birnessite phase exhibits a distinct lack of Mn(II) oxidation and subsequent Mn oxide formation. Thus, the evolution of initial reactive hexagonal birnessite to non-reactive triclinic birnessite imposes the need for continuous production of new colloidal hexagonal particles for Mn(II) oxidation to be sustained, illustrating an intimate dependency of enzymatic and mineral-based reactions in Mn(II) oxidation. Further, the coupled enzymatic and mineral-induced pathways are linked such that enzymatic formation of Mn oxide is requisite for the mineral-induced pathway to occur. Here, we show that Mn(II) oxidation involves a complex network of abiotic and biotic processes, including enzymatically produced superoxide, mineral catalysis, organic reactions with mineral surfaces, and likely photo-production of ROS. The complexity of coupled reactions involved in Mn(II) oxidation here highlights the need for further investigations of microbially-mediated Mn oxide formation, including identifying the role of Mn oxide surfaces, organics, reactive oxygen species, and light in Mn(II) oxidation and Mn oxide phase evolution. 相似文献
19.
Layered ferromanganese crusts collected by dredge from a water depth range of 2770 to 2200 m on Mendeleev Ridge, Arctic Ocean, were analyzed for mineralogical and chemical compositions and dated using the excess 230Th technique. Comparison with crusts from other oceans reveals that Fe-Mn deposits of Mendeleev Ridge have the highest Fe/Mn ratios, are depleted in Mn, Co, and Ni, and enriched in Si and Al as well as some minor elements, Li, Th, Sc, As and V. However, the upper layer of the crusts shows Mn, Co, and Ni contents comparable to crusts from the Atlantic and Indian Oceans. Growth rates vary from 3.03 to 3.97 mm/Myr measured on the uppermost 2 mm. Mn and Fe oxyhydroxides (vernadite, ferroxyhyte, birnessite, todorokite and goethite) and nonmetalliferous detrital minerals characterize the Arctic crusts. Temporal changes in crust composition reflect changes in the depositional environment. Crust formation was dominated by three main processes: precipitation of Fe-Mn oxyhydroxides from ambient ocean water, sorption of metals by those Fe and Mn phases, and fluctuating but large inputs of terrigenous debris. 相似文献