共查询到20条相似文献,搜索用时 312 毫秒
1.
“白云石(岩)问题”与湖相白云岩研究 总被引:4,自引:1,他引:3
近30年来,微生物白云石模式推动“白云石(岩)问题”前进了一大步,大量的实验和实例证明微生物(硫酸盐还原菌、产甲烷古菌、中度嗜盐有氧细菌等)的代谢活动对于促进白云石低温沉淀起了关键作用。微生物白云石特殊的微结构、微形貌和稳定同位素特征是其主要识别标志。然而,该模式在微生物成岩规模、诱导机制、是否存在纳米细菌化石以及现代微生物白云石成因模式能否用来解释古代白云石的成因等方面仍存在较大争议。我国古代湖相白云岩因其时空分布广、成因机制多样等特点可为“白云石问题”的研究提供良好的条件。 相似文献
2.
四川汉源-峨边地区上震旦统灯影组藻白云岩特征及成因研究 总被引:1,自引:0,他引:1
"藻白云岩"术语的提出已有五十年历史,震旦系藻白云岩以其巨大的厚度,精美的原生结构、构造,以及丰富的微生物化石和矿产资源而闻名,但至今其成因仍存在争议。以四川汉源-峨边地区上震旦统灯影组藻白云岩为研究对象,对其宏观的剖面、岩石学、原生构造特征,微观的白云石和微生物化石形态、原生结构特征,以及相应的地球化学特征进行了详细研究。结果表明:研究区灯影组藻白云岩为一套在潮坪和潟湖环境下形成的微生物(碳酸盐)岩的岩石类型组合,以藻黏结型的叠层状、纹层状、葡萄状和均一状(藻)白云岩为主要的次级类型;藻白云岩中主要发育原生的隐晶状微生物白云石和次生的纤维状拟晶白云石,其形成与蓝细菌、硫酸盐还原细菌、中度嗜盐好氧细菌和红藻等微生物的矿化作用密切相关:沉积-同生阶段,主要由微生物诱导矿化作用形成大量纳米似立方体粒状和(亚)微米级片状微生物白云石,同时共(伴)生纤维状文石和高镁方解石;同生-准同生阶段,主要由微生物影响矿化作用形成纳米球粒状和微米级不规则状、球状和卵状微生物白云石,同时纤维状文石和高镁方解石因微生物催化矿化作用和拟晶白云石化作用形成纤维状拟晶白云石;随后微生物白云石与拟晶白云石一起组成具纹层状、叠层状、均一状等构造的藻白云岩。对藻白云岩特征及成因的研究有助于理解微生物-矿物交互作用和过程的复杂性、多样性,也为前寒武纪微生物矿化作用、微生物白云石和拟晶白云石研究提供了新的实例。 相似文献
3.
《古地理学报》2017,(2)
近年来,随着对微生物白云石模式研究的不断深入,为解释"白云石问题"提供了新思路。前人对微生物白云石成因研究侧重于微生物对未固结沉积物的改造,即有机准同生白云石化作用,这与实验室中以微生物为媒介形成的"有机原生白云石"在成因机理上存在差异。笔者将微生物白云石机理引入湖相原生白云石成因解释中,认为在湖水—沉积物交界处也会发生微生物成因的原生白云石沉淀,即有机原生白云石。湖水与沉积物交界处的微环境存在明显区别,总体可分为有氧和缺氧2种亚环境,不同亚环境中生活有不同的微生物群落。根据湖泊亚环境特性和微生物种类及其在白云石形成过程中所发挥的作用,可以区分出细菌有氧氧化模式、硫酸盐还原模式和产甲烷模式3种微生物白云石模式。不同模式对应于不同的湖泊环境:细菌有氧氧化模式主要发生于有氧、高Mg/Ca值的咸水/盐湖环境;硫酸盐还原模式主要发生于缺氧、高Mg/Ca值的咸水/盐湖环境;产甲烷模式主要发生于缺氧、低Mg/Ca值的淡水/咸水湖环境。另外,还探讨了pH值变化、SO_4~(2-)的存在和硫化物对镁水合物脱水的影响以及微生物白云石沉淀的环境因子。对微生物成因的原生白云石模式的深入认识,将为湖相白云石成因研究提供新的理论基础和研究思路。 相似文献
4.
5.
白云岩成因问题一直是个未解之谜,近年提出的微生物成因模式受到了广泛关注。白云石在现代和古代冷泉环境中普遍发育,以白云石为主的冷泉白云岩主要呈烟囱状和管状产出,微观上可见菱形白云石,也有梭形和哑铃状的白云石。冷泉白云石碳同位素值变化较大,指示了可能主要来源于冷泉渗漏甲烷、海水溶解无机碳、有机质氧化和产甲烷残余的CO2等,而氧同位素值的变化可能与甲烷水合物的生成与分解、黏土矿物的脱水和沉积温度等有关。半封闭的冷泉渗漏环境中的微生物甲烷缺氧氧化和硫酸盐还原作用可能有利于白云石的沉淀。与微生物实验相结合的冷泉白云岩研究可能是"白云岩问题"取得突破的新方向。 相似文献
6.
白云岩是一种常见的碳酸盐岩,它广泛分布在古代碳酸盐岩台地中,却很少见于全新世沉积物中,这构成了一个未解之谜。近20多年的研究成果表明,早期成岩过程中微生物参与的硫酸盐还原反应、甲烷生成和厌氧氧化反应以及有氧呼吸作用能够促进白云石的沉淀:细菌细胞和胞外聚合物(EPS)带有负电荷,能够聚集溶液中Mg2+和Ca2+;同时上述氧化还原反应产生HCO3-,提高了孔隙水中反应物的浓度;这样在细菌细胞周围形成一个对白云石超饱和的微环境,有利于白云石的沉淀。这是一种新的白云石成因模式,微生物活动和有机质是影响白云石形成最重要的因素,特殊的球状形态和碳同位素特征是鉴别有机成因白云石的重要标志。白云岩有机成因模式为认识地质历史时期大套白云岩的成因、探索"白云岩之谜"提供了新的思路。 相似文献
7.
白云石的成因机制一直是地球科学领域备受争论的议题.传统研究多认为白云石为次生成因.新近提出的"微生物(有机)白云石模式"认为该矿物在微生物或有机物作用下可以从溶液中直接沉淀,从而为白云石的成因研究提供了新思路.总结了该模式近20年来取得的重要进展,并指出尚待弥补的环节.微生物的催化机理主要表现为其代谢作用可提高胞外微环境中白云石的饱和度,同时其携带负电荷的细胞外壁可作为白云石晶体的成核位点.微生物成因白云石呈球状、哑铃状和花椰菜形等外貌.高盐度有利于微生物介导低温白云石沉淀,而硫酸根扮演的角色则仍需进一步验证.最新的研究表明微生物胞外聚合物有助于Mg~(2+)摆脱水合作用的束缚,是微生物催化白云石形成的关键.非微生物源的羧基化合物也可通过与胞外聚合物类似的途径在白云石饱和溶液中促进低温白云石形成.微生物(有机)成因白云石为原白云石,而非有序白云石.目前对微生物(有机)成因白云石在成岩改造中的演化过程仍然缺乏认识,是"微生物(有机)白云石模式"的缺失环节,亟待完善. 相似文献
8.
近年来,随着对微生物白云石模式研究的不断深入,为解释“白云石问题”提供了新思路。前人对微生物白云石成因研究侧重于微生物对未固结沉积物的改造,即有机准同生白云石化作用,这与实验室中以微生物为媒介形成的“有机原生白云石”在成因机理上存在差异。笔者将微生物白云石机理引入湖相原生白云石成因解释中,认为在湖水—沉积物交界处也会发生微生物成因的原生白云石沉淀,即有机原生白云石。湖水与沉积物交界处的微环境存在明显区别,总体可分为有氧和缺氧2种亚环境,不同亚环境中生活有不同的微生物群落。根据湖泊亚环境特性和微生物种类及其在白云石形成过程中所发挥的作用,可以区分出细菌有氧氧化模式、硫酸盐还原模式和产甲烷模式3种微生物白云石模式。不同模式对应于不同的湖泊环境: 细菌有氧氧化模式主要发生于有氧、高Mg/Ca值的咸水/盐湖环境;硫酸盐还原模式主要发生于缺氧、高Mg/Ca值的咸水/盐湖环境;产甲烷模式主要发生于缺氧、低Mg/Ca值的淡水/咸水湖环境。另外,还探讨了pH值变化、SO 4 2 -
9.
白云石是沉积岩中广泛存在的碳酸盐矿物,其成因机制一直备受关注.野外调研发现现生白云石多分布于高盐环境,模拟实验也表明嗜盐微生物能诱导形成白云石,但微生物诱导白云石沉淀的机理仍不明确.分别用嗜盐古菌Natrinema sp.J7-1对数后期的活细胞、失去代谢活性的J7-1完整细胞(经线粒体氧化磷酸化解偶联剂处理)、表面蛋白质变性的J7-1细胞(经多聚甲醛和戊二醛处理)和表面富含羧基的微球,在盐度为280‰的沉淀体系中诱导白云石沉淀.分别利用X射线衍射(XRD)分析矿物的物相,扫描电子显微镜(SEM)分析矿物、微生物以及羧基微球的形貌,傅立叶红外光谱(FT-IR)分析细胞变性前后表面的官能团.结果表明,失去代谢活性的J7-1细胞与正常的对数后期细胞均能够诱导原白云石形成;经过多聚甲醛/戊二醛固定后,细胞表面羧基含量降低,不能诱导白云石沉淀;羧基微球能够诱导形成原白云石.以上研究证实细胞表面的羧基可能是微生物促进白云石沉淀的一种关键因素,而细胞的生长代谢在本研究的条件下不是控制白云石沉淀的主要因素. 相似文献
10.
白云石成因研究新方法--白云石晶体结构分析 总被引:6,自引:0,他引:6
传统的白云石研究方法对于白云石成因分析具有多解性,对于已有白云石成因模式的套用或重新建立新的白云石成因模式将白云石的形成机理过于简单化、模式化。白云石的晶体结构保存了晶体的形成环境、结晶速度、晶体生长与变化特征、流体特征的证据,白云石晶体结构分析是进行白云石成因分析的有效手段,之前很少有研究者从晶体结构角度进行白云石成因分析。在岩石学和地球化学研究的基础上,本文对四川盆地灯影组-寒武系鞍状白云石、纤状白云石、残余颗粒细晶白云石、孔洞充填粗晶白云石和泥晶白云石五种白云石进行了微组构取样,并利用X衍射仪、透射电镜等晶体结构研究手段,从晶体结构角度对五种白云石组构的有序度、晶胞参数、晶格条纹、晶面间距、晶格缺陷等晶体结构参数进行了差异性研究,分析了它们不同的形成环境和成岩演化特征,初步建立了不同类型白云石晶体结构判识标志。 相似文献
11.
Dolomite Mountains and the origin of the dolomite rock of which they mainly consist: historical developments and new perspectives 总被引:3,自引:0,他引:3
Beginning in the late 18th Century, the Dolomite Mountains in Northern Italy have been the location for major sedimentological developments, from the discovery of the mineral dolomite to the formulation of the coral-reef hypothesis to explain the origin of the massive dolomite structures that define the splendid scenery of the region. Further, the Dolomite Mountains have inspired voluminous research into the origin of dolomite, questioning whether dolomite is a primary precipitate or a secondary replacement product. Recently, with the recognition that microbes can mediate dolomite precipitation, a new geomicrobiological approach, combining the study of modern natural environments with bacterial culture experiments, is now being used to calibrate or interpret microbial evidence derived from the dolomite rock record. This three-pronged methodology applied to the study of dolomite formation holds great promise for future research into the 'Dolomite Problem' and provides a new impetus to revisit the Dolomite Mountains in the 21st Century. 相似文献
12.
《Applied Geochemistry》2004,19(2):215-230
Sources of As in the Ganges sediments and microbial mechanisms of its release in groundwater were examined in the present study, where the authors have systematically examined the pertinent mineral species present in the sediments using XRD, TEM-EDS and EPMA techniques. The results show several As-bearing minerals in the Ganges sediments, in western Bangladesh. Iron-sulfide minerals consist of near-amorphous and/or crystalline precursors of framboidal pyrite and pyrite both of which contain As. Several types of Fe oxyhydroxides (oxides), which contain variable amounts of As were also found in muddy sediments. The content of As increases from Fe-oxides to the precursors of framboidal pyrite and pyrite. Four different chemical forms of As from the core sediments were determined. The sequentially extracted chemical forms are as follows: (1) acid soluble form (As mainly fixed in carbonates), (2) reducible form (As fixed in Fe- and/or Mn-oxides), (3) organic form, (4) insoluble form (As fixed mainly in sulfide and rarely in silicate minerals). Arsenic is dominantly sorbed on to Fe- and/or Mn-oxides, organic forms and sulfide minerals in most samples, although their relative abundances differ in different samples. Geomicrobial culture experiments were carried out to test the hypothesis that microbial processes play a key role in the release of As in groundwater. Batch culture and circulating water system experiments were designed using the sediments from Bangladesh. In the batch experiments, As was released at low Eh values a few days after adding nutrients containing glucose, polypepton and yeast extract, urea and fertilizer under a dominantly N2 atmosphere. This contrasts with the control experiments without nutrients. Circulating water experiments with sand layer in a N2 atmosphere showed similar results. These results support the hypothesis that microbial processes mediate the release of As into groundwater under reducing conditions. Glucose and polypepton used in the experiments may correspond to C and N sources, respectively. Younger sediments contain abundant organic matter, which is easily used by bacteria. So, the enhanced bacterial activity may correspond to simulation of accelerated natural diagenetic process using organic matter, or some fertilizer/wastewater effects. 相似文献
13.
Precipitation of dolomite using sulphate-reducing bacteria from the Coorong Region, South Australia: significance and implications 总被引:9,自引:0,他引:9
Dolomite was successfully precipitated in culture experiments that simulated microbiogeochemical conditions prevailing during late stages of evaporation in ephemeral, hypersaline dolomitic lakes of the Coorong region, South Australia. Analyses of lake- and pore-water samples document rapid geochemical changes with time and depth in both dolomitic and non-dolomitic lakes. Extremely high sulphate and magnesium ion concentrations in lake waters decline rapidly with depth in pore waters throughout the sulphate-reduction zone, whereas carbonate concentrations in pore waters reach levels up to 100 times those of normal sea water. Ultimately, sulphate is totally consumed and no solid sulphate is recorded in the dolomitic lake sediments. ‘Most probable number’ calculations of lake sediment samples record the presence of large populations of sulphate-reducing bacteria, whereas sulphur-isotope analyses of lake-water samples indicate microbial fractionation in all the lakes studied. Viable populations of microbes from the lake sediments were cultured in anoxic conditions in the laboratory. Samples were then injected into vials containing sterilized clastic or carbonate grains, or glass beads, immersed in a solution that simulated the lake water. Falls in the levels of sulphate and rising pH in positive vials were interpreted as indicating active bacterial sulphate reduction accompanied by increased concentrations of carbonate. Within 2 months, sub-spherical, sub-micron-size crystals of dolomite identical to those of lake sediments were precipitated. It is concluded that bacterial sulphate reduction overcomes kinetic constraints on dolomite formation by removing sulphate and releasing magnesium and calcium ions from neutral ion pairs, and by generating elevated carbonate concentrations, in a hypersaline, strongly electrolytic solution. The results demonstrate that bacterial sulphate reduction controls dolomite precipitation in both the laboratory experiments and lake sediments. It is proposed that dolomite formation, through bacterial sulphate reduction, provides a process analogue applicable to thick platformal dolostones of the past, where benthic microbial communities were the sole or dominant colonizers of shallow marine environments. 相似文献
14.
Iron biominerals can form in neutral pH microaerophilic environments where microbes both catalyze iron oxidation and create polymers that localize mineral precipitation. In order to classify the microbial polymers that influence FeOOH mineralogy, we studied the organic and mineral components of biominerals using scanning transmission X-ray microscopy (STXM), micro X-ray fluorescence (μXRF) microscopy, and high-resolution transmission electron microscopy (HRTEM). We focused on iron microbial mat samples from a creek and abandoned mine; these samples are dominated by iron oxyhydroxide-coated structures with sheath, stalk, and filament morphologies. In addition, we characterized the mineralized products of an iron-oxidizing, stalk-forming bacterial culture isolated from the mine. In both natural and cultured samples, microbial polymers were found to be acidic polysaccharides with carboxyl functional groups, strongly spatially correlated with iron oxyhydroxide distribution patterns. Organic fibrils collect FeOOH and control its recrystallization, in some cases resulting in oriented crystals with high aspect ratios. The impact of polymers is particularly pronounced as the materials age. Synthesis experiments designed to mimic the biomineralization processes show that the polysaccharide carboxyl groups bind dissolved iron strongly but release it as mineralization proceeds. Our results suggest that carboxyl groups of acidic polysaccharides are produced by different microorganisms to create a wide range of iron oxyhydroxide biomineral structures. The intimate and potentially long-term association controls the crystal growth, phase, and reactivity of iron oxyhydroxide nanoparticles in natural systems. 相似文献
15.
J. Akai A. Kanekiyo N. Hishida M. Ogawa T. Naganuma H. Fukuhara H.N. Anawar 《Applied Geochemistry》2008
Arsenic release experiments using natural indigenous microbial assemblages and natural sediment samples in Bangladesh have been performed. The As release appears to be facilitated by moderate organic input. Addition of some nutrients caused reducing conditions, which may generate the appropriate environment for Fe-reducing bacteria to become active. Detailed cellular phospholipid fatty acid (PLFA) analysis suggests the presence of SO4-reducing and Fe-reducing bacteria in the sediments. These Fe-reducing bacteria may serve as the agents catalyzing As release in the organic-rich sediments. 16S rDNA analysis of one cultured sample suggests the presence of clostridia, some of which are known to mediate Fe reduction. Based on new PLFA analyses, it is proposed that combined microbial processes of SO4 reduction to generate anaerobic conditions and Fe reduction to co-reduce As are important biogeochemical factors for As release in the Bangladesh sediments. 相似文献
16.
Felix Bilek 《Environmental Geology》2006,49(5):674-683
Dump groundwaters in the former East-German lignite-mining district are characterized by high amounts of ferrous iron and
sulphate. Both the pyrite weathering products endanger the surface water quality when discharged into lakes. Only the precipitation
of both contaminants in the subsurface can prevent the further contamination of surface waters. The two-step process of microbial
catalyzed sulphate reduction and iron sulphide precipitation is limited by the low availability of natural organic substances
as electron donators. Therefore, a new remediation technique is developed based on the injection of a liquid organic electron
donator (methanol) into the contaminated aquifer. The saturated aquifer is used as a bioreactor, where iron monosulphides
are precipitated in the groundwater-filled pore space. Column experiments were performed under natural pressure and temperature
conditions with natural anoxic groundwater and original sediments to test the remediation technology. The test showed that
a complete iron removal (4 mmol/l), even under rather acid conditions (pH 3.8), is possible after having established an active
sulphate reducer population. The turnover of the added organic substance with sulphate is complete and the amount of the resulting
sulphide controls the effluent pH. In addition, intensified microbial activity triggers the turnover of natural organic substances.
Also, natural Fe(III) hydroxides react with the sulphide produced. Considering the long natural retention times (decades),
artificially enhanced FeS precipitation is spontaneous, although it shows kinetic behaviour in the range of days. In light
of the promising results, the development of a field scale application of this technique is considered to be necessary. It
will have to focus on the improved precipitation control of the FeS in the subsurface. 相似文献
17.
This study demonstrates discernible biosilicification of natural microbial mats through batch laboratory experiments. Identification of the geochemical requirements for this process to occur includes thermodynamically favorable, but sluggish silica reaction kinetics associated with acidic conditions, and the necessity for colloidal silica rather than dissolved silicic acid species. This study provides the first results to bridge the apparent literature discrepancy between widespread, in-situ observations of microbial silicification, and the inability to demonstrate a detectable microbial impact in this process under well-constrained laboratory conditions. We compared the silica scavenging abilities of three natural microbial mats collected from Yellowstone National Park (YNP) hotsprings, relative to those of both abiotic particle (TiO2) and solution controls at constant, near-saturated aqueous silica concentrations, while experimental pH and temperature conditions were varied, using both dissolved and colloidal SiO2 forms. We specifically evaluated three microbial mats sampled from YNP sites all exhibiting saturation with respect to amorphous SiO2, but possessing variable pH and temperature conditions that should reflect differential kinetics (and therefore biological opportunity) relative to silica polymerization: (1) most biologically favorable, acidic-mesophile (AM: pH 3, T = 35 °C); (2) biologically possible, but less opportune, alkaline, mesophile (ALK-M: pH 8, T = 35 °C) and (3) unlikely to be biologically favorable, alkaline-thermophile (ALK-T: pH 8, T = 80 °C). Comparison of field and laboratory results substantiates the requirements for thermodynamically favorable, but kinetically slower SiO2 polymerization conditions. Results show that acidic moderate temperature conditions were required for an observable biosilicification impact. Moreover, they also identified for the first time, the necessity specifically for colloidal silica forms which are surface bound under acidic pH conditions, to distinguish discernible biosilicification compared to mineral particle controls. Results also highlight the important influence of mat surface characteristics in this process, specifically the extent of live, non-mineralized, exposed biological mat surface. Greater colloidal SiO2 scavenging abilities are associated with non-mineralized microbial mat surfaces than with mineral particle surfaces or microbial mat surfaces encrusted with authigenic silica. These results are the first to demonstrate that biosilicification can be a microbially mediated, discernible geobiological process, shedding new light on the longstanding argument in the literature, and opening the door for more sensitive evaluation of this phenomenon in natural systems. 相似文献
18.
为查明土著微生物活动对高砷地下水形成的影响,利用河套平原高砷地下水中分离出的土著微生物(YH002)进行了微宇宙实验研究.实验结果表明: 高砷地下水中加入的葡萄糖提供了微生物生长所需要的碳源,微生物大量繁殖,分泌的有机酸使溶液的pH值降低.在缺氧条件下,溶液中的OD值最高达到了0.189,pH值最低为6.22;在有氧条件下,OD值最高达到了0.286,pH值最低为6.04.溶液中As(III)的初始质量浓度为74 μg/L,占总砷质量浓度的11.2%,在加入微生物和葡萄糖后,在缺氧和有氧条件下,As(III)的质量浓度分别为278 μg/L和310 μg/L,占总砷质量浓度的42%和47%.微宇宙实验说明地下水中的土著微生物能将As(V)还原成As(III). 相似文献
19.
“白云石问题”无疑是地质学上最有趣最长久的难题之一。作为一种常见的碳酸盐矿物,白云石在地质历史时期大量 发育,却在现代海洋沉积环境中鲜少沉积,并且在实验室模拟海水条件下也几乎无法低温合成。白云石[CaMg(CO3)2]不同于 Ca2+、Mg2+无序的高镁方解石,具有阳离子有序超结构,空间群为R-3,在地表条件下为热力学稳定相。尽管人们尝试模拟 自然界中白云石存在的物理化学条件,但却几乎没有从实验中成功合成有序白云石。在已有的实验室研究中,有序白云石 仅能通过高温水热实验形成。这说明白云石的形成极可能是一个动力学控制过程。而近些年被人们广泛接受的白云石微生 物成因模式认为微生物活动是低温白云石形成的关键,相关的微生物矿化实验也证实微生物的存在能够促进高镁方解石的 形成。对白云石问题的探讨不仅对理解白云岩成因具有重要意义,还能够促进矿物学理论研究发展。此次研究从高温合成 实验、低温合成实验、微生物协同沉淀实验等方面综述了有关白云石问题的实验室研究进展,阐明了目前对于白云石问题 认识的局限,有助于更好的理解“白云石问题”和其中所包含的矿物学和物理化学问题,乃至于帮助寻找到它的答案。 相似文献
20.
微生物异养反硝化技术是市政污水处理中广泛应用的技术,但在实际应用中,微生物活性易受冲击负荷、重金属胁迫等环境条件影响,使出水效果不稳定。麦饭石作为一种天然硅酸盐矿物,能有效提高微生物活性及对环境胁迫的抗性,可以将其应用于微生物污染治理领域。通过批实验研究麦饭石的剂量、处理方式对异养反硝化的促进作用并探究麦饭石作用于微生物的机理。结果表明,麦饭石的投加剂量和处理方式均显著影响了微生物对硝酸盐的去除效果。硝酸盐去除率与麦饭石投加量呈正相关,麦饭石投加量为350 g/L时硝酸盐去除率可达96%,未添加麦饭石的空白组硝酸盐去除率仅为25%;处理方式会影响麦饭石对反硝化过程的强化作用,研磨后过200目筛的麦饭石在投加量<150 g/L时具有优势,投加量继续增大后,未经处理的麦饭石表现出更强的反硝化促进作用。进一步采用未经处理的麦饭石、研磨后过200目筛麦饭石及球磨麦饭石浸出液进行反硝化的促进实验及微生物毒性实验探究麦饭石作用于微生物的机理。实验结果表明,麦饭石浸出液能够提高微生物的活性及对环境胁迫的抗性,影响麦饭石生物促进作用的主要因素为其溶出微量元素的成分及浓度。本研究为天然矿物麦饭石应用于微生物污染治理提供理论依据和实际应用价值。 相似文献