基于TM影像的白云岩与石灰岩上喀斯特植被时空变化差异研究

喀斯特土壤主要由白云岩和石灰岩风化而来,植被生长及其分布究竟怎样响应这一特殊地质背景?以人为干扰影响较小的喀斯特自然保护区为研究对象,采用监督分类法对1990年和2011年两期TM影像进行植被分类,并利用景观格局分析方法研究两种岩性上植被变化差异。结果表明,1990年和2011年研究区内两种母岩上均以乔木林和乔灌为主,草灌和草丛分布少,白云岩上乔木林的面积比例大于石灰岩上的比例,而草灌和草丛小于石灰岩上的比例;近20年来白云岩与石灰岩上草丛、草灌、灌丛和乔灌均以正向演替为主,但白云岩上正向演替比例大于石灰岩上的比例;两种岩性上植被斑块连接性均增强、破碎程度均降低,白云岩上植被斑块的破碎化程度和多样性指数较石灰岩上低,内部连接性强。由此可见,喀斯特白云岩较石灰岩有利于草丛、草灌的自然恢复,岩性引起的水土资源配置和养分地球化学循环过程差异制约着喀斯特地区植被的时空格局。     

球形赖氨酸芽孢杆菌(Lysinibacillus sphaericus)和嗜冷芽孢八叠球菌(Sporosarcina psychrophila)介导形成白云石晶体

【目的】白云石(Dolomite)是一种含有钙镁的碳酸盐矿物[CaMg(CO3)2],广泛存在于陆地和海洋等环境并常与油气埋藏共存。尽管白云石(或岩)的发现已经有三百多年的历史,但是对白云石的成因仍然没有定论,地质学上称之为"白云石之谜"。20世纪90年代Vasconcelos C.提出了"微生物白云石模型",为白云石成因的研究带来了新的思路。但是这一模型并不完善,白云石的形成与所介导的微生物生理状态以及环境参数之间的关系不明确。另外,所有报道的实验都是在地表压强条件下进行,无法表征自然界中白云石所处的高压环境。本研究中引入压力这一环境参数,结合菌株本身生理特性参数,综合考察多重因子对微生物介导形成白云岩的影响。【方法】利用球形赖氨酸芽孢杆菌(Lysinibacillus sphaericus)和嗜冷芽孢八叠球菌(Sporosarcina psychrophila)两株具有尿素水解活性的细菌作为生物材料,在不同的温度(15°C和30°C)压强(常压和20 MPa)氧气浓度(常压好氧条件和常压微氧条件)不同的尿素水解活性下进行生物矿化实验。通过SEM(扫描电子显微镜)和EDS(X射线能谱分析)相结合的方法观察沉淀物形貌和矿物成分构成。通过XRD(X射线衍射分析)定性测定碳酸盐矿物沉淀物的种类。【结果】球形赖氨酸芽孢杆菌和嗜冷芽孢八叠球菌在实验中所设计的所有矿化条件下都能够介导形成碳酸盐矿物沉淀。XRD和SEM检测均证实球形赖氨酸芽孢杆菌在30°C的20 MPa微氧条件下能够介导形成不规则菱面型和椭球型白云石。高压条件更有助于白云石的形成。除了白云石晶体,实验中还观察到有其他矿物(如方解石,碳氢镁石,钙镁碳酸石等)。【结论】实验证实球形赖氨酸芽孢杆菌和嗜冷芽孢八叠球菌具有矿化能力,特别是球形赖氨酸芽孢杆菌具有介导形成白云石的能力。微生物介导形成的碳酸盐矿物组分受到微生物的代谢活性以及温度、压力等生物矿化实验条件控制。这一研究结果帮助完善"微生物白云石模型",为解释白云石的深部成因提供数据支持。     

Sabkha and Burrow-Mediated Dolomitization in the Mississippian Debolt Formation,Northwestern Alberta,Canada

Dolomitized burrows in the Mississippian (Visean) Debolt Formation of northwestern Alberta, Canada form the primary reservoir intervals in the Dunvegan gas field. Sedimentological and ichnological analyses suggest a carbonate ramp setting that includes subenvironments such as sabkhas, hypersaline lagoons, restricted subtidal lagoons, intertidal mud flats, and peloidal shoals. Dolomitization occurs primarily within oxidized muds and highly bioturbated sediments, with the primary mode being sabkha-associated precipitation. In this context, dolomitization within the burrows also appears to be mediated by sulfate-reducing bacteria. δ¹⁸O values for dolomite within burrows (mean 2.4‰) are enriched by 1.3‰ relative to calcite values (mean 1.1‰) within the burrows. This degree of fractionation is similar for dolomite and calcite that have precipitated from the same solution. It is therefore suggested that the protodolomite precipitated in equilibrium with calcite rather than by replacement of pre-existing calcite. Isotopic values of δ¹³C measured for dolomite associated with burrows (mean 3.4‰) and matrix (mean 3.5‰) is slightly enriched relative to measured calcite values (mean 3.2‰ for matrix; mean 3.1‰ for burrows). These isotopic trends are common for modern dolomite that has precipitated in equilibrium with seawater where concomitant sulfate reduction and organic carbon-oxidation is inferred to occur near the surface.     

Chemolithotrophic Metal Mobilization from Dolomite

The potential of indigenous chemolithotrophic bacteria to mobilize metals from dolomite in the presence of added ammonium or thiosulfate was studied in a laboratory experiment over a period of 35 days. The rock sample was collected in the Dolomites (Alps, Europe). The average mineralogical composition of the sample was dolomite (89%) and calcite (11%). After 35 days, mobilization of total metal in the rock sample amounted to 3.4% (Ca), 8.5% (Mg), 1% (Al), and 0.9% (Mn) in the presence of a nitrifying culture. In the presence of a sulfur-oxidizing culture, mobilization of total magnesium in the rock sample amounted to 34%.The results contribute to our understanding of interactions between atmospheric deposition of energy substrates, bacterial activity and metal mobilization in Alpine areas.     

Microbial influence on dolomite and authigenic clay mineralisation in dolocrete profiles of NW Australia

Dolomite (CaMg(CO₃)₂) precipitation is kinetically inhibited at surface temperatures and pressures. Experimental studies have demonstrated that microbial extracellular polymeric substances (EPS) as well as certain clay minerals may catalyse dolomite precipitation. However, the combined association of EPS with clay minerals and dolomite and their occurrence in the natural environment are not well documented. We investigated the mineral and textural associations within groundwater dolocrete profiles from arid northwest Australia. Microbial EPS is a site of nucleation for both dolomite and authigenic clay minerals in this Late Miocene to Pliocene dolocrete. Dolomite crystals are commonly encased in EPS alveolar structures, which have been mineralised by various clay minerals, including montmorillonite, trioctahedral smectite and palygorskite-sepiolite. Observations of microbial microstructures and their association with minerals resemble textures documented in various lacustrine and marine microbialites, indicating that similar mineralisation processes may have occurred to form these dolocretes. EPS may attract and bind cations that concentrate to form the initial particles for mineral nucleation. The dolomite developed as nanocrystals, likely via a disordered precursor, which coalesced to form larger micritic crystal aggregates and rhombic crystals. Spheroidal dolomite textures, commonly with hollow cores, are also present and may reflect the mineralisation of a biofilm surrounding coccoid bacterial cells. Dolomite formation within an Mg-clay matrix is also observed, more commonly within a shallow pedogenic horizon. The ability of the negatively charged surfaces of clay and EPS to bind and dewater Mg²⁺, as well as the slow diffusion of ions through a viscous clay or EPS matrix, may promote the incorporation of Mg²⁺ into the mineral and overcome the kinetic effects to allow disordered dolomite nucleation and its later growth. The results of this study show that the precipitation of clay and carbonate minerals in alkaline environments may be closely associated and can develop from the same initial amorphous Ca–Mg–Si-rich matrix within EPS. The abundance of EPS preserved within the profiles is evidence of past microbial activity. Local fluctuations in chemistry, such as small increases in alkalinity, associated with the degradation of EPS or microbial activity, were likely important for both clay and dolomite formation. Groundwater environments may be important and hitherto understudied settings for microbially influenced mineralisation and for low-temperature dolomite precipitation.     

世界自然遗产地陆生藻类物种多样性比较研究

藻类是真核生物进化、植物起源与进化、生物地理学研究的良好材料,研究藻类物种多样性对理解生命起源与早期进化,探明地球地质地貌演化有着非常重要的意义。以两世界自然遗产地施秉云台山白云岩喀斯特、赤水丹霞的陆生藻类为研究对象,通过G-F多样性指数、Jaccard相似性系数、Bray-Curtis矩阵比较分析了不同地质地貌的两世界自然遗产地陆生藻类的物种多样性及种组特征,结果如下：（1）两地陆生藻类丰富,均以蓝藻为优势,共有优势科为色球藻科Chroococcaceae、颤藻科Oscillatoriaceae,施秉云台山还具伪枝藻科Scytonemataceae、念珠藻科Nostocaceae优势,优势属为粘球藻属Gloeocapsa、色球藻属Chroococcus,赤水丹霞仅以粘球藻属Gloeocapsa为优势。（2）施秉云台山G-F多样性指数高于赤水丹霞。（3）两地陆生藻类泛热带成分明显,施秉云台山中国特有成分较赤水丹霞丰富;两地科、属、种相似性系数依次为：56.25%、44.05%、37.62%,科的相似性达到中度水平,与同纬度范围其它地区的Bray-Curtis矩阵聚类结果显示不同地质地貌的两地首先聚为一类。从陆生藻类多样性组成上,初步反映两世界自然遗产地的地质历史、地层岩性及地理位置的异同。     

水洞沟地区白云岩细石叶的微痕实验研究

水洞沟遗址是中国北方旧石器时代晚期的著名遗址,石制品原料以就地取材的白云岩为主。本文利用水洞沟地区的白云岩生产细石叶和石片,进行了29组复制使用实验。对使用痕迹的观察表明:不同加工对象和使用方式导致细石叶上出现不同的微痕特征,细石叶适于装柄使用,以刮、切、削等利用侧刃缘的运动方式效率为高,尖部用于加工硬度较低的动植物效果较好。对比燧石、黑曜岩等不同石料的微痕实验数据可知,不同石料的产品,其使用痕迹存在一定差异。本文对白云岩细石叶的微痕实验,探讨了其适宜的使用方式和加工对象的范围,为分析水洞沟地区出土的白云岩细石叶功能提供了可资参考、对比的实验数据。     

Dolomite limits acidification of a biofilter degrading dimethyl sulphide

The applicability of dolomite particlesto control acidificationin a Hyphomicrobium MS3inoculated biofilter removingdimethyl sulphide (Me₂S) wasstudied. While direct inoculationof the dolomite particles with theliquid microbial culture was notsuccessful, start-up ofMe₂S-degradation in thebiofilter was observed when thedolomite particles were mixed with33% (wt/wt) of Hyphomicrobium MS3-inoculatedcompost or wood bark material.Under optimal conditions, anelimination capacity (EC) of 1680~g Me₂S m^-3 d^-1 wasobtained for the compost/dolomitebiofilter. Contrary to a wood barkor compost biofilter, no reductionin activity due to acidificationwas observed in these biofiltersover a 235 day period because ofthe micro environmentneutralisation of the microbialmetabolite H₂SO₄ with thecarbonate in the dolomite material.However, performance of thebiofilter decreased when themoisture content of the mixedcompost/dolomite material droppedbelow 15%. Next to this, nutrientlimitation resulted in a gradualdecrease of the EC andsupplementation of a nitrogensource was a prerequisite to obtaina long-term high EC (> 250 gMe₂S m^-3 d^-1) forMe₂S. In relation to thisnitrogen supplementation, it wasobserved that stable ECs forMe₂S were obtained when thisnutrient was dosed to the biofilterat a Me₂S-C/NH₄Cl-Nratio of about 10.Abbreviations:DW – dry weight,EC – elimination capacity,Me₂S – dimethyl sulphide,OL – organic loading rate,VS - volatile solids     

Desulfovibrio brasiliensis sp. nov., a moderate halophilic sulfate-reducing bacterium from Lagoa Vermelha (Brazil) mediating dolomite formation

A novel halotolerant sulfate-reducing bacterium, Desulfovibrio brasiliensis strain LVform1, was isolated from sediments of a dolomite-forming hypersaline coastal lagoon, Lagoa Vermelha, in the state of Rio de Janeiro, Brazil. The cells are vibrio-shaped and 0.30 to 0.45 m by 1.0 to 3.5 m in size. These bacteria mediate the precipitation of dolomite [CaMg(CO₃)₂] in culture experiments. The strain was identified as a member of the genus Desulfovibrio in the -subclass of the Proteobacteria on the basis of its 16S rRNA gene sequence, its physiological and morphological properties. Strain LVform1 is obligate sodium-dependent and grows at NaCl concentrations of up to 15%. The 16S rRNA sequence revealed that this strain is closely related to Desulfovibrio halophilus (96.2% similarity) and to Desulfovibrio oxyclinae (96.8% similarity), which were both isolated from Solar Lake, a hypersaline coastal lake in the Sinai, Egypt. Strain LVform1 is barotolerant, growing under pressures of up to 370 bar (37 MPa). We propose strain LVform1 to be the type strain of a novel species of the genus Desulfovibrio, Desulfovibrio brasiliensis (type strain LVform1 = DSMZ No. 15816 and JCM No. 12178). The GenBank/EMBL accession number for the 16S rDNA sequence of strain LVform1 is AJ544687.     

Laboratory Simulations of Cyanobacterial Mats of the Alkaline Geochemical Barrier

The goal of this work was to illustrate a possible interaction between the soda continent and the ocean. A laboratory simulation was undertaken of the development of alkaliphilic mat with calcium carbonate and calcium phosphate interlayers in the zone where ocean waters, containing calcium and manganese, come into contact with carbonate- and phosphate-rich alkaline waters. The macrostructure of the layered cyanobacterial mat turned out to be little dependent on the chemical conditions causing sediment formation. The chemical composition of freshly formed mineral interlayers of the mat was found to vary with the medium composition. The mineralogical composition of the sediment is determined by diagenesis conditions in its depth, which can cause mineral phase conversions.