内蒙古胜利煤田0-1孔煤中微量元素地球化学特征

运用电感耦合等离子体质谱和煤质分析等技术方法,对内蒙古胜利煤田0-1号钻孔揭露的早白垩世1、2和4号煤层(共20个煤分层,1个夹矸)进行了研究。结果显示,1、2号煤层的挥发分产率大于44%,透光率小于50%,煤类为褐煤;4号煤层挥发分产率42%,透光率53%,煤类为次烟煤(长焰煤);1、2号煤层灰分和硫含量较高,4号煤层灰分和硫含量较低。与世界煤微量元素含量平均值相比,1、2和4号煤层中Sb富集,V、Zr、Nb、Hf、W等元素轻微富集,其它微量元素的含量接近或低于世界煤含量的平均值。1、2和4号煤层中稀土元素和钇(REY)含量较低,根据上地壳标准值(La/Lu)N比值,所有煤分层均显示重稀土富集类型特征,而煤中泥岩夹矸则显示轻稀土富集类型特征。     

贵州小牛井田煤的地球化学特征及古海平面变化

基于贵州水城小牛井田晚二叠世煤样的全硫分、微量元素、常量元素等测试数据,探讨了煤中元素富集特征及其与陆源碎屑的关系,重点是全硫分、微量元素对古海平面变化的反演。结果表明,小牛井田煤中常量元素Si、Ca、Mg、Ti、K含量高于中国煤均值,Al、Fe、Na含量低于中国煤均值;与地壳克拉克值相比,煤中微量元素只有B和Mo相对富集;煤中微量元素的富集在一定程度上受控于陆源碎屑,常量元素对陆源碎屑也有一定的继承性。煤中全硫分及微量元素B、Co、Cr、Cu、Ga、Ge、Mo、Ni、Pb、Sr、V、Zn的纵向变化规律可以用来反演古海平面变化,海退时形成的煤层全硫分及微量元素含量较低,海侵时形成的煤层全硫分及微量元素含量较高。      

准东煤田煤地球化学特征

利用电感耦合等离子原子发射光谱和电感耦合等离子质谱仪对准东煤田不同勘探区煤样中常量和微量元素含量进行测定,对准东煤田主要勘探区煤地球化学特征与中国和世界范围煤地球化学特征进行较系统对比.划分煤中微量元素组合特征,归纳各区内煤的常量与微量元素亲和性.较系统地揭示了准东煤田煤中微量元素丰度和赋存状态,对煤田大规模资源开发利用地球化学环境条件及煤中伴生元素工业利用提供参考.     

古泥炭沉积环境及其对微量元素的控制:以宁武煤田东露天煤矿11#煤层为例*

古泥炭形成时期沉积环境对煤中微量元素的富集具有重要的影响,而煤相和相关地球化学参数是指示古泥炭沉积环境的重要标志。以宁武煤田平朔矿区东露天煤矿11#煤层为例,利用煤相参数、地球化学参数和矿物学特征对东露天11#煤层的古泥炭沉积环境进行了重建,并探讨了沉积环境对微量元素富集的影响。结果表明: (1)东露天煤矿11#煤层煤相类型包括障壁岛潟湖低位沼泽相、下三角洲平原低位沼泽相和上三角洲平原低位沼泽相3种类型,受海侵影响,沼泽水体pH、古盐度、氧化还原状态和水动力条件呈现动荡变化; (2)11#煤层中元素Li(平均133.50 μg/g)、Zr(平均198.12 μg/g)和Pb(平均60.76 μg/g)含量远高于世界硬煤; (3)微量元素在11#煤层剖面中表现为2种不同的组合,即Li-Zr-Nb-Ta-Hf组合和Pb-Cu-Ga-Ge-Tl-REY组合,前者主要在DLT-11-2、DLT-11-6和DLT-11-10这3个层位富集,这些层位具有相似的沉积环境,为海水(咸水)、酸性、缺氧—还原、水动力较强、硫含量相对较低的障壁岛—潟湖低位沼泽相,而后者主要在DLT-11-0、DLT-11-4和DLT-11-8这3个层位富集,沉积环境也相似,为海水(咸水)、碱性、氧化或缺氧、水动力较弱、硫含量相对较高的下三角洲平原低位沼泽相。该成果将为含煤盆地关键金属矿产资源的勘探开发和煤炭资源的清洁利用提供理论依据。     

济宁煤田煤中微量元素的地球化学研究

阐述了研究煤中微量元素的意义,对研究区及采样方法作了介绍,在测试分析资料的基础上,探讨了济宁煤田煤中微量元素在各井田内的平面变化特征和微量元素在不同煤层、同一煤层中垂向上的分布变化规律,初步研究了煤中微量元素的赋存状态,分析了煤中微量元素富集的原因,为今后济宁煤田煤的综合开发和利用提供了重要的参考资料。     

东胜煤田深部区煤质特征研究

东胜煤田深部区延安组主要发育2-6五个煤组,含煤26层,煤层总厚度5.9～36.7m,根据33个钻孔293个煤样的煤质分析结果,研究区各煤层有机显微组分均以镜质组为主,含量为51.4%～83.0%,惰质组占17.0%～48.0%,煤中矿物质含量为0.18%～14.5%,以粘土矿物为主。从下到上镜质组含量有所增加,常量元素含量较稳定。本区煤类属不粘煤,工业利用以动力用煤为主,因有害元素总体含量较低,其利用不会对环境产生影响。     

淮北煤田二叠纪煤中稀土元素地球化学研究

从淮北煤田二叠系10,7,5,4和3煤层中采集34个样品,采用等离子体质谱（ICP-MS）、中子活化（INNA）、等离子体发射光谱（ICP-AES）等方法对样品中主量元素和稀土元素进行了测试,利用X射线衍射等方法对煤中矿物质及其煤质参数进行了测定。在各种测试的基础上,全面分析了稀土元素含量特征、空间分布规律、地球化学参数和分布模式,探讨了淮北煤田二叠纪煤中稀土元素的主要来源及其在煤中的主要赋存方式。研究表明：与华北和国内外其他地区相比,本区煤层中稀土元素相对富集;产于石盒子组煤中的稀土元素含量高于山两组的,在同一煤层中自下而下稀土元素含量有增高趋势,在顶底板中可能出现富集。Ce呈正异常,Eu明显负异常,不同煤层稀土元素的分布模式相似,稀土元素和灰分具有较好的正相关,∑REE与灰分、灰分中的主要元素以及典型陆源灰分中的微量元素正相关,与反映海相的低灰组分相关性较差。结合煤中矿物质的X射线衍射结果,分析获知,淮北煤田二叠纪成煤环境基本不受海水影响,稀土元素主要由陆源供给,而且主要赋存在以高岭石、伊利石为主的粘土矿物中。     

赣东北晚二叠和晚三叠煤的微量元素对比研究

通过对赣东北晚二叠世和晚三叠世煤的微量元素对比研究，阐述了这两种类型煤中常量和微量元素的含量和赋存特征。通过煤质特征，矿物学和元素的组相关性分析，概括了引起这两种类型煤常量和微量元素之间差弄的地质原因。     

贵州黔西煤田白岩脚矿区煤中硫的分布规律

通过对黔西煤田白岩脚矿区龙潭组主要煤层进行化验分析,认为矿区煤中硫含量从低到高均有分布,垂向上自下而上逐渐降低,平面上9、14及15煤总体呈现东北部高西南部低的趋势,4煤层则表现为西南部相对较高;硫的赋存形态以硫化物硫为主,沉积环境控制了煤中硫的含量及各种形态硫的分布;9、14煤层以硫化物硫为主,脱硫效果良好,15煤层以有机硫为主,脱硫效果一般。建议在矿山开发过程中对低硫煤和高硫煤进行配采。     

渭北煤田下峪口矿二叠纪煤中稀土元素地球化学研究

运用电感耦合等离子体质谱（ICP MS）对渭北煤田韩城下峪口矿二叠纪主采煤层及其顶底板中的稀土元素进行了测定。在此基础上,全面分析了稀土元素的含量特征和分布模式,探讨渭北煤田二叠纪煤中稀土元素的主要来源及赋存状态。结果表明：与华北和中国煤均值相比,本区煤层中稀土元素相对不富集,∑REY平均含量为87.70 μg/g;剖面上,2号煤中稀土含量稍高于3号煤,3号煤层中自上而下,稀土元素含量呈降低的趋势,在顶底板中出现富集。研究区煤层中轻稀土元素相对于重稀土元素明显富集,Ce呈微弱正异常,成煤沼泽受海水的影响程度较小。Eu明显负异常,且∑REY含量与CaO含量呈负相关关系,说明当时的成煤环境为酸性还原环境。煤层与其顶底板样品中稀土元素分布模式相似,成煤期间物质来源基本一致,陆源物质供应相对稳定。煤中稀土元素含量与灰分呈不太显著的正相关关系（R=0.216）,表明煤中稀土元素可能以无机态和有机吸附态共存。     

淮南张集矿区煤中微量元素的含量分布特征分析

在采用ICP-AES对张集7个煤层144个样品微量元素含量测试分析的基础上,探讨了元素在不同煤层中的变化规律及其在煤层对比中的应用。结果表明:张集矿区煤中元素B、Se和As含量偏高;不同煤层中微量元素含量变化较大,但具有一定的规律性,其中在9煤层中元素Ba和Cr含量最低,Mn、Zn、As和Se含量相对较高,可以利用这些元素分布特征来区别和划分相邻煤层。     

The occurrence of potentially hazardous trace elements in five Highveld coals, South Africa

Permian coals of the southern hemisphere are generally considered to contain lower concentrations of sulfides, halogens, and trace elements when compared to northern hemisphere Carboniferous coals. Few studies have considered the trace element content in South African coals, and little or no work has been published for Highveld coals. Of the nineteen coal fields in South Africa, the Highveld coal field is one of the nine currently producing, and is second largest in terms of production. Five run of mine samples and a high ash middlings product from the Number 4 Lower seam were analyzed, totaling six sample sets. Fourteen trace elements (As, Cd, Co, Cr, Cu, Hg, Mn, Mo, Ni, Pb, Sb, Se, V, and Zn) were selected for this study based on the global perception that these elements may be hazardous to human health and/or the environment when they are released during coal utilization. Several sample preparation techniques were tested using certified reference materials (SARMs 18, 19 and 20) to determine the most repeatable technique for these coals. The samples were analyzed by ICP-AES and CVAA (Hg only). Microwave digestion proved to be generally unreliable despite the utilization of several different methods. A slurry direct injection method into the ICP-AES provided good correlations with the reference material, but requires further development to enhance the confidence level in this relatively unexplored technique. Samples prepared based on three ASTM standards for the determination of trace elements in coal provided repeatable results in most instances, and were the preparation methods utilized for the Highveld coals.The trace element values determined for the Highveld coals are generally in good agreement with values available in literature for South African coals, with the exception of Hg, Mn and Cr. Hg values reported here are lower, Cr and Mn higher. Results generally agree well with analyses on the same samples conducted by the United States Geological Survey. When considering the global ranges for trace elements, the Highveld range values are within Swaine's range boundaries with the exception of Cr. Compared to the cited global average values for the fourteen trace elements determined, the values obtained for the Highveld coals generally fall below or well below these average values, with the exception of Cr and Mn. Concentrations of Cd and Cu are lower compared to global average values, and As, Mo, Pb, Se, Sb, and Zn can be considered low to very low. Arsenic is ten times lower compared to typical USA values. Concentrations of Co and Ni are similar to global averages, with V and Hg being very slightly higher. The middlings samples reported higher concentrations of most elements, related to the higher ash content of these samples. Of interest, the chalcophile elements determined are all depleted in the Highveld coals compared to global averages, and the siderophile elements are enriched or comparable to global averages.Risk-based health studies in the USA on coals with similar or higher Hg and significantly higher As contents have not reported negative health effects, and therefore it could be assumed that the mobilization of these trace elements from the five Highveld coals are unlikely to cause human health problems. Work is ongoing to determine the modes of occurrence of these HAPs and to address the partitioning behaviors and speciation states of these elements during coal utilization.     

鸡西煤的无机地球化学研究

鸡西煤田是东北地区重要的炼焦煤基地，由于受成煤环境的影响，原煤灰分较高，影响了煤炭精细加工利用和环境。采用Ｘ射线衍射、红外光谱等分析方法对鸡西煤的无机地球化学特征研究显示，煤中的主要矿物为石英、方解石、粘土矿物、黄铁矿和菱铁矿等，它们分别以不同的状态赋存于有机质中。煤灰的主要成分为ＳｉＯ２和Ａｌ２Ｏ３，其主要源自流水带入泥炭沼泽的石英和粘土等同生矿物。元素分析表明，煤中硫、磷及微量元素锗和镓等含量较低。     

山西平朔安太堡露天矿9号煤层中的微量元素

使用ＩＣＰ－ＡＥＳ方法对安太堡露天矿９号煤层中的微量元素进行了系统测定,检测出５３种微量元素,将研究煤样的平均微量元素质量分数与世界范围微量元素平均质量分数相比较,煤样中Ｌｉ,Ｇａ,Ｓｒ,Ｚｒ,Ｎｂ,Ｓｎ和Ｔａ具有较高的富集,而Ｃｒ,Ｃｏ,Ｎｉ,Ｇｅ,Ｒｂ,Ｙ,Ｃｓ和Ｂａ具有较低的富集,研究资料表明不同微量元素在垂向剖面上其质量分数具有不同的分布特征。经相关分析表明：（１）与镜质组含量相关的元素有     

Concentration and distribution of trace elements in some coals from Northern China

The concentration, distribution and modes of occurrence of trace elements in thirty coals, four floors and two roofs from Northern China were studied. The samples were collected from the major coalfields of Shanxi Province, Shaanxi Province, Inner Mongolian Autonomous Region, and Ningxia Hui Autonomous Region. The concentrations of seventeen potential hazardous trace elements, including Hg, As, Se, Pb, Cd, Br, Ni, Cr, Co, Mo, Mn, Be, Sb, Th, V, U, Zn, and five major elements P, Na, Fe, Al, and Ca in coals were determined.Compared with average concentration of trace elements in Chinese coal, the coals from Northern China contain a higher concentration of Hg, Se, Cd, Mn, and Zn. They may be harmful to the environment in the process of combustion and utilization. Vertical variations of trace elements in three coal seams indicated the distributions of most elements in coal seam are heterogeneous. Based on statistical analyses, trace elements including Mo, Cr, Se, Th, Pb, Sb, V, Be and major elements including Al, P shows an affinity to ash content. In contrast, Br is generally associated with organic matter. Elements As, Ni, Be, Mo, and Fe appear to be associated with pyrite. The concentrations of trace elements weakly correlate either to coal rank or to maceral compositions.     

枣庄煤田太原组煤中微量元素地球化学特征

采用中子活化法测定了山东枣庄煤田晚古生代太原组高硫煤层中的微量元素质量分数 ,用数理统计方法取得了高硫煤中微量元素的浓度分布范围、平均值和变异系数 ,用逐步聚类分析法和相关分析法分析了微量元素的共生组合关系 ,并用扫描电镜 -能谱分析了不同煤岩组分的微量元素浓度 ,在此基础上结合形态硫分析结果和沉积相分析结果 ,讨论了高硫煤中微量元素的富集因素、聚集机理和成因背景 ,指出受海水影响的沼泽沉积环境不但对煤中形态硫的分布和含量有控制作用 ,同时对煤中微量元素的浓度和共生组合特点也有影响。太原组高硫煤中的微量元素按其成因可分成两组 ,一组是陆源碎屑富集型 ,其含量直接与煤中灰分产率呈正相关关系 ;另一组为盆地内部沉积 -生物作用富集型元素 ,海水的入侵和盆地介质的停滞还原条件和陆源碎屑物质输入量的减少最有利于沉积 -生物作用型元素的富集 ,并以有害元素 Cu、As、 U、 Pb、 Mo、 Sr和 Co的富集为特征。煤中黄铁矿及其他硫化物是许多有害元素的重要载体 ,充分凝胶化的富氢镜质体比其他组分承载和吸附有更多的有害元素。深入研究不同煤层的有害元素的有机亲和性有利于指导煤的合理利用和采用有效的有害元素的去除措施 ,以利于煤的有效和洁净利用     

辽宁北票地区煤中微量元素研究

对辽宁北票地区煤中微量元素进行了研究 ,将研究区煤中微量元素的平均质量分数与世界范围煤的微量元素的平均质量分数进行比较 ,发现北票煤中的Cr、Co、Ni、As、Sr、Y、Zr、Ba、Ta、Sc具有较高的富集 ,而Sn、U具有较低的富集 ,这种差异可能主要与聚煤区域的地球化学背景有关。计算了微量元素之间的相关系数 ,得出北票地区煤中稀土元素总量较世界范围稀土元素总量的平均值偏高 ,且煤中稀土元素分布模式十分相似 ,表明在成煤期间陆源物质供应相对稳定。煤中矿物主要为高岭石、石英及方解石及少量的伊利石 ,并对其中的地质成因进行了初步解释。     

Determination of elemental affinities by density fractionation of bulk coal samples from the Chongqing coal district, Southwestern China

The occurrence and distribution of major and trace elements have been investigated in two coal-bearing units in the Chonqing mining district (South China): the Late Permian and Late Triassic coals.The Late Permian coals have higher S contents than the Late Triassic coals due to the fixation of pyrite in marine-influenced coal-forming environments. The occurrence of pyrite accounts for the association of a large number of elements (Fe, S, As, Cd, Co, Cu, Mn, Mo, Ni, Pb, Sb, Se, and Zn) with sulphides, as deduced from the analysis of the density fractions. The marine influence is probably also responsible for the organic association of B. The REEs, Zr, Nb, and Hf, are enriched by a factor of 2–3 with respect to the highest levels fixed for the usual worldwide concentration ranges in coal for these elements. The content of these elements in the Late Permian coal is higher by a factor of 5–10 with respect to the Late Triassic coal. Furthermore, other elements, such as Cu, P, Th, U, V, and Y, are relatively enriched with respect to the common range values, with maximum values higher than the usual range or close to the maximum levels in coal. The content of these elements in the Late Permian coal is higher than the Late Triassic coal. These geochemical enrichments are the consequence of the occurrence, in relatively high levels, of phosphate minerals, such as apatite, xenotime, and monazite, as deduced from the study of the density fractions obtained from the bulk coal.The Late Triassic coal has a low sulphur content with a major organic affinity. The trace element contents are low when compared with worldwide ranges for coal. In this coal, the trace element distribution is governed by clay minerals, carbonate minerals, and to a lesser extent, by organic matter and sulphide minerals.Major differences found between late Permian and Triassic coals are probably related to the source rocks, given that the main source rock of the late Permian epicontinental marine basin is the Emeishan basalt formation, characterised by a high phosphate content.