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1.
根据中国东部上地壳区域元素丰度研究和新疆北部地区1:20万化探成果,总结了23个二级大地构造单元出露地壳的元素地球化学特征.与全球大陆上地壳元素丰度值的对比显示,中国大陆出露地壳成分演化程度介于岛弧与成熟的加拿大地盾之间.华北、扬子地台由于含大量碳酸盐岩地层,其出露地壳SiO2含量偏低,明显富集CaO和MgO,可见在出露地壳和上地壳元素丰度值研究中不应忽视碳酸盐岩的贡献.相对于最新发表的2种全球大陆上地壳平均成分模型,中国大陆出露地壳系统亏损Au、Hg、Mo、Sn和W,表明现有上地壳模型过高地估计了Au、Hg、Mo、Sn、W等元素丰度值.华北地台及其南缘的秦岭-大别山造山带出露地壳具低μ(238U/204Pb)值(<8)特征,但其他地区μ值较高,暗示华北地台及其周边地区出露地壳的低μ值特点不具备全球意义.鉴于中国大陆内部各构造单元之间出露地壳成分的显著横向差异,以华北地台为主体的上地壳成分模型目前尚无充分理由作为中国和全球大陆上地壳平均值的可靠代表. 相似文献
2.
根据中国东部上地壳区域元素丰度研究和新疆北部地区1:20万化探成果,总结了23个二级大地构造单元出露地壳的元素地球化学特征。与全球大陆上地壳元素丰度值的对比显示,中国大陆出露地壳成分演化程度介于岛弧与成熟的加拿大地盾之间。华北、扬子地台由于含大量碳酸盐岩地层,其出露地壳SiO2含量偏低,明显富集CaO和MgO,可见在出露地壳和上地壳元素丰度值研究中不应忽视碳酸盐岩的贡献。相对于最新发表的2种全球大陆上地壳平均成分模型,中国大陆出露地壳系统亏损Au、Hg、Mo、Sn和W,表明现有上地壳模型过高地估计了Au、Hg、Mo、Sn、W等元素丰度值。华北地台及其南缘的秦岭-大别山造山带出露地壳具低μ(^238U/^204Pb)值(〈8)特征,但其他地区μ值较高,暗示华北地台及其周边地区出露地壳的低μ值特点不具备全球意义。鉴于中国大陆内部各构造单元之间出露地壳成分的显著横向差异,以华北地台为主体的上地壳成分模型目前尚无充分理由作为中国和全球大陆上地壳平均值的可靠代表。 相似文献
3.
中国大陆地壳和岩石圈化学成分模型可信吗? ——来自大地热流值的检验 总被引:3,自引:0,他引:3
大地热流值是大陆地壳和岩石圈U,Th,K丰度的直接约束;根据地球化学元素丰度值推算出的大地构造单元的区域地壳热流值,必定不能大于区域的平均热流值,根据700余个实测大地热流数据,对目前发表的中国大陆地壳和岩石圈的化学成分模型进行了检验,结果表明,多数模型不能满足大地热充约束,如黎彤等的关于中国大陆及其内部构造单元的地壳和岩石圈成分模型,倪守斌等提出的新疆北部地壳生热率模型,以及高山等提出的扬子地台北缘地壳成分模型,这些模型的U,Th,K丰度值不太可靠,其他强不相容元素的丰度值的可信程度亦值得怀疑,而迟清华,鄢明才提出的华北地台地壳成分模型和高山等建立的中国东部及华北地台和秦岭造山带的地壳成分模型通过了区域大地热流的检验。 相似文献
4.
运用区域大规模采样方法,对内蒙古中南部地区所采样品进行元素丰度值加权计算,这是建立区域地壳模型的基础工作之一,同时也为化探异常的检出提供较为准确的背景值。研究区涉及内蒙古地轴和内蒙古中部造山系2个构造单元。采用加权求平均值的方法,得到内蒙古中南部出露地壳10种常量元素氧化物和40种微量元素的丰度值。经地表热流值、地震平均波速和元素比值方法检验后证明所得结果合理。计算所得内蒙古中南部出露地壳平均成分为花岗闪长质,与目前一般认为的结论相同。将结果与其他地区进行比较分析后可知,内蒙古中南部出露的地壳与全球上地壳的组成基本一致。由微量元素、稀土元素的图解和内蒙古中南部出露地壳的元素丰度与中国东部出露地壳元素丰度的对比可以看出,整体上,内蒙古中南部具有较强的壳内分异作用和地壳增生作用(地幔物质加入)。 相似文献
5.
运用区域大规模采样方法,对内蒙古中南部地区所采样品进行元素丰度值加权计算,这是建立区域地壳模型的基础工作之一,同时也为化探异常的检出提供较为准确的背景值。研究区涉及内蒙古地轴和内蒙古中部造山系2个构造单元。采用加权求平均值的方法,得到内蒙古中南部出露地壳10种常量元素氧化物和40种微量元素的丰度值。经地表热流值、地震平均波速和元素比值方法检验后证明所得结果合理。计算所得内蒙古中南部出露地壳平均成分为花岗闪长质,与目前一般认为的结论相同。将结果与其他地区进行比较分析后可知,内蒙古中南部出露的地壳与全球上地壳的组成基本一致。由微量元素、稀土元素的图解和内蒙古中南部出露地壳的元素丰度与中国东部出露地壳元素丰度的对比可以看出,整体上,内蒙古中南部具有较强的壳内分异作用和地壳增生作用(地幔物质加入)。 相似文献
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7.
根据天山地区(42~44^oN,81~89^oE)1:20万,七探采集的900余个岩石样品的分析结果,基于全样本统计和迭代剔除方法,得到新疆天山地区表壳(出露地壳)的39种元素丰度值;对其中的SiO2、TiO2、Al2O3、TFe2O3、MgO、MnO、CaO、Na2O、K2O、P2O5 10种常量元素,按氧化物之和为100%进行归算。与全球大陆上地壳元素丰度值相比,天山地区表壳元素丰度富集SiO2、MnO和Ag、As、Hj、Sb元素,明显亏损CaO和。Be、Co、Cr、Ni、Mo、Sn,V、W等元素。从元素比值来看,该区表壳的Ba/La、K/La、K/Th、Nb/La、Th/La、Y/La值与全球大陆上地壳相应元素值相当;而K/Na、La/As、La/Sb值明显低于全球大陆上地壳。该区表壳化学成分相当于花岗闪长岩,同时表现出相对富钠和As、Sb元素的特征;这一地球化学特征与区内出露的表壳岩石主要是加里东期和海西期岛弧造山作用的产物有关,相对富钠的成分特征与岛弧岩浆活动中的Adakite质岩浆作用有关。 相似文献
8.
《物探与化探》2020,(3)
运用区域大规模采样方法,通过对采集于内蒙古5条地震剖面的392个样品的元素含量进行计算,得到内蒙古地区出露地壳的12种常量元素(氧化物)及40种微量元素的丰度。计算方法主要采取每个时代地层用其标准剖面中各个岩性岩石厚度权重进行加权,而后按地质图上各地层及岩体出露面积进行加权的方法。计算得到的元素丰度经地表热流值、地震平均波速及元素比值方法检验后证明在合理范围内。将常量元素与不同研究者所得的上地壳元素平均值进行比较分析后可知,内蒙古地区出露地壳与全球上地壳组成基本一致,平均成分为花岗闪长岩,只是其中Ca、Mg的含量略低。由微量元素、稀土元素及元素比值等方面的分析结果可以看出,内蒙古地区两个主要构造单元——内蒙古地轴和兴蒙造山带存在较大差异,内蒙古地轴具有强烈的壳内分异作用,而兴蒙造山带则具有较强烈的地壳增生作用。 相似文献
9.
根据能量守恒原理和中国大陆实测热流数据,给出中国大陆地壳生热率上限值为1.3μWm-3。根据热流值和地下流体氦同位素组成资料,估算出中国大陆地壳生热率为0.58~1.12μWm-3,中位数为0.85μWm-3,相应的铀、钍、钾丰度范围分别是0.83~1.76μg/g、3.16~6.69μg/g和1.0%~2.12%。中国陆壳铀、钍、钾元素整体丰度值明显高于太古宇地壳,反映中国陆壳成分演化程度较高。同时,中国大陆地壳成分具有明显的横向非均匀性特征:东部地壳相对西北部富集铀、钍、钾等强不相容元素,褶皱带相对克拉通地区富集铀、钍、钾元素。基于大陆地壳SiO2含量与地壳生热率之间的正相关关系推断,中国东部地壳较西部富长英质组分,褶皱带地壳成分较克拉通富长英质组分。此区域性变化特征与基于地震波速资料推断的结果相符。基于中国大陆地壳生热率变化范围以及地震波速低于全球平均值的特征,推断Rudnick和Fountain(1995)、Rudnick和Gao(2003)、Weaver和Tarney(1984)、Shaw等(1986)以及Wedepohl(1995)的全球陆壳成分模型均高估了铀、钍、钾等强不相容元素丰度。 相似文献
10.
根据东准噶尔地区1:20万化探均匀采集的900余个岩石样品的分析结果,基于全样本统计和迭代剔除方法,得到新疆东准噶尔地区表壳(出露地壳)的39种元素丰度值;同时对其中的SiO2、TiO2、Al2O3、TFe2O3、MgO、MnO、CaO、Na2O、K2O、P2O5 10种常量元素,按氧化物之和为100%进行了归算。东准噶尔地区表壳在化学成份上相当于花岗闪长岩。与全球大陆上地壳元素丰度值相比,明显富集Na2O、MnO和As、Sb、Ag元素,略富集SiO2、TiO2、P2O5和Y,明显亏损Co、Cr、Mo、Ni、Sn、W等元素,亏损CaO、K2O、MgO和Be、La、Nb、Pb、Sr、Th、U等元素。从元素比值来看,东准噶尔地区地区表壳的K/La、K/Th、Nb/La、Th/La、La/As、K/Na比值低于全球大陆上地壳相应元素比值;而La/Cr比值高于全球大陆上地壳。东准噶尔地区表壳在成分特征上与典型的岛弧造山带上地壳更为接近,但较后者略为成熟。加里东和海西期造山作用是影响和制约东准噶尔地区表壳的元素地球化学特征的重要地质因素。 相似文献
11.
A.E. Ringwood 《Geochimica et cosmochimica acta》1974,38(6):983-984
The case for heterogeneous accretion of the Moon is considered in the light of recent studies of lunar internal differentiation. The evidence which was formerly held to favour heterogeneous accretion is no longer compelling. 相似文献
12.
Prof. Dr. L. U. de Sitter 《International Journal of Earth Sciences》1960,50(1):219-225
Summary Variations in density in the basaltic layer and the upper mantle are postulated as being due to mineral conversions as result of high temperature and pressure variations. This theory has been developed in order to explain the elevation of mountain chains, median ocean rises and deep sea trenches as being caused by compressional and tensional stressfields.
Zusammenfassung Es wird angenommen, daß Dichte-Änderungen in der Basalt-Schale und dem oberen Teile des Erdmantels von Mineralumwandlungen infolge hoher Temperatur- und Druck-Änderungen herrühren. Diese Theorie wird ausgebaut, um die Hebung von Kettengebirgen und ozeanischen Rücken und die Bildung von Tiefseegräben auf Grund von Zug- und Druckspannungs-Feldem zu erklären.相似文献
13.
Chemical composition and fractionation of the continental crust 总被引:8,自引:0,他引:8
Prof. Dr. K. H. Wedepohl 《International Journal of Earth Sciences》1991,80(2):207-223
A new estimate of the bulk continental crust is reported consisting of 57 percent lower crust (60% felsic and 40% mafic granulites) and 43 percent upper crust. The proportions of crustal units are based on petrological observations (Bohlen &Mezger, 1989). The estimate of a bulk composition is intermediate between andesite and tonalite and is higher in Si, K, Rb, Sr, Zr, Nb, Ba, LREE, Pb, Th concentrations and lower in Mg, Ca, Sc, Mn, Fe than the crustal abundances reported byTaylor &McLennan (1985). Equal chemical composition between the upper crust and the felsic part of the lower crust is attained in balance computations if one restores a fraction of 12.5 percent S-type granite from the upper into the lower crust. An example of water-undersaturated partial melting and separation of a fraction of about 35 percent granitic magma at the conversion from amphibolite-into granulite-facies metasediments has been balanced bySchnetger (1988) in the Ivrea area (N. Italy). The worldwide observed discrepancy between a larger negative Eu anomaly in the upper crust compared with the half as large positive anomaly of the lower crust increasing from the early Precambrian to present has been explained by recycling of Ca-rich restite into the upper mantle. The composition of the Archean crust (example: Greenland) does not differ systematically from the post-Archean crust.
Zusammenfassung Die chemische Zusammensetzung der gesamten kontinentalen Kruste, die zu 57% aus der Unterkruste (60% felsische und 40% mafische Granulite) und zu 43% aus Oberkruste besteht, wurde neu ermittelt. Die Proportionen der Krusteneinheiten beruhen auf petrologischen Beobachtungen (Bohlen &Mezger, 1989). Die geschätzte Zusammensetzung der Gesamtkruste liegt zwischen Andesit und Tonalit. Sie ist höher in den Gehalten an Si, K, Rb, Sr, Zr, Nb, Ba, LREE, Pb, Th und niedriger im Mg, Ca, Sc, Mn, Fe als die vonTaylor &McLennan (1985) mitgeteilten mittleren Krustenwerte. Die chemischen Unterschiede zwischen Ober- und Unterkruste werden ausgeglichen, wenn man die Substanz von 12,5% S-Typ-Granit von der Oberkruste abzieht und zur Unterkruste hinzufügt. Als typisches Beispiel der Abtrennung granitischer Partialschmelzen im wasseruntersättigten System wird das der variskischen Metamorphose von Metasedimenten in der Ivreazone (Nord-Italien) angesehen.Schnetger (1988) konnte hier mit einer chemischen Bilanz zeigen, daß die Umwandlung von amphibolitfaziellen zu granulitfaziellen Gesteinen mit dem Verlust von etwa 35% granitischer Schmelze verbunden war. Die negative Eu-Anomalie der Oberkruste ist weltweit doppelt so groß wie die positive Anomalie der Unterkruste. Diese in der Zeit vom Archaikum bis heute vergrößerte Diskrepanz läßt sich nur mit dem Verlust von Ca-reichen Restiten aus der Kruste an den Mantel erklären. Die chemische Zusammensetzung der kontinentalen Kruste hat sich sonst seit dem Archaikum nicht systematisch geändert, wie am Beispiel Grönlands gezeigt wird.
Résumé Cette note propose une nouvelle estimation de la composition chimique d'ensemble de la croûte continentale, constituée pour 57% de croûte inférieure (60% de granulites felsiques et 40% de granulites mafiques) et pour 43% de croûte supérieure. Les proportions de ces unités crustales sont basées sur les observations pétrologiques (Bohlen etMezger 1989). La composition d'ensemble proposée est intermédiaire entre celles d'une andésite et d'une tonalite; par rapport aux abondances crustales données parTaylor etMcLennan (1985), les teneurs sont plus élevées en Si, K, Rb, Sr, Zr, Nb, Ba, LEE, Pb, Th et moins élevées en Mg, Ca, Sc, Mn, Fe. Si on tranfère de la croûte supérieure à la croûte inférieure la matière correspondant à 12,5% de granite de type S, la différence de composition entre ces deux croûtes disparaît. Un exemple typique de fusion partielle granitique en système sous-saturé en eau est fourni par le métamorphisme varisque de métasédiments dans la zone d'Ivrée (Italie du Nord). D'après ce bilan chimique établi parSchnetger (1988), le passage des roches du faciès des amphibolites à celui des granulites s'accompagne de la production d'environ 35% de magma granitique. L'anomalie négative en Eu de la croûte supérieure est partout le double de l'anomalie positive de la coûte inférieure. Cette différence, qui s'est accrue depuis l'Archéen jusqu'aujourd'hui, s'explique par le passage de restites riches en Ca dans le manteau supérieur. La composition d'ensemble de la croûte continentale ne s'est toutefois pas modifiée depuis l'Archéen, comme le montre l'exemple du Groenland.
, 57% (60% 40% ), -43%. , (Bohlen & Mezger, 1989). . Taylor & McLennan (1985) Si, K, Rb, Sr, Zr, Nb, Ba, LREE, Pb, Th Mg, Ca, Sc, Mn, Fe. , 12,5% S, , . — , , . Schnetger (1988) , 35%. , . , , , , , . , .相似文献
14.
Jörg Erzinger 《International Journal of Earth Sciences》1989,78(3):731-740
The alteration of the upper oceanic crust through sea water-basement rock interaction produces different and distinct alteration zones with increasing depth. The zonation generally shows a consistent worldwide pattern.The uppermost basement is influenced by oxidative sea water-basalt alteration at low temperatures and high water/rock ratios. With increasing crustal depth or even in a single pillow the temperatures rise, the water/rock ratios become lower, the redox and pH values normally decrease, and the oxidative zone is followed by a non-oxidative one. Below these zones the basement has suffered high-temperature alteration under reducing and acidic conditions.This results in chemical modifications of the rocks by the addition or leaching of certain elements, and has also consequences for the composition of sea water.From our own data and data presently available in the literature I summarize the mineralogical and geochemical characteristica of sea water alteration processes affecting the oceanic crust.
Zusammenfassung Die chemische Veränderung der oberen ozeanischen Kruste durch Gestein/Meerwasser-Interaktionen produziert verschiedene und unterscheidbare Alterationszonen die von der Krustentiefe abhängig sind. Diese Zonierung zeigt weltweit vergleichbare Muster.Das oberste Basement wird von einer niedrig temperierten oxidativen Meerwasseralteration beeinflußt. Mit zunehmender Krustentiefe steigen die Reaktionstemperaturen an, die Redox- und pH-Werte werden kleiner, d.h. nichtoxidative Alterationsvorgänge dominieren. Unterhalb dieser Zonen wird die ozeanische Kruste überwiegend von reduzierenden und sauren Hydrothermallösungen alteriert.Im Verlauf der Seewasser/Basalt-Reaktionen werden die Gesteine mineralogisch und chemisch verändert, indem verschiedene Elemente aus den Basalten herausgelöst und wiederum andere aufgenommen werden. Diese Vorgänge haben auch für die Zusammensetzung des Meerwassers drastische Konsequenzen.Mit Hilfe publizierter aber vor allem mit eigenen Daten werden die mineralogischen und geochemischen Charakteristika der unterschiedlichen Alterationsprozesse zusammengefaßt dargestellt.
Résumé L'altération de la partie supérieure de la croûte océanique sous l'action de l'eau de mer engendre plusieurs zones distinctes qui se succèdent de haut en bas. Ce zonage présente d'ordinaire une extension mondiale.La partie supérieure de la croûte est affectée d'une altération oxydante de basse température du basalte. Vers le bas, parfois même au sein d'un même pillow, la température s'élève, la quantité d'eau décroît, le potentiel redox et le pH diminuent, de sorte que la zone d'oxydation est suivie d'une zone non oxydante. En-dessous de ces deux zones, les roches ont subi une altération de haute température dans des conditions acides et réductrices.Il en résulte des changements de la composition chimique des roches par apport ou par lessivage de certains élements, ainsi qu'une modification de la composition de l'eau de mer.A partir des données de la littérature et surtout de mes propres observations, je présente une synthèse des caractères minéralogiques et géochimiques des divers processus de l'altération sous-marine.
, . . . , pH , .. , . . , , , . . , . . , .相似文献
15.
16.
Large scale segregation of sialic crust from mantle material may have taken place by magmatic differentiation, partial melting or by exogenic processes. Weathering is a little considered, but verifiable process by which free silica can be generated in quantity from mafic material. In proto-Archean time acid ocean water must have been highly reactive. Even submarine weathering by such acid water could lead to large scale generation of free silica. Evidence from soil formation supports this view. Recrystallization of weathering products would take place by anatexis in the course of relatively intense recycling processes in pre-Archean and early Archean times. Much Fe and Mg in shales and carbonates would segregate downward as mafic xenoliths. The sialic fraction would be returned to shallow crustal levels by diapiric ascent and upward melting. This model is valid only if the sialic crust has grown little since Archean time. We show that “primitive” isotope ratios in later sialic rocks which may suggest gradual accretion of sialic crust throughout geologic time can also be explained by recycling mechanisms. We conclude that exogenic processes in pre-Archean times could have generated most of the sialic crust. 相似文献
17.
David W Schwartzman 《Geochimica et cosmochimica acta》1973,37(11):2479-2495
The degassing of radiogenic Ar40 is defined as coherent if only the Ar40 associated with parent K is degassed as K is transferred from the mantle to crust. Coherency predicts, for a 4.55 b.y. Earth, a sialic crust with 2.50 per cent K, using only the Ar content of the atmosphere and present crust (from a Hurley and Rand, 1969, age distribution). This is a maximum limit to K content of the sialic crust if the age of the Earth is no younger than 4.55 b.y. A K content of the sialic crust of 1.9 per cent (Holland and Lambert, 1972) implies an efficiency (E) less than 100 per cent for K transfer from oceanic basalt to sialic crust in subduction zones and/or some non-coherent (preferential) degassing of Ar from the mantle.K, Ar coherence for mantle differentiation to crust is supported however, by the agreement of the predicted oceanic He flux and radiogenic He-Ar ratios of volcanic gases with the observed limits if the best estimate of K, U, Th influx rates at oceanic ridges is used.Assuming K, Ar coherence, various sea-floor spreading rates as functions of time, and limiting K contents of the sialic crust, computed models give E and the portion of the sialic crust derived from melting oceanic basalt in subduction zones. Except for models with very high spreading rates in the Precambrian, they also predict that a significant part of the sialic crust was derived from vertical differentiation of the mantle, presumably early in Earth history. The results are in accord with Armstrong's model of an early sialic crust that is recycled to give a Hurley-type age pattern with the proviso that the ‘vertical’ sial Kυis formed early in Earth history for models with a high Kυcomponent.The coherent K, Ar models with preferred estimates of input parameters are also consistent with a limited mixing model (only old and new sial are equilibrated) for Sr isotopic evolution and the probable average ratio now of the sialic crust. 相似文献
18.
David E Fisher 《Geochimica et cosmochimica acta》1979,43(5):709-716
Uranium contents of 67 oceanic basalts have been measured by fission track analysis. Average value for ridge and intraplate basalts is ~ 78 ppb, for the Easter Hot Line it is ~1600 ppb. Estimates of mantle concentrations derived from the ridge and intraplate samples are insufficient to account for the observed surface heat flow. The whole-Earth concentration of U is > 8 ppb. and < 33 ppb if all heat generated within the Earth reaches the surface. 相似文献
19.
Rates of generation and growth of the continental crust 总被引:4,自引:1,他引:3
Models for when and how the continental crust was formed are constrained by estimates in the rates o crustal growth. The record of events preserved in the continental crust is heterogeneous in time with distinctive peaks and troughs of ages for igneous crystallisation, metamorphism, continental margin and mineralisation. For the most part these are global signatures, and the peaks of ages tend to b associated with periods of increased reworking of pre-existing crust, reflected in the Hf isotope ratios o zircons and their elevated oxygen isotope ratios. Increased crustal reworking is attributed to periods o crustal thickening associated with compressional tectonics and the development of supercontinents Magma types similar to those from recent within-plate and subduction related settings appear to hav been generated in different areas at broadly similar times before ~3.0 Ga. It can be difficult to put th results of such detailed case studies into a more global context, but one approach is to consider when plate tectonics became the dominant mechanism involved in the generation of juvenile continental crust The development of crustal growth models for the continental crust are discussed, and a number o models based on different data sets indicate that 65%-70% of the present volume of the continental crus was generated by 3 Ga. Such estimates may represent minimum values, but since ~3 Ga there has been reduction in the rates of growth of the continental crust. This reduction is linked to an increase in th rates at which continental crust is recycled back into the mantle, and not to a reduction in the rates a which continental crust was generated. Plate tectonics results in both the generation of new crust and it destruction along destructive plate margins. Thus, the reduction in the rate of continental crustal growth at ~3 Ga is taken to reflect the period in which plate tectonics became the dominant mechanism b which new continental crust was generated. 相似文献
20.
Element Abundances of China‘s Continental Crust and Its Sedimentary Layer and Upper Continental Crust 总被引:4,自引:0,他引:4
Li Tong 《中国地球化学学报》1995,14(1):26-32
China’s continental crust (CCC) has an average thickness of 47km, with the upper continental crust (CUCC) being 31 km and
the sedimentary layer(CSL) 5 km in thickness. The CCC, CUCC and CSL measure 12.437 × 10−17, 8.005 × 10−17 and 1.146 × 1017 metric tons in mass, respectively. The mass ratio of the upper continental crust to the lower one is 1.8:1. The element abundances
were calculated for the CCC, CUCC and CSL respectively in terms of the chemical compositions of 2246 samples of various types
and some complementary trace element data. The total abundance of 13 major elements accounts for 99.6% of the CCC mass while
the other minor elements only account for 0.4%. REE characteristics, the abundance ratios of element pairs and the amounts
of ore-forming elements are also discussed in the present paper. 相似文献