辽东古元古界镁质岩石成因及其对硼矿成矿控制作用
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摘要
辽东硼矿是我国特有的变质热液交代型硼矿,它发育于我国古元古代的“辽吉古裂谷”中,含硼岩系为经过角闪岩相区域变质作用的辽河群里尔峪组,容矿岩石为镁橄榄岩、橄榄玄武岩和富镁大理岩等镁质岩石。
镁橄榄岩、橄榄玄武岩和富镁大理岩这套特殊组合的镁质岩石为辽东古裂谷发育中期幔源富镁岩浆熔离、水下喷发的产物。三者在空间关系上密切共生,明显出现互相包容及共生现象,呈透镜状、似层状局限分布;都由富镁质矿物组成,具有火山岩的某些结构构造;主量元素具高镁特征,镁橄榄岩显示出地幔橄榄岩残余相的特点,橄榄玄武岩为偏碱性的板内玄武岩,富镁大理岩亦显示出火成岩的某些特点;微量元素具相似性,都显示出火成岩的某些特征;稀土元素具相似的La/Yb比值,镁橄榄岩、橄榄玄武岩显示出相近的玄武岩形成环境(从拉斑玄武岩到碱性玄武岩),富镁大理岩稀土特征处于球粒陨石和沉积岩之间;碳氧同位素亦表明富镁大理岩为岩浆成因。
镁橄榄岩、橄榄玄武岩和富镁大理岩这套镁质岩石不仅是辽东硼矿的容矿岩石,而且其岩石特性对硼矿的形成有决定性的岩控作用:(1)硼矿体与镁质容矿岩石地层层位上一致,硼矿体的形态受镁质岩石地质产状的制约。(2)硼矿矿石在矿物种类、矿物形态、结构、构造等方面都与镁质岩石有明显的交代继承关系。(3)矿石与容矿镁质岩石及其蚀变岩的主量元素特征具继承性,微量元素特征具相似性,稀土元素演化方面具一致性,尤其是其配分形式显示出硼矿矿石的形成主要受镁质容矿岩石和区域变质混合岩化作用的双重控制。
辽东硼矿的成矿模式可概括为原始矿源层(火山喷发—沉积)中硼元素初始富集和区域变质混合岩化作用过程中的含硼热液交代镁质岩石两个过程,尤其是后一过程促成辽东硼矿的最终形成,在这一过程中区域变质混合岩化过程中产生大量的热流体,热流体促使含硼岩系中的硼质活化从而产生大量含硼热液,含硼热液交代镁质岩石则形成辽东特有的镁硼酸盐型硼矿或交代硅铝岩石形成富电气石的硼硅酸盐岩石。含硼热液对镁质岩石的作用形式有充填、交代两种。
East Liaoning borate deposits are special metamorphic-hydrothermal~metasomatic borate deposits and are distributed in "Liaoji paleorift" of Paleoproterozoic of China. Their rocks boron-bearing are Lieryu formation of Liaohe group which went regional metamorphism with amphibolite facies, and their host rocks are magnesian rocks such as magnesium peridotites, olivine basalts and magnesian marbles.
The special suite of magnesian rocks (magnesium peridotites, olivine basalts and magnesian marbles) is the product of liquating and erupting of magnesian magma in the intermediate stage of development of "Liaoji paleorift" .The three kinds of magnesian rocks are distributed limitly in lentoid , layer-like , and contained each other. They are maded of magnesian minerals and are of textures and structures of igneous rocks. Their characteristics of major elements are magnesian-rich , magnesium peridotites display characteristics of last phase of mantle peridotites melting partly, olivine basalts display characteristics of weak alkali basalts , and magnesian marbles display some characteristics of magmatic carbonatites . Their trace elements are similar to igneous rocks' . Ttheir REE elements are of similar La/Yb value, the REE elements of magnesium peridotites and olivine basalts display that their formed setting are similar (from tholeiite to alkali-basalt), and the REE elements of magnesian marbles between the REE elements of chondrite and sedimentary rocks. The composition of C-O isotopes of the magnesian marbles can indicate that the rocks are of characteristics of magmatic origin.
The suite of magnesian rocks is not only the host rocks of east Liaoning borate deposits, but also has decisive role on forming of borate deposits:(1)the borate ore bodies and magnesian rocks are same in stratigraphic position, and their shape controlled by attitude of magnesian rocks;(2) ores have relationship of replacement and inheritance with magnesian rocks in composition and shape of minerals, texture, structure ,etc.;(3) major elements are of succession , trace elements are similar and characteristics of evolution of REE elements are accordant between ores and their host rocks, specially, the patterns of REE elements indicate that the formation of ores are depended on magnesian rocks and migmatization.
The metallogenic model of east Liaoning borate deposits can be divided into two courses, the one is initial enrichment of boron in original ore-source layer (volcanic eruption— sedimentation) , the other is replacment of hydrotherm boron-bearing on magnesian rocks in
regional metamorphism and migmatization, specially, the later one, it favored the final formation of east Liaoning borate deposits, in this course, a large of hydrotherm is formed in regional metamorphism and migmatization , the hydrotherm makes boron activate, and the hydrotherm boron-bearing is formed. As result, the magnesian borate type ores, which are distributed only in east Liaoning borate deposits, are formed with replacing of hydrotherm boron-bearing on magnesian rocks and boron silicate rocks tourmaline-rich are formed with replacing of hydrotherm boron-bearing on aluminous silicate rocks. The formats that the hydroherm boron-bearing act on magnesian rocks are filling and metasomatism.
镁橄榄岩、橄榄玄武岩和富镁大理岩这套特殊组合的镁质岩石为辽东古裂谷发育中期幔源富镁岩浆熔离、水下喷发的产物。三者在空间关系上密切共生,明显出现互相包容及共生现象,呈透镜状、似层状局限分布;都由富镁质矿物组成,具有火山岩的某些结构构造;主量元素具高镁特征,镁橄榄岩显示出地幔橄榄岩残余相的特点,橄榄玄武岩为偏碱性的板内玄武岩,富镁大理岩亦显示出火成岩的某些特点;微量元素具相似性,都显示出火成岩的某些特征;稀土元素具相似的La/Yb比值,镁橄榄岩、橄榄玄武岩显示出相近的玄武岩形成环境(从拉斑玄武岩到碱性玄武岩),富镁大理岩稀土特征处于球粒陨石和沉积岩之间;碳氧同位素亦表明富镁大理岩为岩浆成因。
镁橄榄岩、橄榄玄武岩和富镁大理岩这套镁质岩石不仅是辽东硼矿的容矿岩石,而且其岩石特性对硼矿的形成有决定性的岩控作用:(1)硼矿体与镁质容矿岩石地层层位上一致,硼矿体的形态受镁质岩石地质产状的制约。(2)硼矿矿石在矿物种类、矿物形态、结构、构造等方面都与镁质岩石有明显的交代继承关系。(3)矿石与容矿镁质岩石及其蚀变岩的主量元素特征具继承性,微量元素特征具相似性,稀土元素演化方面具一致性,尤其是其配分形式显示出硼矿矿石的形成主要受镁质容矿岩石和区域变质混合岩化作用的双重控制。
辽东硼矿的成矿模式可概括为原始矿源层(火山喷发—沉积)中硼元素初始富集和区域变质混合岩化作用过程中的含硼热液交代镁质岩石两个过程,尤其是后一过程促成辽东硼矿的最终形成,在这一过程中区域变质混合岩化过程中产生大量的热流体,热流体促使含硼岩系中的硼质活化从而产生大量含硼热液,含硼热液交代镁质岩石则形成辽东特有的镁硼酸盐型硼矿或交代硅铝岩石形成富电气石的硼硅酸盐岩石。含硼热液对镁质岩石的作用形式有充填、交代两种。
East Liaoning borate deposits are special metamorphic-hydrothermal~metasomatic borate deposits and are distributed in "Liaoji paleorift" of Paleoproterozoic of China. Their rocks boron-bearing are Lieryu formation of Liaohe group which went regional metamorphism with amphibolite facies, and their host rocks are magnesian rocks such as magnesium peridotites, olivine basalts and magnesian marbles.
The special suite of magnesian rocks (magnesium peridotites, olivine basalts and magnesian marbles) is the product of liquating and erupting of magnesian magma in the intermediate stage of development of "Liaoji paleorift" .The three kinds of magnesian rocks are distributed limitly in lentoid , layer-like , and contained each other. They are maded of magnesian minerals and are of textures and structures of igneous rocks. Their characteristics of major elements are magnesian-rich , magnesium peridotites display characteristics of last phase of mantle peridotites melting partly, olivine basalts display characteristics of weak alkali basalts , and magnesian marbles display some characteristics of magmatic carbonatites . Their trace elements are similar to igneous rocks' . Ttheir REE elements are of similar La/Yb value, the REE elements of magnesium peridotites and olivine basalts display that their formed setting are similar (from tholeiite to alkali-basalt), and the REE elements of magnesian marbles between the REE elements of chondrite and sedimentary rocks. The composition of C-O isotopes of the magnesian marbles can indicate that the rocks are of characteristics of magmatic origin.
The suite of magnesian rocks is not only the host rocks of east Liaoning borate deposits, but also has decisive role on forming of borate deposits:(1)the borate ore bodies and magnesian rocks are same in stratigraphic position, and their shape controlled by attitude of magnesian rocks;(2) ores have relationship of replacement and inheritance with magnesian rocks in composition and shape of minerals, texture, structure ,etc.;(3) major elements are of succession , trace elements are similar and characteristics of evolution of REE elements are accordant between ores and their host rocks, specially, the patterns of REE elements indicate that the formation of ores are depended on magnesian rocks and migmatization.
The metallogenic model of east Liaoning borate deposits can be divided into two courses, the one is initial enrichment of boron in original ore-source layer (volcanic eruption— sedimentation) , the other is replacment of hydrotherm boron-bearing on magnesian rocks in
regional metamorphism and migmatization, specially, the later one, it favored the final formation of east Liaoning borate deposits, in this course, a large of hydrotherm is formed in regional metamorphism and migmatization , the hydrotherm makes boron activate, and the hydrotherm boron-bearing is formed. As result, the magnesian borate type ores, which are distributed only in east Liaoning borate deposits, are formed with replacing of hydrotherm boron-bearing on magnesian rocks and boron silicate rocks tourmaline-rich are formed with replacing of hydrotherm boron-bearing on aluminous silicate rocks. The formats that the hydroherm boron-bearing act on magnesian rocks are filling and metasomatism.
引文
[1] 宋世文,王运华.硼矿粉直接施用的研究.土壤肥料.1997(3):36-37.
[2] 罗锡裕.超硬材料的发展.产业论坛,2000,9:35-38.
[3] 肖荣阁,大井隆夫,野村雅大,等.湘南高温热液矿床中硼同位素组成及分馏作用研究.华南地质与矿产,2001(2),1-7.
[4] 肖荣阁,大井隆夫,候万荣,等.天津蓟县锰方硼石矿物硼同位素研究,现代地质,2002,16(3):270-275.
[5] 孙福.我国西部硼市场前景广阔.建材工业信息,1996,6:19.
[6] 李文光.我国硼矿资源概况及利用.化工矿物与加工,2002,9:37.
[7] 冯本智,朱国林,董清水,等.辽东海城—大石桥超大型菱镁矿矿床的地质特点及成因.长春地质学院学报,1995,25(2):121—124.
[8] Chaussidon M., and Jambon A. Boron content and isotopic composition of oceanic basalts: geochemical and cosmochemic implicationa, Earth Planet. Sci. Lett. 1994, 121: 277-291.
[9] Nomura M.,Okamoto M.,and Kakihana H. Determination of boron content and boron isotopic ratio of seawater samples, Nihon Kaisuigakkai shi 1419, 1984.
[10] A.A.奥佐尔.沉积和火山沉积硼矿.北京:地质出版社,1987.
[11] Donald E. Garrett, Borates, Handbook of Deposits, Processing, Properties, and Use, Academic Press, 1998, California, USA .
[12] Erd, R. C. The minerals of boron. In Mellor's Inorganic and Theoretical Chemistry, Longman, New York., Pt.A. 1980, 5:7-71.
[13] Kistler, R. B., and Helvaci, C. Boron and Borates. In Industrial Minerals and Rocks (S. J. Lefond, ed.), Soc. Min. Eng., AIME., 1994, 171-186.
[14] Helvaci, C., Stamatakis, M.G., Zagouraglou, C., and Kanaris, J. Borate minerals and related authigenic silicates in northeastern Mediterranean Late Miocene continental basins. Explor. Mining Geol. 1993, 2(2):171-178.
[15] Sanford, W.E., and Wood, W.W. Brine evolution and mineral deposition in hydrologically open evaporite basins Am.J. Sci., 1991, 291(7):687-710.
[16] 冯本智,卢静文,邹日,等.中国辽吉地区早元古代大型-超大型硼矿床的形成条件.长春科技大学学报,1998,28(1):1-15.
[17] 姜春潮.辽吉东部前寒武纪地质.沈阳:辽宁科学技术出版社,1987.
[18] 刘敬党,肖荣阁,王文武,等.辽宁宽甸砖庙硼矿区成矿地质特征及找矿.地质与资源,2005,14(2):126-131.
[19] 刘敬党,肖荣阁,王翠芝,等.辽宁大石桥花岗质岩石成因分析及其在硼矿勘查中的意义.吉林大学学报[地球科学版],2005,6:714-719.
[20] 刘敬党.辽东地区下元古界镁硼酸盐矿床控矿模型及其勘查与评价研究:[博士学位论文].北京:中国地质大学(北京),2006.
[21] 李永达.辽东早元古宙构造环境及岩石圈构造.辽宁地质,1992(3).
[22] 王秀璋.东北内生硼矿床的矿物组成和矿床成因研究.北京:科学出版社,1974.
[23] 辽宁省地质局第五勘探队.辽宁省营口县后仙峪硼矿床最终勘探储量报告,1966.
[24] 辽宁省地质局丹东地质大队二队.辽宁省风城县翁泉沟铁硼矿矿床总结勘探报告,1976.
[25] 化学工业部地质勘探公司辽宁地质勘探大队.辽宁省宽甸县砖庙硼矿区栾家沟矿段勘探地质报告,1988.
[26] 张秋生.辽东半岛早期地壳与矿床.北京:地质出版社,1988年.
[27] 化学工业部化学矿产地质研究院.辽东—吉南地区硼矿床控构造研究,1991.
[28] 化学工业部化学矿产地质研究院.辽吉内生硼矿矿物学及找矿标志研究,1993.
[29] 黄作良,王濮,冯本智.辽吉硼矿床矿物学.北京:地质出版社,1999.
[30] 路远发,陈毓川,李华芹,等.辽东古元古代裂谷中硼矿床成矿年代学研究.《地质学报》英文版,2005,79(2):287.
[31] 董中保.变质作用矿床概述.地学前缘,1999,6(2):231-242.
[32] 彭齐鸣,许虹.辽东-吉南地区早元古南变质蒸发岩系及硼矿床.长春:东北师范大学出版社,1994.
[33] Peng, Q.M., Feng, B.Z., Liu, J.D and Zhou, R. Geology of the early Proterozoic boron deposits in eastern Liaoning, Northeastern China. Resources Geology, Special Issue No. 1993,15: 343-350.
[34] Peng Q M, Palmer M R. The Paleoproterozoic boron deposits in eastern Liaoning, China: a metamorphosed evaporite. Precambrian Research, 1995, 72: 185-197.
[35] Qi-ming PENG. The Paleoterozoic Mg-Fe borate deposits Of Liaoning and Jilin Provinces, Northeast China. Economic Geology, 2002, 97:93-108.
[36] Jiang S Y,Palmer M R, Peng Q M,et al. Chemical and stable isotope (B, Si, and O)compositions of Proterozoic metamorphosed evaporite and associated tourmalines from the Houxianyu borate deposit, eastern Liaoning, China. Chem. GeoL., 1997, 135:189-211.
[37] Jiang S Y,Ni P, Ling H F ,et al. Boron isotope geochemistry of borate and magnesite deposits in eastern Liaoning and Jilin provinces of China. in:piestrzynski, et al. eds. Mineral Deposits at the Beginning of the 21st Century. Swets & Zeitlinger publishers Liss. 2001, 987-991.
[38] 冯本智,邹日,谢宏远.辽吉早元古宙裂谷带内含硼热水沉积建造与硼矿床.见:中国地质学会矿床地质专业委员会编.第五届全国矿床地质论文集.北京:地质出版社,1993.512-515.
[39] 冯本智,邹日.辽宁营口后仙峪硼矿床特征及成因:地学前缘,1994,l(4):235-237.
[40] 邹日.营口虎皮峪地区早元古代含硼岩系中热水沉积建造特征及硼矿成因:[博士学位论文].吉林:长春地质学院,1993.
[41] 邹日,冯本智.营口后仙峪硼矿容矿火山—热水沉积岩系特征.地球化学,1995,12,第24卷(增):46-54.
[42] 张景山.辽东硼镁石型硼矿床地质特征及成矿作用.辽宁地质,1994,4:289-324.
[43] 曲洪祥,张国仁,李显东,等.辽东地区硼矿床成矿模式探讨及找矿标志.见:中国地质调查局,辽吉地区地质与成矿研讨会论文集,2001,119-126.
[44] 曲洪祥,郭伟静,张永,等.辽东地区硼矿床成因探讨与硼矿远景区预测.地质与资源,2005,14(2):131-138.
[45] Liu J k, Liu Y J, Chen H, et al. The inner zone of the liaoji paleorift:its early structural styles and structural evolution. Journal of Asian Earth Sciences, 1997,15(1):19-31.
[46] 李江海,侯贵廷,黄雄南,等.华北克拉通对前寒武纪超大陆旋回的基本制约.岩石学报,2001,17(2):177-186.
[47] 王成文,刘永江,李东涛.辽河岩群南北区域对比的新证据.长春地质学院学报,1997,27(1):17-24.
[48] 白瑾.华北陆台北缘前寒武纪地质及铅锌成矿作用.北京:地质出版社,1993,1-123.
[49] 贺高品,叶慧文.辽东-吉南地区早元古代两种类型变质作用及其构造意义.岩石学报,1998,14(2):52-162.
[50] 敖丽娟,王殿忠,张海峰,等.辽宁东部白硼矿矿床特征及找矿方向.见:中国地质调查局,辽吉地区地质与成矿研讨会论文集.北京:中国地质调查局,2001,127-136.
[51] 王殿忠,敖丽娟,王奇.营口东部区含硼蚀变岩带特征及找矿方向.辽宁地质,1998,4:251-260.
[52] 王殿忠,敖丽娟,张海峰,等.辽宁营口东部白硼矿床特征及找矿方向.辽宁地质,2000,17(4),249-258.
[53] 蔡克勤,陈从喜.辽东古元古代镁质非金属矿床成矿系统研究.地球科学—中国地质大学学报,2000,25(4):346-351.
[54] 翟裕生,邓军,彭润民,等.古陆边缘成矿系统.北京:地质出版社,2002.
[55] 辽宁省地质矿产局第七地质大队.辽宁省宽甸县杨木杆硼矿典型矿床研究报告,1986.
[56] 邓晋福,罗照华,苏尚国,等.岩石成因、构造环境与成矿作用.北京:地质出版社,2004.
[57] 化学工业部地质勘探公司辽宁地质勘探大队.辽宁省宽甸满族自治县夹皮沟乡砖庙硼矿区二人沟矿段详查地质报告,1992.
[58] 化学工业部地质勘探公司辽宁地质勘探大队.辽宁省宽甸满族自治县夹皮沟乡砖庙硼矿区花园沟矿段详查地质报告,1993.
[59] 王安平,姚杰,曹林.辽东硼矿中遂安石的微结构研究及其地质意义.世界地质,1997,16(4),27-30.
[60] 王翠芝,肖荣阁,刘敬党,等.辽宁营口后仙峪硼矿区超镁橄榄岩的岩石学特征.2006年全国博士生学术论坛论文集-地球科学领域.北京:中国地质大学(北京).2006:213-221.
[61] 王翠芝,肖荣阁,刘敬党,等.辽宁营口后仙峪硼矿区超镁橄榄岩的地球化学特征及其对源区的约束.中国地质,2006,33(6):1247-1255.
[62] 倪心垣,巴登珠,杨茂同.西藏上地幔橄榄岩及铬铁矿矿石结构构造图册.武汉:中国地质大学出版社,1992.
[63] 北京大学地质系岩矿教研室.岩石和岩体野外工作方法.北京:地质出版社,1979.
[64] 喻学惠.甘肃西秦岭区新生代碱性火山岩中的钛金云母.岩石矿物杂志,1994,13(4):319-327.
[65] 黄作良,王濮.辽吉内生硼矿反吸收金云母的发现及其地质意义.化工地质,1991,16(1):11-16.
[66] Viljoen R P,Viljoen M J.科马提岩—历史回顾.颜乘纲,王炳熙,白文吉等译.北京:地质出版社,1986.
[67] Arnolt N T,Nisbet E G.科马提岩.颜乘纲,王炳熙,白文吉,等译.北京:地质出版社,1986.
[68] 谭劲,赵珊茸,莫宣学.非均匀温度场中熔体结品作用与科马提岩结构成因.地质科技情报,1994,13(4):35-40.
[69] 李仰春,赵海滨,杨晓平,等.大兴安岭吉峰地区中元古代科马提岩及成因类型.地质与资源,2002,11(2):76-82.
[70] 杨晓明.后仙峪硼矿区金云母蚀变岩与硼矿化之关系初探.化工矿产地质,1998,20(1):38-40.
[71] 王翠芝,肖荣阁,刘敬党,等.辽东吉南硼矿矿石特征及其与容矿岩石的关系.矿产地质,2006年增刊:277-280.
[72] 邱家骧.岩浆岩岩石学.北京:地质出版社,1983.
[73] Le Maitre (ed). Igneous Rocks: A Classification and Glossary of Terms (2nd edition). Cambridge University Press, 2002.
[74] 王中刚,于学元,赵振华,等.稀土元素地球化学.北京:科学出版社,1989.
[75] 李昌年.火成岩微量元素岩石学.武汉:中国地质大学出版社,1992.
[76] 陈树良,郇彦清,邴志波.辽东地区古元古代侵入岩特征及构造岩浆大陆动力学演化.辽宁地质,2001,18(1):43-51.
[77] Allegre, C. J. and Hart, S. R. Trace elements in Ignous petrology. Developments in Petrology, 1973, 5. New York.
[78] N.T.Amdt and E.G.Nisbet.颜秉纲,王炳熙,白文吉,等译.KOMATIITES.北京:地质出版社,1985.
[79] 王希斌,鲍佩声,戎合.中国蛇绿岩中变质橄榄岩的稀士元素地球化学.岩石学报,1996,11(增刊):24-41.
[80] 邱瑞照,邓晋福,周肃,等.青藏高原西部蛇绿岩类型:岩石学与地球化学证据.地学前缘,2005,12(5):277-291.
[81] 董显扬,李行,叶良和,等.中国超镁铁质岩.北京:地质出版社,1995.
[82] Hugh Rollinson. Petrology and geochemistry of metamorphosed komatiites and basalts from the Sula Mountains greenstone belt, Sierra Leone. Contrib Mineral Petrol, 1999, 134: 86—101.
[83] Hess P C. Phase equilibria constraints on the origin of ocean floorbasalts .Morgen J P Blackman D K Sinton J M. MantleFlow and Melt Generation at Mid-Ocean Ridges OxfordPergamon 1992,67-102.
[84] Hugh R. Rollonson. Using Geochemical Data-Evalution, Presention, interpretation. Pearson Education limited, 1993.
[85] 潘兆橹.结晶学及矿物学(下册).北京:地质出版社,1993.
[86] 李建平,Jacques Kornprobst,Daniel Vielzeuf.地慢橄榄岩部分熔融及相转变(尖晶石相~斜长石相)过程中的固相化学成分演化—Ⅰ实验研究,地球化学,1996,25(1):39-52.
[87] 牛贺才,许继锋,于学元,等.新疆阿尔泰富镁火山岩系的发现及其地质意义.科学通报,1999,44(9):1002-1004.
[88] 张旗,宝林,刘若新,等.一个消减带之上的大陆岩石圈地慢残片—安徽饶拨寨超镁铁岩的地球化学特征.中国科学 (D)1995,25(8):867-873.
[89] 董云鹏,王润三,周鼎武.南天山北缘榆树沟变质基性-超基性岩的地球化学及其成因机制.地球化学,2001,30(6):559-568.
[90] 赵伦山,张本仁.地球化学.北京:地质出版社,1988.
[91] 刘月星,唐红松,吴厚泽.中国铜镍硫化物矿床类型及控矿条件.Mineral Resources And Geology,1998,64(12):86-90.
[92] 张招崇,毛景文,杨建民,等.北祁连熬油沟蛇绿岩岩石成因的地球化学证据.地质学报,1998,72(1):42-51.
[93] 曹德成.丹东地区古元古市成矿系列及找矿方向.见:中国地质调查局,辽吉地区地质与成矿研讨会论文集.北京:中国地质调查局,2001.58-65.
[94] 张泽军.北秦岭松树沟超镁铁质岩中两类不同成因的纯橄榄岩.岩石学报,1995,11(增):178-189.
[95] C. R. Friend, V.C. Bennett, A. P. Numan. Abyssal peridotites>3800Ma from southern west Greenland:field relationships, petrography, geoxhronology, whole-rock and mineral chemistry of dunite and harxburgite inclusions in the ltsaq gneiss complex. Contrib Mineral petrol, 2002, 143:71-92.
[96] 邓宏文,钱凯.沉积地球化学与环境分析.兰州:甘肃科学技术出版社,1993.
[97] Xuehui Xia, Fei Yan, YuHai Zhao, et. al. Geological features and mineralization of the uranium-bearing vonsenite deposit in the Liaodong rift. Mineral Deposit Research:meeting the global challenge. The 8~# Beinnial SGA Meeting, 2005.
[98] Feihongcai et. al. Geochemical characteristics and genesis of Na-rich rocks in the bayan obo REE-Nb-Fe deposit, inner Mongolia, china, the 8th Biennial SGA meeting, August 18-21,2005.
[99] 武钢第二炼钢厂.复吹转炉溅护炉实用技术.北京:.冶金工业出版,2004.
[100] 王生志,徐大地,张琦.后仙峪硼矿区硼矿地质特征及其成因探讨.地质与资源,2003,12(4),221-227.
[101] 全国矿产储量委员会.硼矿床勘探类型实例附图(硼矿地质勘探规范附件,内部资料).1987.
[102] 王翠芝,肖荣阁,刘敬党,等.辽宁营口后仙峪硼矿区超镁橄榄岩的控矿作用.矿产地质,2006,25(6):683-692.
[103] Ozol A. A. Basic characteristics of boron geochemistry and formation conditions for volcanic-sedimentary type boron deposits, USSR, Litol. Polezn. Iskop., 1976, 3: 60-74.
[104] Smith, G.I. Borate deposits in the United States:Dissimilar in form, similar in geologic setting, In borates, Economic Geology and Production (J.M. Barker and S.J. Lefond, eds.), Soc. Min. Eng., AIMMPE, New York, 1985, 37-51.
[105] Crowley, J.K. Mg- and K-bearing borates and associated □aporates at Eagle Borax Spring, Death Valley, California:A spectroscopic exploration: Economic Geology, 1996, 91: 622 - 635.
[106] Barker, C. E. Geology of the Terry borate deposit..California Geology , 1980, 33(8): 181-189.
[107] Barker, C. E., andBarker, J.M. Borate deposits, DeathValley, California. InBorates: Economic Geology and Production(J. M. barker and S. J. Lefond, eds.), Soc. Min. Eng., AIMMPE, New York, 1985, 103-135.
[108] Barker, J.M., and Wilson, J.L. Borate deposits in the Death Valley region, in Guidebook:Las Vegas to Death Valley and Return: Nevada Bureau of Mines and Geology, Report 26, 1975, 23-32.
[109] Joe W.Siefke.美国克拉莫硼矿床及波热露天硼矿.内蒙古地质,1999,第4期,37—41(张德平译自, 1995, 29th Forumon the Geology of Industrial Minerals: Proceedings; California Department of Conservation, Divisionof Minesand Geology Special Publication 110, p. 181-188. )
[110] Sieke, J. W. The Boron open pit mine at the Kramer borate deposit: The diversity of mineral and energy resources of southern California. Soc. Econ. Geol. Guidebook Series 12, 1991, 4-15.
[111] Helvaci, C., and Firman, R.J. Geological setting and mineralogy of Emet borate deposits, Turkey: Institution of Mining and Metallurgy, Transactions, sect. B, 1976, 85:142 - 152.
[112] Melvaci, C. Stratigraphy, mineralogy and genesis of the Bigadic, borate deposits, western Turkey: Economic Geology, 1995, 90: 1237-1260.
[113] Helvaci, C., and Yagmurlu, F. Geological setting and economic potential of the lignite and evaporite-bearing Neogene basins of western Anatolia, Turkey: Israel Journal of Earth Sciences, 1995, 44:91-105.
[114] Inan, K., Dunham, A.C., and Esson, J. Mineralogy, chemistry and origin of Kirkaborate deposits, Eskisehir Province, Turkey: Institution of Mining and Metallurgy, Transactions, Sect.B,1973,82:114-123.
[115] 肖荣阁,原振雷,刘敬党,等.区域成矿流体的形成与演化.地学前缘(中国地质大学,北京),2004,11(2):461-469.
[116] 翟裕生,彭润民,向运川,等.区域成矿研究法.北京:中国大地出版社,2004,60-66.
[117] 梁婷,高景刚,朱文戈.成矿流体类型及研究方法综述.西安文理学院学报(自然科学版),2005,8(4):323-328.
[118] S pearfs. Metamorphic Phase Equilibria and Pressure-Temperature-Time Paths[M]. Washington D C: Mineralogical Society of America, 1993, 19: 673-708.
[119] 游振东,钟增球,周汉文.区域变质作用中的流体.地学前缘(中国地质大学,北京),2001,8(3):157-164.
[120] 徐德义,於崇文,鲍征宁.热液成矿系统中—维反应扩散过程的混沌边缘.地学前缘(中国地质大学,北京),2004,11(1):99-103.
[121] 徐德义,於崇文,鲍征宇.热液成矿分带的径向对称性.地学前缘(中国地质大学,北京),2005,12(2):303-308.
[122] 刘新秒,李长民.混合岩形成模式的研究进展.前寒武纪研究进展,2001,24(4):237-246.
[123] 李兆麟.关于变质深熔作用与成岩成矿关系的思考.地学前缘(中国地质大学,北京),2001,8(3):29-38.
[124] 韩发,赵汝松,沈建忠,等.大厂锡多金属矿床地质及成因.北京:地质出版社,1997.
[125] Griffin W L, Slack J F, Ramsden A R, et al. Trace elements in tourmaline from massive sulfide deposits and tourmalinites: Geochemical controls and exploration applications. Economic Geology, 1996,91:657-675.
[126] Roda E, Pesquera A, Velasco F. Tourmaline in granitic pegmatites and their country rocks, Fregeneda area, Salamanca, Spain. Canadian Mineralogist, 1995, 33:835-848.
[127] Chaussidon M, Appel P W U. Boron isotopic composition of tourmalines from the 3.8Ga-old Isua supracrustals, West Greenland:Implications on the δ 11b value of Early Archean seawater. Chemical Geology. 1997, 136:171-180.
[128] DingT P, Jiang S Y, Wan D F, et al. Silicon Isotope Geochemistry. Beijing:Geological Publishing House, 1996, 125.
[129] Musachi M., Oi T., OssakaT., and Kakihana H. Natural boron isotope fractionation between hot spring water and rock in direct contact, Isotopenraxis 1991,27: 163-166.
[130] 肖荣阁,大井隆夫,费红彩,等.辽东沉积变质硼矿床及硼同位素研究.现代地质,2003,17(2):137-142.
[131] 夏学惠.辽东地区硫铁矿床中电气岩热水沉积剖面结构序列.岩石学报,1997,13(2):215-225.
[132] Ishikawa V.T., and Nakamura E. Boron isotope systematics of marine sediments, Earth Planet. Sci. Lett. 1993, 117: 567-580.
[133] Oi T.,Nomura M.,Ossaka T.,Okamoto M., and Kakihana H. Boron isotopic composition of some boron minerals, Geochim. Cosmochim. Acta., 1989,53: 3189-3195.
[134] Swihart G. H., and Moore P.B. Boron isotopic composition of marine and nonmarine evaporite borates, Geochim. Cosmochim. Acta 50, 1986,1297-1301.
[135] Palmer, M.R., Slack ,J. F. Boron isotopic composition of tourmaline from massive sulfide deposits and tourmalines. Contr. Mineralogy and Petrology, 1989,103: 434-451.
[136] Slack J. F., Palmer M.R., and Stavens B. P. J. Boron isotope evidence for the involvement of nonmarine evaporites in the origin of the Broken Hillore deposits, Nature 342, 1989,913-916.
[137] Slack J. F., Palmer M.R., and Stavens B. P. J. Origin and significance of tourmalinerich rocks in the Broken Hill district, Australia. Econ. Geol., 1993,88: 505-511.
[138] 周红春.辽东地区元古界硼矿床矿石学研究[硕士论文].北京:中国地质大学(北京),2006.
[2] 罗锡裕.超硬材料的发展.产业论坛,2000,9:35-38.
[3] 肖荣阁,大井隆夫,野村雅大,等.湘南高温热液矿床中硼同位素组成及分馏作用研究.华南地质与矿产,2001(2),1-7.
[4] 肖荣阁,大井隆夫,候万荣,等.天津蓟县锰方硼石矿物硼同位素研究,现代地质,2002,16(3):270-275.
[5] 孙福.我国西部硼市场前景广阔.建材工业信息,1996,6:19.
[6] 李文光.我国硼矿资源概况及利用.化工矿物与加工,2002,9:37.
[7] 冯本智,朱国林,董清水,等.辽东海城—大石桥超大型菱镁矿矿床的地质特点及成因.长春地质学院学报,1995,25(2):121—124.
[8] Chaussidon M., and Jambon A. Boron content and isotopic composition of oceanic basalts: geochemical and cosmochemic implicationa, Earth Planet. Sci. Lett. 1994, 121: 277-291.
[9] Nomura M.,Okamoto M.,and Kakihana H. Determination of boron content and boron isotopic ratio of seawater samples, Nihon Kaisuigakkai shi 1419, 1984.
[10] A.A.奥佐尔.沉积和火山沉积硼矿.北京:地质出版社,1987.
[11] Donald E. Garrett, Borates, Handbook of Deposits, Processing, Properties, and Use, Academic Press, 1998, California, USA .
[12] Erd, R. C. The minerals of boron. In Mellor's Inorganic and Theoretical Chemistry, Longman, New York., Pt.A. 1980, 5:7-71.
[13] Kistler, R. B., and Helvaci, C. Boron and Borates. In Industrial Minerals and Rocks (S. J. Lefond, ed.), Soc. Min. Eng., AIME., 1994, 171-186.
[14] Helvaci, C., Stamatakis, M.G., Zagouraglou, C., and Kanaris, J. Borate minerals and related authigenic silicates in northeastern Mediterranean Late Miocene continental basins. Explor. Mining Geol. 1993, 2(2):171-178.
[15] Sanford, W.E., and Wood, W.W. Brine evolution and mineral deposition in hydrologically open evaporite basins Am.J. Sci., 1991, 291(7):687-710.
[16] 冯本智,卢静文,邹日,等.中国辽吉地区早元古代大型-超大型硼矿床的形成条件.长春科技大学学报,1998,28(1):1-15.
[17] 姜春潮.辽吉东部前寒武纪地质.沈阳:辽宁科学技术出版社,1987.
[18] 刘敬党,肖荣阁,王文武,等.辽宁宽甸砖庙硼矿区成矿地质特征及找矿.地质与资源,2005,14(2):126-131.
[19] 刘敬党,肖荣阁,王翠芝,等.辽宁大石桥花岗质岩石成因分析及其在硼矿勘查中的意义.吉林大学学报[地球科学版],2005,6:714-719.
[20] 刘敬党.辽东地区下元古界镁硼酸盐矿床控矿模型及其勘查与评价研究:[博士学位论文].北京:中国地质大学(北京),2006.
[21] 李永达.辽东早元古宙构造环境及岩石圈构造.辽宁地质,1992(3).
[22] 王秀璋.东北内生硼矿床的矿物组成和矿床成因研究.北京:科学出版社,1974.
[23] 辽宁省地质局第五勘探队.辽宁省营口县后仙峪硼矿床最终勘探储量报告,1966.
[24] 辽宁省地质局丹东地质大队二队.辽宁省风城县翁泉沟铁硼矿矿床总结勘探报告,1976.
[25] 化学工业部地质勘探公司辽宁地质勘探大队.辽宁省宽甸县砖庙硼矿区栾家沟矿段勘探地质报告,1988.
[26] 张秋生.辽东半岛早期地壳与矿床.北京:地质出版社,1988年.
[27] 化学工业部化学矿产地质研究院.辽东—吉南地区硼矿床控构造研究,1991.
[28] 化学工业部化学矿产地质研究院.辽吉内生硼矿矿物学及找矿标志研究,1993.
[29] 黄作良,王濮,冯本智.辽吉硼矿床矿物学.北京:地质出版社,1999.
[30] 路远发,陈毓川,李华芹,等.辽东古元古代裂谷中硼矿床成矿年代学研究.《地质学报》英文版,2005,79(2):287.
[31] 董中保.变质作用矿床概述.地学前缘,1999,6(2):231-242.
[32] 彭齐鸣,许虹.辽东-吉南地区早元古南变质蒸发岩系及硼矿床.长春:东北师范大学出版社,1994.
[33] Peng, Q.M., Feng, B.Z., Liu, J.D and Zhou, R. Geology of the early Proterozoic boron deposits in eastern Liaoning, Northeastern China. Resources Geology, Special Issue No. 1993,15: 343-350.
[34] Peng Q M, Palmer M R. The Paleoproterozoic boron deposits in eastern Liaoning, China: a metamorphosed evaporite. Precambrian Research, 1995, 72: 185-197.
[35] Qi-ming PENG. The Paleoterozoic Mg-Fe borate deposits Of Liaoning and Jilin Provinces, Northeast China. Economic Geology, 2002, 97:93-108.
[36] Jiang S Y,Palmer M R, Peng Q M,et al. Chemical and stable isotope (B, Si, and O)compositions of Proterozoic metamorphosed evaporite and associated tourmalines from the Houxianyu borate deposit, eastern Liaoning, China. Chem. GeoL., 1997, 135:189-211.
[37] Jiang S Y,Ni P, Ling H F ,et al. Boron isotope geochemistry of borate and magnesite deposits in eastern Liaoning and Jilin provinces of China. in:piestrzynski, et al. eds. Mineral Deposits at the Beginning of the 21st Century. Swets & Zeitlinger publishers Liss. 2001, 987-991.
[38] 冯本智,邹日,谢宏远.辽吉早元古宙裂谷带内含硼热水沉积建造与硼矿床.见:中国地质学会矿床地质专业委员会编.第五届全国矿床地质论文集.北京:地质出版社,1993.512-515.
[39] 冯本智,邹日.辽宁营口后仙峪硼矿床特征及成因:地学前缘,1994,l(4):235-237.
[40] 邹日.营口虎皮峪地区早元古代含硼岩系中热水沉积建造特征及硼矿成因:[博士学位论文].吉林:长春地质学院,1993.
[41] 邹日,冯本智.营口后仙峪硼矿容矿火山—热水沉积岩系特征.地球化学,1995,12,第24卷(增):46-54.
[42] 张景山.辽东硼镁石型硼矿床地质特征及成矿作用.辽宁地质,1994,4:289-324.
[43] 曲洪祥,张国仁,李显东,等.辽东地区硼矿床成矿模式探讨及找矿标志.见:中国地质调查局,辽吉地区地质与成矿研讨会论文集,2001,119-126.
[44] 曲洪祥,郭伟静,张永,等.辽东地区硼矿床成因探讨与硼矿远景区预测.地质与资源,2005,14(2):131-138.
[45] Liu J k, Liu Y J, Chen H, et al. The inner zone of the liaoji paleorift:its early structural styles and structural evolution. Journal of Asian Earth Sciences, 1997,15(1):19-31.
[46] 李江海,侯贵廷,黄雄南,等.华北克拉通对前寒武纪超大陆旋回的基本制约.岩石学报,2001,17(2):177-186.
[47] 王成文,刘永江,李东涛.辽河岩群南北区域对比的新证据.长春地质学院学报,1997,27(1):17-24.
[48] 白瑾.华北陆台北缘前寒武纪地质及铅锌成矿作用.北京:地质出版社,1993,1-123.
[49] 贺高品,叶慧文.辽东-吉南地区早元古代两种类型变质作用及其构造意义.岩石学报,1998,14(2):52-162.
[50] 敖丽娟,王殿忠,张海峰,等.辽宁东部白硼矿矿床特征及找矿方向.见:中国地质调查局,辽吉地区地质与成矿研讨会论文集.北京:中国地质调查局,2001,127-136.
[51] 王殿忠,敖丽娟,王奇.营口东部区含硼蚀变岩带特征及找矿方向.辽宁地质,1998,4:251-260.
[52] 王殿忠,敖丽娟,张海峰,等.辽宁营口东部白硼矿床特征及找矿方向.辽宁地质,2000,17(4),249-258.
[53] 蔡克勤,陈从喜.辽东古元古代镁质非金属矿床成矿系统研究.地球科学—中国地质大学学报,2000,25(4):346-351.
[54] 翟裕生,邓军,彭润民,等.古陆边缘成矿系统.北京:地质出版社,2002.
[55] 辽宁省地质矿产局第七地质大队.辽宁省宽甸县杨木杆硼矿典型矿床研究报告,1986.
[56] 邓晋福,罗照华,苏尚国,等.岩石成因、构造环境与成矿作用.北京:地质出版社,2004.
[57] 化学工业部地质勘探公司辽宁地质勘探大队.辽宁省宽甸满族自治县夹皮沟乡砖庙硼矿区二人沟矿段详查地质报告,1992.
[58] 化学工业部地质勘探公司辽宁地质勘探大队.辽宁省宽甸满族自治县夹皮沟乡砖庙硼矿区花园沟矿段详查地质报告,1993.
[59] 王安平,姚杰,曹林.辽东硼矿中遂安石的微结构研究及其地质意义.世界地质,1997,16(4),27-30.
[60] 王翠芝,肖荣阁,刘敬党,等.辽宁营口后仙峪硼矿区超镁橄榄岩的岩石学特征.2006年全国博士生学术论坛论文集-地球科学领域.北京:中国地质大学(北京).2006:213-221.
[61] 王翠芝,肖荣阁,刘敬党,等.辽宁营口后仙峪硼矿区超镁橄榄岩的地球化学特征及其对源区的约束.中国地质,2006,33(6):1247-1255.
[62] 倪心垣,巴登珠,杨茂同.西藏上地幔橄榄岩及铬铁矿矿石结构构造图册.武汉:中国地质大学出版社,1992.
[63] 北京大学地质系岩矿教研室.岩石和岩体野外工作方法.北京:地质出版社,1979.
[64] 喻学惠.甘肃西秦岭区新生代碱性火山岩中的钛金云母.岩石矿物杂志,1994,13(4):319-327.
[65] 黄作良,王濮.辽吉内生硼矿反吸收金云母的发现及其地质意义.化工地质,1991,16(1):11-16.
[66] Viljoen R P,Viljoen M J.科马提岩—历史回顾.颜乘纲,王炳熙,白文吉等译.北京:地质出版社,1986.
[67] Arnolt N T,Nisbet E G.科马提岩.颜乘纲,王炳熙,白文吉,等译.北京:地质出版社,1986.
[68] 谭劲,赵珊茸,莫宣学.非均匀温度场中熔体结品作用与科马提岩结构成因.地质科技情报,1994,13(4):35-40.
[69] 李仰春,赵海滨,杨晓平,等.大兴安岭吉峰地区中元古代科马提岩及成因类型.地质与资源,2002,11(2):76-82.
[70] 杨晓明.后仙峪硼矿区金云母蚀变岩与硼矿化之关系初探.化工矿产地质,1998,20(1):38-40.
[71] 王翠芝,肖荣阁,刘敬党,等.辽东吉南硼矿矿石特征及其与容矿岩石的关系.矿产地质,2006年增刊:277-280.
[72] 邱家骧.岩浆岩岩石学.北京:地质出版社,1983.
[73] Le Maitre (ed). Igneous Rocks: A Classification and Glossary of Terms (2nd edition). Cambridge University Press, 2002.
[74] 王中刚,于学元,赵振华,等.稀土元素地球化学.北京:科学出版社,1989.
[75] 李昌年.火成岩微量元素岩石学.武汉:中国地质大学出版社,1992.
[76] 陈树良,郇彦清,邴志波.辽东地区古元古代侵入岩特征及构造岩浆大陆动力学演化.辽宁地质,2001,18(1):43-51.
[77] Allegre, C. J. and Hart, S. R. Trace elements in Ignous petrology. Developments in Petrology, 1973, 5. New York.
[78] N.T.Amdt and E.G.Nisbet.颜秉纲,王炳熙,白文吉,等译.KOMATIITES.北京:地质出版社,1985.
[79] 王希斌,鲍佩声,戎合.中国蛇绿岩中变质橄榄岩的稀士元素地球化学.岩石学报,1996,11(增刊):24-41.
[80] 邱瑞照,邓晋福,周肃,等.青藏高原西部蛇绿岩类型:岩石学与地球化学证据.地学前缘,2005,12(5):277-291.
[81] 董显扬,李行,叶良和,等.中国超镁铁质岩.北京:地质出版社,1995.
[82] Hugh Rollinson. Petrology and geochemistry of metamorphosed komatiites and basalts from the Sula Mountains greenstone belt, Sierra Leone. Contrib Mineral Petrol, 1999, 134: 86—101.
[83] Hess P C. Phase equilibria constraints on the origin of ocean floorbasalts .Morgen J P Blackman D K Sinton J M. MantleFlow and Melt Generation at Mid-Ocean Ridges OxfordPergamon 1992,67-102.
[84] Hugh R. Rollonson. Using Geochemical Data-Evalution, Presention, interpretation. Pearson Education limited, 1993.
[85] 潘兆橹.结晶学及矿物学(下册).北京:地质出版社,1993.
[86] 李建平,Jacques Kornprobst,Daniel Vielzeuf.地慢橄榄岩部分熔融及相转变(尖晶石相~斜长石相)过程中的固相化学成分演化—Ⅰ实验研究,地球化学,1996,25(1):39-52.
[87] 牛贺才,许继锋,于学元,等.新疆阿尔泰富镁火山岩系的发现及其地质意义.科学通报,1999,44(9):1002-1004.
[88] 张旗,宝林,刘若新,等.一个消减带之上的大陆岩石圈地慢残片—安徽饶拨寨超镁铁岩的地球化学特征.中国科学 (D)1995,25(8):867-873.
[89] 董云鹏,王润三,周鼎武.南天山北缘榆树沟变质基性-超基性岩的地球化学及其成因机制.地球化学,2001,30(6):559-568.
[90] 赵伦山,张本仁.地球化学.北京:地质出版社,1988.
[91] 刘月星,唐红松,吴厚泽.中国铜镍硫化物矿床类型及控矿条件.Mineral Resources And Geology,1998,64(12):86-90.
[92] 张招崇,毛景文,杨建民,等.北祁连熬油沟蛇绿岩岩石成因的地球化学证据.地质学报,1998,72(1):42-51.
[93] 曹德成.丹东地区古元古市成矿系列及找矿方向.见:中国地质调查局,辽吉地区地质与成矿研讨会论文集.北京:中国地质调查局,2001.58-65.
[94] 张泽军.北秦岭松树沟超镁铁质岩中两类不同成因的纯橄榄岩.岩石学报,1995,11(增):178-189.
[95] C. R. Friend, V.C. Bennett, A. P. Numan. Abyssal peridotites>3800Ma from southern west Greenland:field relationships, petrography, geoxhronology, whole-rock and mineral chemistry of dunite and harxburgite inclusions in the ltsaq gneiss complex. Contrib Mineral petrol, 2002, 143:71-92.
[96] 邓宏文,钱凯.沉积地球化学与环境分析.兰州:甘肃科学技术出版社,1993.
[97] Xuehui Xia, Fei Yan, YuHai Zhao, et. al. Geological features and mineralization of the uranium-bearing vonsenite deposit in the Liaodong rift. Mineral Deposit Research:meeting the global challenge. The 8~# Beinnial SGA Meeting, 2005.
[98] Feihongcai et. al. Geochemical characteristics and genesis of Na-rich rocks in the bayan obo REE-Nb-Fe deposit, inner Mongolia, china, the 8th Biennial SGA meeting, August 18-21,2005.
[99] 武钢第二炼钢厂.复吹转炉溅护炉实用技术.北京:.冶金工业出版,2004.
[100] 王生志,徐大地,张琦.后仙峪硼矿区硼矿地质特征及其成因探讨.地质与资源,2003,12(4),221-227.
[101] 全国矿产储量委员会.硼矿床勘探类型实例附图(硼矿地质勘探规范附件,内部资料).1987.
[102] 王翠芝,肖荣阁,刘敬党,等.辽宁营口后仙峪硼矿区超镁橄榄岩的控矿作用.矿产地质,2006,25(6):683-692.
[103] Ozol A. A. Basic characteristics of boron geochemistry and formation conditions for volcanic-sedimentary type boron deposits, USSR, Litol. Polezn. Iskop., 1976, 3: 60-74.
[104] Smith, G.I. Borate deposits in the United States:Dissimilar in form, similar in geologic setting, In borates, Economic Geology and Production (J.M. Barker and S.J. Lefond, eds.), Soc. Min. Eng., AIMMPE, New York, 1985, 37-51.
[105] Crowley, J.K. Mg- and K-bearing borates and associated □aporates at Eagle Borax Spring, Death Valley, California:A spectroscopic exploration: Economic Geology, 1996, 91: 622 - 635.
[106] Barker, C. E. Geology of the Terry borate deposit..California Geology , 1980, 33(8): 181-189.
[107] Barker, C. E., andBarker, J.M. Borate deposits, DeathValley, California. InBorates: Economic Geology and Production(J. M. barker and S. J. Lefond, eds.), Soc. Min. Eng., AIMMPE, New York, 1985, 103-135.
[108] Barker, J.M., and Wilson, J.L. Borate deposits in the Death Valley region, in Guidebook:Las Vegas to Death Valley and Return: Nevada Bureau of Mines and Geology, Report 26, 1975, 23-32.
[109] Joe W.Siefke.美国克拉莫硼矿床及波热露天硼矿.内蒙古地质,1999,第4期,37—41(张德平译自, 1995, 29th Forumon the Geology of Industrial Minerals: Proceedings; California Department of Conservation, Divisionof Minesand Geology Special Publication 110, p. 181-188. )
[110] Sieke, J. W. The Boron open pit mine at the Kramer borate deposit: The diversity of mineral and energy resources of southern California. Soc. Econ. Geol. Guidebook Series 12, 1991, 4-15.
[111] Helvaci, C., and Firman, R.J. Geological setting and mineralogy of Emet borate deposits, Turkey: Institution of Mining and Metallurgy, Transactions, sect. B, 1976, 85:142 - 152.
[112] Melvaci, C. Stratigraphy, mineralogy and genesis of the Bigadic, borate deposits, western Turkey: Economic Geology, 1995, 90: 1237-1260.
[113] Helvaci, C., and Yagmurlu, F. Geological setting and economic potential of the lignite and evaporite-bearing Neogene basins of western Anatolia, Turkey: Israel Journal of Earth Sciences, 1995, 44:91-105.
[114] Inan, K., Dunham, A.C., and Esson, J. Mineralogy, chemistry and origin of Kirkaborate deposits, Eskisehir Province, Turkey: Institution of Mining and Metallurgy, Transactions, Sect.B,1973,82:114-123.
[115] 肖荣阁,原振雷,刘敬党,等.区域成矿流体的形成与演化.地学前缘(中国地质大学,北京),2004,11(2):461-469.
[116] 翟裕生,彭润民,向运川,等.区域成矿研究法.北京:中国大地出版社,2004,60-66.
[117] 梁婷,高景刚,朱文戈.成矿流体类型及研究方法综述.西安文理学院学报(自然科学版),2005,8(4):323-328.
[118] S pearfs. Metamorphic Phase Equilibria and Pressure-Temperature-Time Paths[M]. Washington D C: Mineralogical Society of America, 1993, 19: 673-708.
[119] 游振东,钟增球,周汉文.区域变质作用中的流体.地学前缘(中国地质大学,北京),2001,8(3):157-164.
[120] 徐德义,於崇文,鲍征宁.热液成矿系统中—维反应扩散过程的混沌边缘.地学前缘(中国地质大学,北京),2004,11(1):99-103.
[121] 徐德义,於崇文,鲍征宇.热液成矿分带的径向对称性.地学前缘(中国地质大学,北京),2005,12(2):303-308.
[122] 刘新秒,李长民.混合岩形成模式的研究进展.前寒武纪研究进展,2001,24(4):237-246.
[123] 李兆麟.关于变质深熔作用与成岩成矿关系的思考.地学前缘(中国地质大学,北京),2001,8(3):29-38.
[124] 韩发,赵汝松,沈建忠,等.大厂锡多金属矿床地质及成因.北京:地质出版社,1997.
[125] Griffin W L, Slack J F, Ramsden A R, et al. Trace elements in tourmaline from massive sulfide deposits and tourmalinites: Geochemical controls and exploration applications. Economic Geology, 1996,91:657-675.
[126] Roda E, Pesquera A, Velasco F. Tourmaline in granitic pegmatites and their country rocks, Fregeneda area, Salamanca, Spain. Canadian Mineralogist, 1995, 33:835-848.
[127] Chaussidon M, Appel P W U. Boron isotopic composition of tourmalines from the 3.8Ga-old Isua supracrustals, West Greenland:Implications on the δ 11b value of Early Archean seawater. Chemical Geology. 1997, 136:171-180.
[128] DingT P, Jiang S Y, Wan D F, et al. Silicon Isotope Geochemistry. Beijing:Geological Publishing House, 1996, 125.
[129] Musachi M., Oi T., OssakaT., and Kakihana H. Natural boron isotope fractionation between hot spring water and rock in direct contact, Isotopenraxis 1991,27: 163-166.
[130] 肖荣阁,大井隆夫,费红彩,等.辽东沉积变质硼矿床及硼同位素研究.现代地质,2003,17(2):137-142.
[131] 夏学惠.辽东地区硫铁矿床中电气岩热水沉积剖面结构序列.岩石学报,1997,13(2):215-225.
[132] Ishikawa V.T., and Nakamura E. Boron isotope systematics of marine sediments, Earth Planet. Sci. Lett. 1993, 117: 567-580.
[133] Oi T.,Nomura M.,Ossaka T.,Okamoto M., and Kakihana H. Boron isotopic composition of some boron minerals, Geochim. Cosmochim. Acta., 1989,53: 3189-3195.
[134] Swihart G. H., and Moore P.B. Boron isotopic composition of marine and nonmarine evaporite borates, Geochim. Cosmochim. Acta 50, 1986,1297-1301.
[135] Palmer, M.R., Slack ,J. F. Boron isotopic composition of tourmaline from massive sulfide deposits and tourmalines. Contr. Mineralogy and Petrology, 1989,103: 434-451.
[136] Slack J. F., Palmer M.R., and Stavens B. P. J. Boron isotope evidence for the involvement of nonmarine evaporites in the origin of the Broken Hillore deposits, Nature 342, 1989,913-916.
[137] Slack J. F., Palmer M.R., and Stavens B. P. J. Origin and significance of tourmalinerich rocks in the Broken Hill district, Australia. Econ. Geol., 1993,88: 505-511.
[138] 周红春.辽东地区元古界硼矿床矿石学研究[硕士论文].北京:中国地质大学(北京),2006.
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