浙西南八都群早前寒武纪变质演化与年代学研究
|
摘要
浙西南地区位于华夏陆块中北部,处于华夏陆块和江南造山带的交接部位,同时该地区也是欧亚大陆和太平洋板块相互作用的焦点位置。区域内呈“窗口状”出露于显生宙盖层中的早元古代八都群,是华夏陆块内部目前已知的分布范围最大、形成时代最古老、变质程度最深、地质演化最复杂的变质岩石地层。通过对八都群详细的野外地质工作,以及详细的岩石化学、矿物化学、变质演化和年代学的研究,主要取得了以下几个方而的新认识:
在华夏地块古老基底中首次发现了具有“石榴石+正/反条纹长石+夕线石”特征组合的泥质麻粒岩,表明其曾经历广泛的区域麻粒岩相变质作用。
含榴长英质片麻岩的原岩为以高Si富Al为特征的地壳重熔型过铝质花岗岩。夕线石榴黑云片麻岩的原岩为泥沙质沉积岩。石榴角闪斜长片麻岩和石榴二辉石麻粒岩的原岩类型相同,地球化学特征显示它们的原岩为安山岩-英安岩(花岗闪长岩)。两种岩石在主微量元素、稀土元素含量上的差别,证明在变质级别不同的变质作用中,元素迁移规律有一定差异。
首次对三种典型变质岩:夕线石榴黑云片麻岩、石榴角闪斜长片麻岩和石榴二辉石麻粒岩进行了详细的变质演化研究。三种岩石的变质演化,均可以划分为三阶段的演化过程:早期进变质阶段(M1)、变质峰期阶段(M2)和峰后降压冷却阶段(M3)。夕线石榴黑云片麻岩的峰期阶段温压条件为:800-850℃、0.60-0.70Gpa;峰后降压冷却阶段温度压力估算结果分别为560-590℃、0.25-0.33Gpa;石榴角闪斜长片麻岩的峰期角闪岩相-低麻粒岩相变质阶段(M2)温度压力范围为:T=770-830℃,P=0.82-0.92Gpa,峰后的角闪岩相变质阶段(M3)温度压力范围为:T=580-630℃,P=0.52-0.73Gpa;石榴二辉石麻粒岩峰期麻粒岩相变质阶段(M2)温度压力估算结果:T=850-900℃,P=0.92-1.10Gpa,峰后的角闪岩相变质阶段(M3)温度压力范围为:T=650-700℃,P=0.58-0.65Gpa。
三种典型变质岩的变质演化,都具有顺时针样式的PT轨迹,表现为峰期后同时发生降温、降压,但降压程度大于降温,反映了一种加厚地壳快速减薄的动力学过程。
通过对八都群中富铝片麻岩、变酸性火成岩、变基性火成岩和大理岩等典型变质岩石开展锆石SHRIMP和LA-ICPMS U-Pb体系定年分析,确定其麻粒岩相变质作用发生的时代为18.5-18.8亿年。富铝片麻岩多数锆石具有2002±29Ma和2451±63Ma等两个时段的源区特征,表明其物质主要来源于古元古代以前的古老地体。变酸性岩的成岩时代1923±7.6Ma,在18.7亿年左右发生变质,含有20-28亿年的继承锆石核,最古老继承锆石年龄为2803±34Ma。
浙西南八都群古元古代变质表壳岩所经历的麻粒岩相变质作用和区域广泛发育的S型和A型花岗质岩浆活动,表明其曾经历完整的造山作用过程,其成因很可能与全球1.8-2.1Ga哥伦比亚超大陆的聚合事件有关。
The southwestern Zhejiang region is situated in the middle of the northern Cathaysia Block, which is the boundary of the Cathaysia Block and the Jiangnan orogenic belt, also it the focal area where the Eurasia and the Pacific plate interact with each other. The Paleoproterozoic Badu group outcrops as windows among the phanerozoic cover. By far, it is the oldest rock stratigraphic unit which has experienced the highest level of metamorphism and has the most complicated history of evolution and biggest outcropping area in the Cathaysia Block. Through a combined study of metamorphic evolution, geochemistry and geochronology, we get mainly these following several new findings.
In this dissertation, we report pelitic granulite, with mineral assemblage of garnet, perthite and anti-perthite, sillimanite, for the first time that was discovered in the basement of Cathaysia block. This discovery suggests that the area experienced regional metamorphism of up to granulite facies.
The protolith of garnet-bearing felsic gneiss is granite generated from the remelting of crustal materials, which is characterized by high content of A1and Si. The protolith of sillimanite garnet biotite gneiss is pelitic to sandy sedimentary rock. The protoliths of garnet amphibole plagiogneiss and garnet two-pyroxene granulite are of the same, which are both andesite-dacite rocks, as are shown by their geochemical characteristics. The slight differences in major and trace elements of the two meta-igneous rocks show that elements migrate differently in metamorphic processes of various metamorphic facies.
We present here, for the forst time, the study results of metamorphic evolution of the three different rock types: sillimanite garnet biotite gneiss, garnet amphibole plagiogneiss and garnet two-pyroxene granulite. Three stages of metamorphic evolution can be recognized in all three rocks:early prograde metamorphic stage (M1), peak metamorphic stage (M2) and after peak retrograde metamorphic stage (M3). The PT conditions of the early prograde metamorphic stage are altered in all three metamorphic rocks and they record the PT conditions of only the two later metamorphic stages. For the peraluminous gneiss, the PT condition of the peak metamorphic stage(M2) is800~850℃,0.60~0.70Gpa; the PT condition of the after peak retrograde metamorphic stage (M3) is560~590℃、0.25~0.33Gpa. For the garnet amphibole plagiogneiss, during the peak metamorphic stage (M2), the PT condition is770-830℃,0.82-0.92Gpa; during the after peak retrograde metamorphic stage (M3), the PT condition is580-630℃,0.52-0.73Gpa. For the garnet two-pyroxene granulite, during the peak metamorphic stage (M2), the PT condition is850-900℃,0.92-1.10Gpa; the PT condition of after peak retrograde metamorphic stage (M3) is650-700℃,0.58-0.65Gpa.
The three representative metamorphic rocks mentioned above all recorded PT paths of clockwise style. After peak metamorphic stage, cooling happenned as well as decompression. But the rocks decompressed to a greater extent than that of cooling. Such a process usually happens during the fast thinning of thickened crust.
SHRIMP and LA-ICPMS zircon-U-Pb-dating of peraluminous gneiss, meta-acid-igneous rock, meta-mafic rocks and marble show the early precambrian metamorphism occoured around1.85-1.88Ga. Zircons of peraluminous gneiss show source rocks with the age of2002±29Ma and2451±63Ma, which suggests that the its protolith, the sediments, was from mainly paleoproterozoic terrains. The acid granite, which formed around1923±7.6Ma, experienced metamorphism at about1.87Ga. The zircons of the granite also contain inherited cores ranging from2.0-2.8Ga, with the oldest of2803±34Ma.
The paleoproterozoic granulite facies metamorphism recorded in the supracrustal rocks of the Radu group in southwestern Zhejiang province and the widespread of S-and A-type granites in the region show that this area experienced the whole process of a paleoproterozoic orogeny, which might be resulted from the amalgamation of the supercontinent Columbia between1.8and2.1Ga around the world.
在华夏地块古老基底中首次发现了具有“石榴石+正/反条纹长石+夕线石”特征组合的泥质麻粒岩,表明其曾经历广泛的区域麻粒岩相变质作用。
含榴长英质片麻岩的原岩为以高Si富Al为特征的地壳重熔型过铝质花岗岩。夕线石榴黑云片麻岩的原岩为泥沙质沉积岩。石榴角闪斜长片麻岩和石榴二辉石麻粒岩的原岩类型相同,地球化学特征显示它们的原岩为安山岩-英安岩(花岗闪长岩)。两种岩石在主微量元素、稀土元素含量上的差别,证明在变质级别不同的变质作用中,元素迁移规律有一定差异。
首次对三种典型变质岩:夕线石榴黑云片麻岩、石榴角闪斜长片麻岩和石榴二辉石麻粒岩进行了详细的变质演化研究。三种岩石的变质演化,均可以划分为三阶段的演化过程:早期进变质阶段(M1)、变质峰期阶段(M2)和峰后降压冷却阶段(M3)。夕线石榴黑云片麻岩的峰期阶段温压条件为:800-850℃、0.60-0.70Gpa;峰后降压冷却阶段温度压力估算结果分别为560-590℃、0.25-0.33Gpa;石榴角闪斜长片麻岩的峰期角闪岩相-低麻粒岩相变质阶段(M2)温度压力范围为:T=770-830℃,P=0.82-0.92Gpa,峰后的角闪岩相变质阶段(M3)温度压力范围为:T=580-630℃,P=0.52-0.73Gpa;石榴二辉石麻粒岩峰期麻粒岩相变质阶段(M2)温度压力估算结果:T=850-900℃,P=0.92-1.10Gpa,峰后的角闪岩相变质阶段(M3)温度压力范围为:T=650-700℃,P=0.58-0.65Gpa。
三种典型变质岩的变质演化,都具有顺时针样式的PT轨迹,表现为峰期后同时发生降温、降压,但降压程度大于降温,反映了一种加厚地壳快速减薄的动力学过程。
通过对八都群中富铝片麻岩、变酸性火成岩、变基性火成岩和大理岩等典型变质岩石开展锆石SHRIMP和LA-ICPMS U-Pb体系定年分析,确定其麻粒岩相变质作用发生的时代为18.5-18.8亿年。富铝片麻岩多数锆石具有2002±29Ma和2451±63Ma等两个时段的源区特征,表明其物质主要来源于古元古代以前的古老地体。变酸性岩的成岩时代1923±7.6Ma,在18.7亿年左右发生变质,含有20-28亿年的继承锆石核,最古老继承锆石年龄为2803±34Ma。
浙西南八都群古元古代变质表壳岩所经历的麻粒岩相变质作用和区域广泛发育的S型和A型花岗质岩浆活动,表明其曾经历完整的造山作用过程,其成因很可能与全球1.8-2.1Ga哥伦比亚超大陆的聚合事件有关。
The southwestern Zhejiang region is situated in the middle of the northern Cathaysia Block, which is the boundary of the Cathaysia Block and the Jiangnan orogenic belt, also it the focal area where the Eurasia and the Pacific plate interact with each other. The Paleoproterozoic Badu group outcrops as windows among the phanerozoic cover. By far, it is the oldest rock stratigraphic unit which has experienced the highest level of metamorphism and has the most complicated history of evolution and biggest outcropping area in the Cathaysia Block. Through a combined study of metamorphic evolution, geochemistry and geochronology, we get mainly these following several new findings.
In this dissertation, we report pelitic granulite, with mineral assemblage of garnet, perthite and anti-perthite, sillimanite, for the first time that was discovered in the basement of Cathaysia block. This discovery suggests that the area experienced regional metamorphism of up to granulite facies.
The protolith of garnet-bearing felsic gneiss is granite generated from the remelting of crustal materials, which is characterized by high content of A1and Si. The protolith of sillimanite garnet biotite gneiss is pelitic to sandy sedimentary rock. The protoliths of garnet amphibole plagiogneiss and garnet two-pyroxene granulite are of the same, which are both andesite-dacite rocks, as are shown by their geochemical characteristics. The slight differences in major and trace elements of the two meta-igneous rocks show that elements migrate differently in metamorphic processes of various metamorphic facies.
We present here, for the forst time, the study results of metamorphic evolution of the three different rock types: sillimanite garnet biotite gneiss, garnet amphibole plagiogneiss and garnet two-pyroxene granulite. Three stages of metamorphic evolution can be recognized in all three rocks:early prograde metamorphic stage (M1), peak metamorphic stage (M2) and after peak retrograde metamorphic stage (M3). The PT conditions of the early prograde metamorphic stage are altered in all three metamorphic rocks and they record the PT conditions of only the two later metamorphic stages. For the peraluminous gneiss, the PT condition of the peak metamorphic stage(M2) is800~850℃,0.60~0.70Gpa; the PT condition of the after peak retrograde metamorphic stage (M3) is560~590℃、0.25~0.33Gpa. For the garnet amphibole plagiogneiss, during the peak metamorphic stage (M2), the PT condition is770-830℃,0.82-0.92Gpa; during the after peak retrograde metamorphic stage (M3), the PT condition is580-630℃,0.52-0.73Gpa. For the garnet two-pyroxene granulite, during the peak metamorphic stage (M2), the PT condition is850-900℃,0.92-1.10Gpa; the PT condition of after peak retrograde metamorphic stage (M3) is650-700℃,0.58-0.65Gpa.
The three representative metamorphic rocks mentioned above all recorded PT paths of clockwise style. After peak metamorphic stage, cooling happenned as well as decompression. But the rocks decompressed to a greater extent than that of cooling. Such a process usually happens during the fast thinning of thickened crust.
SHRIMP and LA-ICPMS zircon-U-Pb-dating of peraluminous gneiss, meta-acid-igneous rock, meta-mafic rocks and marble show the early precambrian metamorphism occoured around1.85-1.88Ga. Zircons of peraluminous gneiss show source rocks with the age of2002±29Ma and2451±63Ma, which suggests that the its protolith, the sediments, was from mainly paleoproterozoic terrains. The acid granite, which formed around1923±7.6Ma, experienced metamorphism at about1.87Ga. The zircons of the granite also contain inherited cores ranging from2.0-2.8Ga, with the oldest of2803±34Ma.
The paleoproterozoic granulite facies metamorphism recorded in the supracrustal rocks of the Radu group in southwestern Zhejiang province and the widespread of S-and A-type granites in the region show that this area experienced the whole process of a paleoproterozoic orogeny, which might be resulted from the amalgamation of the supercontinent Columbia between1.8and2.1Ga around the world.
引文
陈斌,庄育勋.1994.粤西云炉紫苏花岗岩及其麻粒岩包体的主要特点和成因讨论.岩石学报,10(2):139-150.
陈迪云,徐伟昌.1993.浙江陈蔡群变质岩变质条件及构造环境的地球化学探讨[J].矿物岩石,(02):29-36.
陈惠芳.1991.海南岛前寒武纪结晶基底和科马提岩的发现.大地构造与成矿学(01):62.
丁式江.1995.琼西戈枕侵入体的地质特征及其发现意义.大地构造与成矿学,19(4):336-343.
丁式江,胡健民,宋彪,陈沐龙,谢盛周和范渊.2005.海南岛抱板群内顺层侵位深熔花岗岩钻石U-Pb定年及其构造意义.中国科学(D辑:地球科学)(10):33-44.
丁兴,周新民,孙涛.2005.华南陆壳基底的幕式生长——来自广东古寨花岗闪长岩中锆石LA-ICPMS定年的信息.地质论评,51(04):382-392.
杜杨松,Collerson K D.,赵建新,等.1999.两广交界地区S型花岗岩中麻粒岩包体的特征和成因[J].岩石学报,15(2):303-314.
付建明.1996.海南岛加里东期花岗岩的发现.中国区域地质(02):175.
付树超,陈觉民,林文生.1991.福建建宁西部上太古界天井坪组(Ar2t)地质特征.福建地质(02):103-113
甘晓春,李惠民,孙大中.1993.闽北前寒武纪基底的地质年代学研究[J].福建地质,12(01):17-32.
甘晓春,季惠民,孙大中,金文山,赵凤清.1995.浙西南早元古代花岗质岩石的年代.岩石矿物学杂志,14(01):1-8.
葛小月,2003.海南岛中生代岩浆作用及其构造意义.博士Thesis,中国科学院研究生院(广州地球化学研究所)
郭福祥.1997.华南地区不存在印支碰撞造山带.贵州地质(02):173.
侯威,陈惠芳,梁新权和王可伏.1992.海南岛前寒武纪地层的确定其大地构造演化.长春地质学院学报(02):136-143.
胡雄健.1994.浙西南下元古界八都群的地质年代学.地球化学,23(S1):18-24.
胡雄健,许金坤和童朝旭.1991.浙西南前寒武纪地质.北京:地质出版杜:1—278.
胡雄健,许金坤,陈程华,李春忠,李惠民.1992.浙西南早元古代花岗岩、伟晶岩的单颗粒锆石U-Pb年龄.科学通报(11):1016-1018.
靳新娣,朱和平.2000.岩石样品中43种元素的高分辨等离子质谱测定.分析化学(05):563-567.
靳是琴,李鸿超.1984.成因矿物学概论.长春:吉林大学出版社
金文山和孙大中,1997.华南大陆深部地壳结构及其演化.地质出版社
孔祥生,李东正,冯长根,1995.浙江省陈蔡地区前寒武纪地质.地质出版社,北京
兰玉琦,叶瑛,兰翔,等.1995.浙江陈蔡群孔兹岩系的变质地质学研究[J].浙江大学学报,29(3):303-309.
劳秋元,施央申,卢华复和马瑞士.1994.东海的构造地层地体.现代地质学研究文集(下),南京:南京大学出版社:81-91.
李继亮,孙枢,许靖华,陈海泓,彭海波,王清晨.1989.南华夏造山带构造演化的新证据.地质科学(03):217-225.
李兼海,王国平,郑铁藩,梁诗经,李超岭,1997.福建省岩石地层.地质大学出版社:1-216
李曙光,陈移之,葛宁洁,胡雄健,刘德良.1996.浙西南八都群变火山岩系及变晶糜棱岩的同位素年龄及其构造意义.岩石学报,12(01):79-87.
李献华.1990.万洋山—诸广山花岗岩复式岩基的岩浆活动时代与地壳运动.中国科学:B辑(007):747-755.
李献华,周汉文,丁式江,李寄喁,张仁杰,张业明和葛文春.2000.海南岛“邦溪-晨星蛇绿岩片”的时代及其构造意义——Sm-Nd同位素制约.岩石学报(03):425-432.
李献华,王一先,赵振华,陈多福,张宏.1998.闽浙古元古代斜长角闪岩的离子探针锆石U-Pb年代学.地球化学,27(04):327-334.
梁新权.1995.海南岛前寒武纪花岗岩-绿岩系Sm-Nd同位素年龄及其地质意义.岩石学报(01).
梁新权,范蔚茗和许德如.2000.海南岛屯昌玄武质科马提岩Sm-Nd同位素年龄及其地质意义.地质科学(02):240-244.
林庆华,李立源和梁明国.1990.粤西合水、思贺地区花岗质岩石的成因.中国区域地质(02):173-180.
刘平华,刘福来,王舫,刘建辉.2010.山东半岛基型高压麻粒岩的成因矿物学及变质演化.岩石学报,07(026):2039-2056.
刘邦秀,刘春根和邱永泉.2001.江西南部鹤仔片麻状花岗岩类Pb-Pb同位素年龄及地质意义.火山地质与矿产(04):264-268.
刘福来,施建荣,刘建辉,叶建国,刘平华和王舫.2011.北苏鲁威海地区超基性岩的原岩形成时代和超高压变质时代.岩石学报(04):1075-1084.
刘福来,叶建国和薛怀民.2006.北苏鲁超高压变质岩锆石中的矿物包体.地质学报(12):1817-1830.
刘锐,2009.华夏地块前海西期地壳深熔作用——以浙闽地区为例.博士Thesis,中国地质大学
刘锐,周汉文,张利,钟增球,曾雯,向华,靳松,吕新前,李春忠.2009.华夏地块古元古代陆壳冉造:锆石微量元素与U-Pb和Lu-Hf同位素证据.科学通报,54(7):906-917.
卢华复.2006.关于华夏古陆.高校地质学报(04):413-417.
卢良兆,徐学纯,刘福来.1996.中国北方早前寒武纪孔兹岩系.长春:长春出版社,1-277
马大铨,黄香定,陈哲培,肖志发,张旺驰和钟盛中.1997.海南省抱板群研究的新进展.中国区域地 质(02).
马瑞士.2006.华南构造演化新思考兼论“华夏古陆”说中的几个问题.高校地质学报,12(04):448-456.
彭松柏,金振民,付建明,等.2004.紫苏花岗岩成因及构造意义[J].华南地质与矿产,(04):63-70.
彭松柏,付建明和刘云华.2004a.大容山-十万大山花岗岩带中A型紫苏花岗岩、麻粒岩包体的发现及意义.科学技术与工程(10):832-834.
彭松柏,金振民,付建明,何龙清,蔡明海和刘云华.2004b.粤西新元古代蛇绿岩的发现及其地质意义.科学技术与工程(12):1006-1012.
彭松柏,金振民,付建明,刘云华,何龙清,蔡明海和王彦斌.2005.云开造山带条带-眼球状(环斑)强过铝花岗岩的岩石地球化学、年代及成因.科学技术与工程(17):1238-1246.
彭松柏和张业明.1999.云开隆起区花岗质岩石同位素定年及其构造意义.地质科技情报(02):15.
覃小锋,潘元明,李江,李容森,周府生,胡贵昂和钟锋运.2006.桂东南云开地区变质杂岩锆石SHRIMP U-Pb年代学.地质通报(05):553-559.
沈渭洲.2006.华夏地块基底变质岩同位素年龄数据评述.高校地质学报(04):475-482.
舒良树.2006.华南前泥盆纪构造演化:从华夏地块到加里东期造山带.高校地质学报,12(004):418-431.
宋彪,张玉海和刘敦一.2002.微量原位分析仪器SHRIMP的产生与锆石同位素地质年代学.质谱学报(01):58-62.
王可伏,范蔚茗,侯威,陈惠芳和梁新权.1992.海南岛土外山古元古代玄武岩成因探讨.地质地球化学(06):72-73+15.
王可伏,范蔚茗,侯威,陈惠芳,梁新权.1994.海南岛土外山早元古代玄武岩的成因—主要元素、微量元素和Sm—Nd同位素证据.地质与勘探(04):30-36.
王丽娟,于津海,孙涛,魏震洋.2007.华夏地块南部可能存在Grenville期造山作用:来自基底变质岩中锆石U-Pb定年信息.全国岩石学与地球动力学暨化学地球动力学研讨会,武汉.
汪新.1988.浙闽板块碰撞造山带研究.南京大学.
王孝磊,周金城,邱检生,张文兰,柳小明和张桂林.2006.桂北新元古代强过铝花岗岩的成因:锆石年代学和Hf同位素制约.岩石学报(02):326-342.
王孝磊,舒徐洁,邢光福,谢思文,张春晖和夏晗.2012.浙江诸暨地区石角-璜山侵入岩LA-ICP-MS锆石U-Pb年龄——对超镁铁质球状岩成因的启示.地质通报(01):75-81.
王银喜,杨杰东,郭令智,等.1992.浙江龙泉早元古代花岗岩的发现及基底时代的讨论[J].地质评论,(06):525-531.
魏春景.2011.变质作用p-T-t轨迹的研究方法与进展.地学前缘(02):1-16.
吴富江和张芳荣.2003.华南板块北缘东段武功山加里东期花岗岩特征及成因探讨.中国地质(02):166-172.
向华,张利,周汉文,钟增球,曾雯,刘锐,靳松.2008.浙西南变质基底基性-超基性变质岩锆石 U-Pb年龄、Hf同位素研究:华夏地块变质基底对华南印支期造山的响应.中国科学(D辑:地球科学)(04):401-413.
许靖华.1987.中国南方大地构造的几个问题.地质科技情报(02):13-27.
许靖华,孙枢,李继亮.1987.是华南造山带而不是华南地台.中国科学(B辑化学生物学农学医学地学)(10):1107-1115.
许德如,夏斌,李鹏春,张玉泉,陈广浩和马驰.2006.海南岛北西部前寒武纪花岗质岩SHRIMP锆石U-Pb年龄及地质意义.大地构造与成矿学(04):510-518.
徐先兵,张岳桥,舒良树,贾东,王瑞瑞和许怀钾.2010.武夷山地区前寒武纪地层沉积时代研究.地层学杂志(03):254-267.
杨杰东,徐士进,王银喜,等.1994.浙江龙泉八都群斜长角闪岩的Sm-Nd和Rb-Sr年龄测定及其意义[J].地球化学,23(S1):25-31.
于津海,王丽娟,王孝磊,邱检生和赵蕾.2007.赣东南富城杂岩体的地球化学和年代学研究.岩石学报(06):1441-1456.
于津海,Y.S.O'Reilly,王丽娟,W.L.Griffin,蒋少涌,王汝成,徐夕生.2007.华夏地块古老物质的发现和前寒武纪地壳的形成.科学通报,52(01):1]-18.
于津海,王丽娟,魏震洋.2007.浙西南古元古代淡竹花岗岩的地球化学和锆石U-Pb-Hf同位素组成.2007年全国岩石学与地球动力学暨化学地球动力学研讨会论文摘要.武汉:中国地质大学出版社,128.
于津海,王丽娟,魏震洋,孙涛,舒良树.2007.华夏地块显生宙的变质作用期次和特征.高校地质学报,13(03):474-483.
于津海,周新民,Y.S.O'Reilly,赵蕾,W.L.Griffin,王汝成,王丽娟,陈小明.2005.南岭东段基底麻粒岩相变质岩的形成时代和原岩性质:锆石的U-Pb-Hf同位素研究.科学通报,50(16):1758-1767.
于津海,周新民,赵蕾,陈小明.2003.南岭东段麻粒岩相变质岩的发现及其地质意义.岩石学报,019(03):461-467.
于津海,魏震洋,王丽娟,舒良树,孙涛.2006.华夏地块:一个由古老物质组成的年轻陆块.高校地质学报(04):440-447.
俞受望,夏萍,邓铁殷,李强.1992.海南抱板地区中元古代花岗岩副矿物锆石的特征及U-Pb同位素年龄测定.地球化学,3:213-221.
翟明国.2009.华北克拉通两类早前寒武纪麻粒岩(HT-HP和HT-UHT)及其相关问题.岩石学报,25(08):1753-1771.
翟明国和刘文军.2001.麻粒岩的形成及其对大陆地壳演化的贡献.岩石学报,017(01):28-38.
翟明国,郭敬辉,阎月华,韩秀伶,李永刚.1992.中国华北太古宙高压基性麻粒岩的发现及初步研究.中国科学(B辑化学生命科学地学)(12):1325-1330.
张业明,付建明,赵子杰,徐安武,吴桂捷和曾波夫.1998.海南岛西部变基性火山岩的岩石特征及Sm-Nd同位素定年.矿物岩石(01).
张业明和彭松柏.2000.云开元古宙陆壳基底年代格架及华南前震旦纪构造演化初论.华南地质与矿产(01):1-10.
张业明,张仁杰.1999.琼中高级变质杂岩中单颗粒锆石Pb—Pb年龄及其….地球学报:中国地质科学院院报,20(003):284-288.
赵风清.1999.华夏地块前加里东期变质基底的年代构造格架.前寒武纪研究进展,22(02):39-46.
赵风清,金文山,甘晓春.1995.华夏地块前加里东期变质基底的特征以及深部地壳性质.地球学报,3:235-245.
赵风清,孙大中,张惠民,1995.华夏地块前加里东期变质基底形成的构造环境及地壳演化
赵国春,孙德有.1994.浙西南陈蔡群变质阶段划分及变质作用P—T—D轨迹研究[J].长春地质学院学报,24(03):246-253.
赵磊,周喜文.2012.浙西南八都群泥质麻粒岩的变质演化与PT轨迹.岩石矿物学杂志,31(01):6]-72.
曾雯,张利,周汉文,钟增球,向华,刘锐,靳松,吕新前,李春忠.2008.华夏地块古元古代基底的加里东期再造:锆石U-Pb年龄,Hf同位素和微量元素制约.科学通报,53(003):335-344.
周喜文,魏春景,耿元生,等.2004.胶北栖霞地区泥质高压麻粒岩的发现及其地质意义[J].科学通报,49(14):1424-1430.
周喜文,魏春景和耿元生.2007.胶北地块高压与低压泥质麻粒岩的相平衡关系与p-T演化轨迹.地学前缘,14(01):135-143.
周喜文,赵国春,耿元生.2010.贺兰山高压泥质麻粒岩——华北克拉通西部陆块拼合的岩石学证据.岩石学报,26(7):2113-2121.
周汉文,游振东,钟增球和韩郁菁.1994.云开隆起区钾长球斑片麻状黑云母花岗岩锆石特征研究——形貌、成分以及U-Pb同位素年龄.地球科学(04):427-432+554.
Ai Y. 1994. A revision of the garnet-clinopyroxene Fe2+-Mg exchange geothermometer. Contributions to Mineralogy and Petrology, 115(4): 467-473
Andersen T. 2002. Correction of common lead in U-Pb analysis that do not report 204Pb. Chemical Geology, 192:59-79.
Bernard E. Leake ARW, Charles E.S. Arps, William D. Brich. 1997. Nomenclature of amphiboles: report of the subcommittee on amphiboles of the International Mineralogical Association, Commission on New Minerals and Mineral Names. The Canadian Mineralogist, 35:219-246
Bhattacharyya C.1971. An evaluation of the chemical distinctions between igneous and metamorphic orthopyroxenes. Am. Mineral,56:499-506
Blundy JD and Holland TJB. 1990. Calcic amphibole equilibria and a new amphibole-plagioclase geothermometer. Contributions to Mineralogy and Petrology, 104(2): 208-224
BROWN M.1993. P-T-t evolution of orogenic belts and the causes of regional metamorphism. Journal of the Geological Society, 150(2):227-241.
Brown M.2009. Metamorphic patterns in orogenic systems and the geological record. Geological Society, London, Special Publications, 318(1):37-74.
Carter A, Roques D, Bristow C and Kinny P. 2001. Understanding Mesozoic accretion in Southeast Asia: significance of Triassic thermotectonism (Indosinian orogeny) in Vietnam. Geology, 29(3): 211,
Chen CH, Hsieh PS, Lee CY and Zhou HW. 2011. Two episodes of the Indosinian thermal event on the South China Block:Constraints from LA-ICPMS U-Pb zircon and electron microprobe monazite ages of the Darongshan S-type granitic suite. Gondwana Research,19(4): 1008-1023.
Deer WA, Howie RA and Zussman J,1997. Rock-forming minerals. 2nd Edition. Washington D.C. Geological Society Publishing House, 3-4
Deng P, Ren J, Ling H, Shen W, Sun L, Zhu B and Tan Z.2012. SHRIMP zircon U-Pb ages and tectonic implications for Indosinian granitoids of southern Zhuguangshan granitic composite, South China. Chinese Science Bulletin,57(13):1542-1552.
Ellis D and Green D. 1979. An experimental study of the effect of Ca upon garnet-clinopyroxene Fe-Mg exchange equilibria. Contributions to Mineralogy and Petrology, 71(1):13-22
Ernst W. 1988. Tectonic history of subduction zones inferred from retrograde blueschist PT paths. Geology, 16(12): 1081
Fletcher CJN, Chan LS and Sewell RJ.2004. Basement heterogeneity in the Cathaysia crustal block, southeast China CHRIS JN FLETCHER1, LUNG S. CHAN1, RODERICK J. SEWELL2, S. DIARMAD G. CAMPBELL2, DONALD W. DAVIS3 & JIESHOU ZHU4. Aspects of the tectonic evolution of China(226): 145.
Gerya T, Perchuk L, Triboulet C, Audren C and Sez'ko A. 1997. Petrology of the Tumanshet zonal metamorphic complex, Eastern Sayan. Petrology, 5(6): 503-533
Gilder SA, Gill J, Coe RS, Zhao X, Liu Z, Wang G, Yuan K, Liu W, Kuang G and Wu H.1996. Isotopic and paleomagnetic constraints on the Mesozoic tectonic evolution of south China. J. geophys. Res, 101(B7):16137.
Graham CM and Powell R. 1984. A garnet-hornblende geothermometer: calibration, testing, and application to the Pelona Schist, Southern California. Journal of Metamorphic Geology, 2(1): 13-31
Gupta S, Rodgers J, Hsu KJ, Shu S, Jiliang L, Haihong C, Haipo P and Sengor A. 1989. Comments and Reply on" Mesozoic overthrust tectonics in south China". Geology, 17(7):669-673.
Harley S. 1989. The origins of granulites: a metamorphic perspective. Geological Magazine, 126(03): 215-247.
Holdaway M.2000. Application of new experimental and garnet Margules data to the garnet-biotite geothermometer[J]. American Mineralogist, 85(7-8): 881-892.
Holdaway M.2001. Recalibration of the GASP geobarometer in light of recent garnet and plagioclase activity models and versions of the garnet-biotite geothermometer[J]. American Mineralogist, 86(10):1117-1129.
Holland T and Blundy J.1994. Non-ideal interactions in calcic amphiboles and their bearing on amphibole-plagioclase thermometry. Contributions to Mineralogy and Petrology, 116(4): 433-447
Hoskin PWO and Schaltegger U.2003. The composition of zircon and igneous and metamorphic petrogenesis. Reviews in Mineralogy and Geochemistry, 53(1):27-62
Hsu KJ, Li J, Chen H, Wang Q, Sun S and Sengor A.1990. Tectonics of South China: key to understanding West Pacific geology. Tectonophysics, 183(1-4):9-39.
K. Nandi. 1967. Garnets as indices of progressive regional metamorphism[J]. Mineral Mag., 36, London, 83-93.
Kohn MJ and Spear FS.1990. Two new geobarometers for garnet amphibolites, with applications to southeastern Vermont. American Mineralogist, 75(1-2): 89
Krogh EJ.1988. The garnet-clinopyroxene Fe-Mg geothermometer—a reinterpretation of existing experimental data. Contributions to Mineralogy and Petrology, 99(1):44-48
Li L-M, Sun M, Wang Y, Xing G, Zhao G, Cai K and Zhang Y. 2011a. Geochronological and Geochemical study of Palaeoproterozoic gneissic granites and clinopyroxenite xenoliths from NW Fujian, SE China: Implications for the crustal evolution of the Cathaysia Block. Journal of Asian Earth Sciences,41(2):204-212.
Li L-M, Sun M, Wang Y, Xing G, Zhao G, Lin S, Xia X, Chan L, Zhang F and Wong J. 2011b. U-Pb and Hf isotopic study of zircons from migmatised amphibolites in the Cathaysia Block: Implications for the early Paleozoic peak tectonothermal event in Southeastern China. Gondwana Research, 19(1): 191-201.
Li S, Xiao Y, Liou D, Chen Y, Ge N, Zhang Z, Sun S, Cong B, Zhang R and Hart SR. 1993. Collision of the North China and Yangtse Blocks and formation of coesite-bearing eclogites: timing and processes. Chemical Geology, 109(1-4):89-111.
Li WY, Ma CQ, Liu YY and Robinson PT. 2012. Discovery of the Indosinian aluminum A-type granite in Zhejiang Province and its geological significance. Science China Earth Sciences, 55(1):13-25.
Li X-H, Li Z-X, He B, Li W-X, Li Q-L, Gao Y and Wang X-C.2011c. The Early Permian active continental margin and crustal growth of the Cathaysia Block:In situ U-Pb, Lu-Hf and O isotope analyses of detrital zircons. Chemical Geology.
Li XH, Li ZX, Li WX and Wang Y. 2006. Initiation of the Indosinian orogeny in South China: Evidence for a Permian magmatic arc on Hainan Island. The Journal of Geology, 114(3): 341-353.
Li ZX, Li X, Zhou H and Kinny PD. 2002. Grenvillian continental collision in south China: New SHRIMP U-Pb zircon results and implications for the configuration of Rodinia. Geology, 30(2): 163.
Li ZX, Li XH, Wartho JA, Clark C, Li WX, Zhang CL and Bao C. 2009. Magmatic and metamorphic events during the early Paleozoic Wuyi-Yunkai orogeny, southeastern South China: New age constraints and pressure-temperature conditions. Geological Society of America Bulletin, 122(5-6): 772-793.
Liu R, Zhou H, Zhang L, Zhong Z, Zeng W, Xiang H, Jin S, Lu X and Li C.2010. Zircon U-Pb ages and Hf isotope compositions of the Mayuan migmatite complex, NW Fujian Province, Southeast China: Constraints on the timing and nature of a regional tectonothermal event associated with the Caledonian orogeny. Lithos, 119(3-4):163-180.
Nakano N, Osanai Y, Minh NT, Miyamoto T, Hayasaka Y and Owada M.2008. Discovery of high-pressure granulite-facies metamorphism in northern Vietnam:Constraints on the Permo-Triassic Indochinese continental collision tectonics. Comptes Rendus Geoscience, 340(2-3):127-138.
Nam TN, Sano Y, Terada K, Toriumi M, Van Quynh P and Dung LT. 2001. First SHRIMP U-Pb zircon dating of granulites from the Kontum massif (Vietnam) and tectonothermal implications. Journal of Asian Earth Sciences,19(1-2):77-84.
Nesbitt H and Young G. 1982. Early Proterozoic climates and plate motions inferred from major element chemistry of lutites. Nature, 299(5885): 715-717.
Newton R and Perkins D. 1982. Thermodynamic calibration of geobarometers based on the assemblages garnet-plagioclase-orthopyroxene (clinopyroxene)-quartz. American Mineralogist, 67(3-4): 203-222
O'Brien P and ROTZLER J. 2003. High-pressure granulites: formation, recovery of peak conditions and implications for tectonics. Journal of Metamorphic Geology, 21(1):3-20
POWELL R. 1985. Regression diagnostics and robust regression in geothermometer/geobarometer calibration:the garnet - clinopyroxene geothermometer revisited. Journal of Metamorphic Geology, 3(3): 231-243
Ravna EK.2000a. Distribution of Fe2+ and Mg between coexisting garnet and hornblende in synthetic and natural systems: an empirical calibration of the garnet-hornblende Fe-Mg geothermometer. Lithos, 53(3-4):265-277
Ravna K. 2000b. The garnet-clinopyroxene Fe2+-Mg geothermometer: an updated calibration. Journal of Metamorphic Geology, 18(2): 211-219.
Rietmeijer FJM.1983. Chemical distinction between igneous and metamorphic orthopyroxenes especially those coexisting with Ca-rich clinopyroxenes: a re-evaluation. Mineral. Mag, 47: 143-151
Roger F, Maluski H, Leyreloup A, Lepvrier C and Truong Thi P. 2007. U-Pb dating of high temperature metamorphic episodes in the Kon Tum Massif (Vietnam). Journal of Asian Earth Sciences, 30(3): 565-572.
Rogers JJW and Santosh M.2002a. Configuration of Columbia, a Mesoproterozoic supercontinent. Gondwana Research,5(1):5-22.
Rogers JJW and Santosh M. 2002b. Mesoproterozoic Supercontinent: Introduction. Gondwana Research, 5(1):3-4.
Rowley DB, Ziegler AM, Gyou N, Hsu KJ, Shu S, Jiliang L, Haihong C, Haipo P and Sengor A.1989. Comment and Reply on" Mesozoic overthrust tectonics in south China". Geology, 17(4): 384-387.
Shaw DM.1972. The origin of the Apsley gneiss, Ontario. Canadian Journal of Earth Sciences, 9(1):18-35.
Shu L-S, Faure M, Yu J-H and Jahn B-M.2011. Geochronological and geochemical features of the Cathaysia block (South China): New evidence for the Neoproterozoic breakup of Rodinia. Precambrian Research,187(3-4):263-276.
Salje E. 1986. Heat capacities and entropies of andalusite and sillimanite; the influence of fibrolitization on the phase diagram of the Al2SiO5 polymorphs. American Mineralogist, 71(11-12): 1366
Song S, Niu Y, Wei C, Ji J and Su L. 2010. Metamorphism, anatexis, zircon ages and tectonic evolution of the Gongshan block in the northern Indochina continent—An eastern extension of the Lhasa Block. Lithos,120(3-4):327-346.
Spear FS and Florence FP. 1992. Thermobarometry in granulites: pitfalls and new approaches. Precambrian Research,55(1-4):209-241
Spear FS, Kohn MJ and Cheney JT. 1999. P-T paths from anatectic pelites[J]. Contributions to Mineralogy and Petrology, 134(1):17-32.
Wan Y, Liu D, Xu M, Zhuang J, Song B, Shi Y and Du L. 2007. SHRIMP U-Pb zircon geochronology and geochemistry of metavolcanic and metasedimentary rocks in Northwestern Fujian, Cathaysia block, China: Tectonic implications and the need to redefine lithostratigraphic units. Gondwana Research, 12(1-2):166-183.
Wang Y, Fan W, Zhao G, Ji S and Peng T. 2007. Zircon U-Pb geochronology of gneissic rocks in the Yunkai massif and its implications on the Caledonian event in the South China Block. Gondwana Research, 12(4):404-416.
Wells PRA.1977. Pyroxene thermometry in simple and complex systems. Contributions to Mineralogy and Petrology, 62(2): 129-139
Winchester J and Floyd P. 1977. Geochemical discrimination of different magma series and their differentiation products using immobile elements. Chemical Geology, 20:325-343
Wu J, Liang H, Huang W, Wang C, Sun W, Sun Y, Li J, Mo J and Wang X.2012. Indosinian isotope ages of plutons and deposits in southwestern Miaoershan-Yuechengling, northeastern Guangxi and implications on Indosinian mineralization in South China. Chinese Science Bulletin, 57(9): 1024-1035.
Wu R, Zheng Y, Wu Y, Zhao Z, Zhang S, Liu X and Wu F.2006. Reworking of juvenile crust: Element and isotope evidence from Neoproterozoic granodiorite in South China. Precambrian Research, 146(3-4):179-212.
Xu X.2005. Relict Proterozoic basement in the Nanling Mountains (SE China) and its tectonothermal overprinting. Tectonics, 24(2).
Xu X, O'Reilly SY, Griffin WL, Wang X, Pearson NJ and He Z. 2007. The crust of Cathaysia: Age, assembly and reworking of two terranes. Precambrian Research, 158(1-2): 51-78.
Yao J, Shu L and Santosh M.2011. Detrital zircon U-Pb geochronology, Hf-isotopes and geochemistry—New clues for the Precambrian crustal evolution of Cathaysia Block, South China. Gondwana Research,20(2-3):553-567.
Yu JH, Zhou XM, Y.S.O'Reilly, et al.2005. Zircon U-Pb-Hf isotopic research on the formation time of the basement granulite facies metamorphic rocks and the characteristics of their protolith in the eastern Nanling[J]. Chinese Science Bulletin, 50(16):1758-1767.
Yu J, O'Reilly S, Wang L, Griffin W, Zhang M, Wang R, Jiang S and Shu L. 2008. Where was South China in the Rodinia supercontinent?::Evidence from U-Pb geochronology and Hf isotopes of detrital zircons. Precambrian Research,164(1-2):1-15.
Yu J, O'Reilly YS, Wang L, Griffin WL, Jiang S, Wang R and Xu X. 2007a. Finding of ancient materials in Cathaysia and implication for the formation of Precambrian crust. Chinese Science Bulletin, 52(1): 13-22.
Yu J, Wang L, O'Reilly SY, Shu L and Sun T. 2009a. Paleoproterozoic basement beneath the southern Jiangxi Province: Evidence from U-Pb ages and Lu-Hf isotopes in zircons from the Doushui lamprophyre. Chinese Science Bulletin, 54(9): 1555-1563.
Yu JH, O'Reilly SY, Zhao L, Griffin WL, Zhang M, Zhou X, Jiang SY, Wang LJ and Wang RC.2007b. Origin and evolution of topaz-bearing granites from the Nanling Range, South China: a geochemical and Sr-Nd-Hf isotopic study. Mineralogy and Petrology, 90(3-4): 271-300.
Yu JH, Wang L, O'Reilly S, Griffin W, Zhang M, Li C and Shu L.2009b. A Paleoproterozoic orogeny recorded in a long-lived cratonic remnant (Wuyishan terrane), eastern Cathaysia Block, China. Precambrian Research,174(3-4):347-363.
Yu J-H, O'Reilly SY, Zhou M-F, Griffin WL and Wang L. 2011. U-Pb geochronology and Hf-Nd isotopic geochemistry of the Badu Complex, Southeastern China: Implications for the Precambrian crustal evolution and paleogeography of the Cathaysia Block. Precambrian Research
Yu X, Hou M and Wang D. 2005. No evidence for a large Mesozoic overthrust in the Lantian area of Anhui Province, south China. Journal of Asian Earth Sciences,25(4):601-609.
Zhang Y, Shu L and Chen X.2011. Geochemistry, geochronology, and petro-genesis of the early Paleozoic granitic plutons in the central-southern Jiangxi Province, China. Science China Earth Sciences, 54(10):1492-1510.
Zhao G, Wilde SA, Cawood PA and Lu L. 1998. Thermal evolution of Archean basement rocks from the eastern part of the North China Craton and its bearing on tectonic setting. International Geology Review, 40(8):706-721.
Zhao G and Cawood P. 1999. Tectonothermal evolution of the Mayuan Assemblage in the Cathaysia Block; implications for Neoproterozoic collision-related assembly of the South China Craton. American Journal of Science,299(4):309-339.
Zhao G, Cawood PA, Wilde SA and Lu L. 2001. High-pressure granulites (retrograded eclogites) from the Hengshan Complex, North China Craton:petrology and tectonic implications. Journal of Petrology, 42(6):1141.
Zhao G, Cawood PA, Wilde SA and Sun M.2002. Review of global 2.1-1.8 Ga orogens: implications for a pre-Rodinia supercontinent. Earth-Science Reviews, 59(1-4): 125-162.
Zhao G, Sun M, Wilde SA and Li S.2003. Assembly, accretion and breakup of the Paleo-Mesoproterozoic Columbia supercontinent: records in the North China Craton. Gondwana Research, 6(3): 417-434.
Zhao G, Sun M, Wilde SA and Li S. 2004. A Paleo-Mesoproterozoic supercontinent: assembly, growth and breakup. Earth-Science Reviews, 67(1-2):91-123.
Zhao G, Sun M, Wilde SA and Sanzhong L. 2005. Late Archean to Paleoproterozoic evolution of the North China Craton: key issues revisited. Precambrian Research, 136(2): 177-202.
Zhao L, Guo F, Fan W, Li C, Qin X and Li H. 2010. Crustal evolution of the Shiwandashan area in South China: Zircon U-Pb-Hf isotopic records from granulite enclaves in Indo-Sinian granites. Chinese Science Bulletin,55(19):2028-2038.
Zheng JP, Griffin WL, Li LS, O'Reilly SY, Pearson NJ, Tang HY, Liu GL, Zhao JH, Yu CM and Su YP. 2011. Highly evolved Archean basement beneath the western Cathaysia Block, South China. Geochimica et Cosmochimica Acta,75(1):242-255.
Zhou XW, Wei CJ, Geng YS, et al.2004. Discovery and implications of the high-pressure pelitic granulite from the Qixia region in Jiaobei massif[J]. Chinese Science Bulletin,49(14):1424-1430.
陈迪云,徐伟昌.1993.浙江陈蔡群变质岩变质条件及构造环境的地球化学探讨[J].矿物岩石,(02):29-36.
陈惠芳.1991.海南岛前寒武纪结晶基底和科马提岩的发现.大地构造与成矿学(01):62.
丁式江.1995.琼西戈枕侵入体的地质特征及其发现意义.大地构造与成矿学,19(4):336-343.
丁式江,胡健民,宋彪,陈沐龙,谢盛周和范渊.2005.海南岛抱板群内顺层侵位深熔花岗岩钻石U-Pb定年及其构造意义.中国科学(D辑:地球科学)(10):33-44.
丁兴,周新民,孙涛.2005.华南陆壳基底的幕式生长——来自广东古寨花岗闪长岩中锆石LA-ICPMS定年的信息.地质论评,51(04):382-392.
杜杨松,Collerson K D.,赵建新,等.1999.两广交界地区S型花岗岩中麻粒岩包体的特征和成因[J].岩石学报,15(2):303-314.
付建明.1996.海南岛加里东期花岗岩的发现.中国区域地质(02):175.
付树超,陈觉民,林文生.1991.福建建宁西部上太古界天井坪组(Ar2t)地质特征.福建地质(02):103-113
甘晓春,李惠民,孙大中.1993.闽北前寒武纪基底的地质年代学研究[J].福建地质,12(01):17-32.
甘晓春,季惠民,孙大中,金文山,赵凤清.1995.浙西南早元古代花岗质岩石的年代.岩石矿物学杂志,14(01):1-8.
葛小月,2003.海南岛中生代岩浆作用及其构造意义.博士Thesis,中国科学院研究生院(广州地球化学研究所)
郭福祥.1997.华南地区不存在印支碰撞造山带.贵州地质(02):173.
侯威,陈惠芳,梁新权和王可伏.1992.海南岛前寒武纪地层的确定其大地构造演化.长春地质学院学报(02):136-143.
胡雄健.1994.浙西南下元古界八都群的地质年代学.地球化学,23(S1):18-24.
胡雄健,许金坤和童朝旭.1991.浙西南前寒武纪地质.北京:地质出版杜:1—278.
胡雄健,许金坤,陈程华,李春忠,李惠民.1992.浙西南早元古代花岗岩、伟晶岩的单颗粒锆石U-Pb年龄.科学通报(11):1016-1018.
靳新娣,朱和平.2000.岩石样品中43种元素的高分辨等离子质谱测定.分析化学(05):563-567.
靳是琴,李鸿超.1984.成因矿物学概论.长春:吉林大学出版社
金文山和孙大中,1997.华南大陆深部地壳结构及其演化.地质出版社
孔祥生,李东正,冯长根,1995.浙江省陈蔡地区前寒武纪地质.地质出版社,北京
兰玉琦,叶瑛,兰翔,等.1995.浙江陈蔡群孔兹岩系的变质地质学研究[J].浙江大学学报,29(3):303-309.
劳秋元,施央申,卢华复和马瑞士.1994.东海的构造地层地体.现代地质学研究文集(下),南京:南京大学出版社:81-91.
李继亮,孙枢,许靖华,陈海泓,彭海波,王清晨.1989.南华夏造山带构造演化的新证据.地质科学(03):217-225.
李兼海,王国平,郑铁藩,梁诗经,李超岭,1997.福建省岩石地层.地质大学出版社:1-216
李曙光,陈移之,葛宁洁,胡雄健,刘德良.1996.浙西南八都群变火山岩系及变晶糜棱岩的同位素年龄及其构造意义.岩石学报,12(01):79-87.
李献华.1990.万洋山—诸广山花岗岩复式岩基的岩浆活动时代与地壳运动.中国科学:B辑(007):747-755.
李献华,周汉文,丁式江,李寄喁,张仁杰,张业明和葛文春.2000.海南岛“邦溪-晨星蛇绿岩片”的时代及其构造意义——Sm-Nd同位素制约.岩石学报(03):425-432.
李献华,王一先,赵振华,陈多福,张宏.1998.闽浙古元古代斜长角闪岩的离子探针锆石U-Pb年代学.地球化学,27(04):327-334.
梁新权.1995.海南岛前寒武纪花岗岩-绿岩系Sm-Nd同位素年龄及其地质意义.岩石学报(01).
梁新权,范蔚茗和许德如.2000.海南岛屯昌玄武质科马提岩Sm-Nd同位素年龄及其地质意义.地质科学(02):240-244.
林庆华,李立源和梁明国.1990.粤西合水、思贺地区花岗质岩石的成因.中国区域地质(02):173-180.
刘平华,刘福来,王舫,刘建辉.2010.山东半岛基型高压麻粒岩的成因矿物学及变质演化.岩石学报,07(026):2039-2056.
刘邦秀,刘春根和邱永泉.2001.江西南部鹤仔片麻状花岗岩类Pb-Pb同位素年龄及地质意义.火山地质与矿产(04):264-268.
刘福来,施建荣,刘建辉,叶建国,刘平华和王舫.2011.北苏鲁威海地区超基性岩的原岩形成时代和超高压变质时代.岩石学报(04):1075-1084.
刘福来,叶建国和薛怀民.2006.北苏鲁超高压变质岩锆石中的矿物包体.地质学报(12):1817-1830.
刘锐,2009.华夏地块前海西期地壳深熔作用——以浙闽地区为例.博士Thesis,中国地质大学
刘锐,周汉文,张利,钟增球,曾雯,向华,靳松,吕新前,李春忠.2009.华夏地块古元古代陆壳冉造:锆石微量元素与U-Pb和Lu-Hf同位素证据.科学通报,54(7):906-917.
卢华复.2006.关于华夏古陆.高校地质学报(04):413-417.
卢良兆,徐学纯,刘福来.1996.中国北方早前寒武纪孔兹岩系.长春:长春出版社,1-277
马大铨,黄香定,陈哲培,肖志发,张旺驰和钟盛中.1997.海南省抱板群研究的新进展.中国区域地 质(02).
马瑞士.2006.华南构造演化新思考兼论“华夏古陆”说中的几个问题.高校地质学报,12(04):448-456.
彭松柏,金振民,付建明,等.2004.紫苏花岗岩成因及构造意义[J].华南地质与矿产,(04):63-70.
彭松柏,付建明和刘云华.2004a.大容山-十万大山花岗岩带中A型紫苏花岗岩、麻粒岩包体的发现及意义.科学技术与工程(10):832-834.
彭松柏,金振民,付建明,何龙清,蔡明海和刘云华.2004b.粤西新元古代蛇绿岩的发现及其地质意义.科学技术与工程(12):1006-1012.
彭松柏,金振民,付建明,刘云华,何龙清,蔡明海和王彦斌.2005.云开造山带条带-眼球状(环斑)强过铝花岗岩的岩石地球化学、年代及成因.科学技术与工程(17):1238-1246.
彭松柏和张业明.1999.云开隆起区花岗质岩石同位素定年及其构造意义.地质科技情报(02):15.
覃小锋,潘元明,李江,李容森,周府生,胡贵昂和钟锋运.2006.桂东南云开地区变质杂岩锆石SHRIMP U-Pb年代学.地质通报(05):553-559.
沈渭洲.2006.华夏地块基底变质岩同位素年龄数据评述.高校地质学报(04):475-482.
舒良树.2006.华南前泥盆纪构造演化:从华夏地块到加里东期造山带.高校地质学报,12(004):418-431.
宋彪,张玉海和刘敦一.2002.微量原位分析仪器SHRIMP的产生与锆石同位素地质年代学.质谱学报(01):58-62.
王可伏,范蔚茗,侯威,陈惠芳和梁新权.1992.海南岛土外山古元古代玄武岩成因探讨.地质地球化学(06):72-73+15.
王可伏,范蔚茗,侯威,陈惠芳,梁新权.1994.海南岛土外山早元古代玄武岩的成因—主要元素、微量元素和Sm—Nd同位素证据.地质与勘探(04):30-36.
王丽娟,于津海,孙涛,魏震洋.2007.华夏地块南部可能存在Grenville期造山作用:来自基底变质岩中锆石U-Pb定年信息.全国岩石学与地球动力学暨化学地球动力学研讨会,武汉.
汪新.1988.浙闽板块碰撞造山带研究.南京大学.
王孝磊,周金城,邱检生,张文兰,柳小明和张桂林.2006.桂北新元古代强过铝花岗岩的成因:锆石年代学和Hf同位素制约.岩石学报(02):326-342.
王孝磊,舒徐洁,邢光福,谢思文,张春晖和夏晗.2012.浙江诸暨地区石角-璜山侵入岩LA-ICP-MS锆石U-Pb年龄——对超镁铁质球状岩成因的启示.地质通报(01):75-81.
王银喜,杨杰东,郭令智,等.1992.浙江龙泉早元古代花岗岩的发现及基底时代的讨论[J].地质评论,(06):525-531.
魏春景.2011.变质作用p-T-t轨迹的研究方法与进展.地学前缘(02):1-16.
吴富江和张芳荣.2003.华南板块北缘东段武功山加里东期花岗岩特征及成因探讨.中国地质(02):166-172.
向华,张利,周汉文,钟增球,曾雯,刘锐,靳松.2008.浙西南变质基底基性-超基性变质岩锆石 U-Pb年龄、Hf同位素研究:华夏地块变质基底对华南印支期造山的响应.中国科学(D辑:地球科学)(04):401-413.
许靖华.1987.中国南方大地构造的几个问题.地质科技情报(02):13-27.
许靖华,孙枢,李继亮.1987.是华南造山带而不是华南地台.中国科学(B辑化学生物学农学医学地学)(10):1107-1115.
许德如,夏斌,李鹏春,张玉泉,陈广浩和马驰.2006.海南岛北西部前寒武纪花岗质岩SHRIMP锆石U-Pb年龄及地质意义.大地构造与成矿学(04):510-518.
徐先兵,张岳桥,舒良树,贾东,王瑞瑞和许怀钾.2010.武夷山地区前寒武纪地层沉积时代研究.地层学杂志(03):254-267.
杨杰东,徐士进,王银喜,等.1994.浙江龙泉八都群斜长角闪岩的Sm-Nd和Rb-Sr年龄测定及其意义[J].地球化学,23(S1):25-31.
于津海,王丽娟,王孝磊,邱检生和赵蕾.2007.赣东南富城杂岩体的地球化学和年代学研究.岩石学报(06):1441-1456.
于津海,Y.S.O'Reilly,王丽娟,W.L.Griffin,蒋少涌,王汝成,徐夕生.2007.华夏地块古老物质的发现和前寒武纪地壳的形成.科学通报,52(01):1]-18.
于津海,王丽娟,魏震洋.2007.浙西南古元古代淡竹花岗岩的地球化学和锆石U-Pb-Hf同位素组成.2007年全国岩石学与地球动力学暨化学地球动力学研讨会论文摘要.武汉:中国地质大学出版社,128.
于津海,王丽娟,魏震洋,孙涛,舒良树.2007.华夏地块显生宙的变质作用期次和特征.高校地质学报,13(03):474-483.
于津海,周新民,Y.S.O'Reilly,赵蕾,W.L.Griffin,王汝成,王丽娟,陈小明.2005.南岭东段基底麻粒岩相变质岩的形成时代和原岩性质:锆石的U-Pb-Hf同位素研究.科学通报,50(16):1758-1767.
于津海,周新民,赵蕾,陈小明.2003.南岭东段麻粒岩相变质岩的发现及其地质意义.岩石学报,019(03):461-467.
于津海,魏震洋,王丽娟,舒良树,孙涛.2006.华夏地块:一个由古老物质组成的年轻陆块.高校地质学报(04):440-447.
俞受望,夏萍,邓铁殷,李强.1992.海南抱板地区中元古代花岗岩副矿物锆石的特征及U-Pb同位素年龄测定.地球化学,3:213-221.
翟明国.2009.华北克拉通两类早前寒武纪麻粒岩(HT-HP和HT-UHT)及其相关问题.岩石学报,25(08):1753-1771.
翟明国和刘文军.2001.麻粒岩的形成及其对大陆地壳演化的贡献.岩石学报,017(01):28-38.
翟明国,郭敬辉,阎月华,韩秀伶,李永刚.1992.中国华北太古宙高压基性麻粒岩的发现及初步研究.中国科学(B辑化学生命科学地学)(12):1325-1330.
张业明,付建明,赵子杰,徐安武,吴桂捷和曾波夫.1998.海南岛西部变基性火山岩的岩石特征及Sm-Nd同位素定年.矿物岩石(01).
张业明和彭松柏.2000.云开元古宙陆壳基底年代格架及华南前震旦纪构造演化初论.华南地质与矿产(01):1-10.
张业明,张仁杰.1999.琼中高级变质杂岩中单颗粒锆石Pb—Pb年龄及其….地球学报:中国地质科学院院报,20(003):284-288.
赵风清.1999.华夏地块前加里东期变质基底的年代构造格架.前寒武纪研究进展,22(02):39-46.
赵风清,金文山,甘晓春.1995.华夏地块前加里东期变质基底的特征以及深部地壳性质.地球学报,3:235-245.
赵风清,孙大中,张惠民,1995.华夏地块前加里东期变质基底形成的构造环境及地壳演化
赵国春,孙德有.1994.浙西南陈蔡群变质阶段划分及变质作用P—T—D轨迹研究[J].长春地质学院学报,24(03):246-253.
赵磊,周喜文.2012.浙西南八都群泥质麻粒岩的变质演化与PT轨迹.岩石矿物学杂志,31(01):6]-72.
曾雯,张利,周汉文,钟增球,向华,刘锐,靳松,吕新前,李春忠.2008.华夏地块古元古代基底的加里东期再造:锆石U-Pb年龄,Hf同位素和微量元素制约.科学通报,53(003):335-344.
周喜文,魏春景,耿元生,等.2004.胶北栖霞地区泥质高压麻粒岩的发现及其地质意义[J].科学通报,49(14):1424-1430.
周喜文,魏春景和耿元生.2007.胶北地块高压与低压泥质麻粒岩的相平衡关系与p-T演化轨迹.地学前缘,14(01):135-143.
周喜文,赵国春,耿元生.2010.贺兰山高压泥质麻粒岩——华北克拉通西部陆块拼合的岩石学证据.岩石学报,26(7):2113-2121.
周汉文,游振东,钟增球和韩郁菁.1994.云开隆起区钾长球斑片麻状黑云母花岗岩锆石特征研究——形貌、成分以及U-Pb同位素年龄.地球科学(04):427-432+554.
Ai Y. 1994. A revision of the garnet-clinopyroxene Fe2+-Mg exchange geothermometer. Contributions to Mineralogy and Petrology, 115(4): 467-473
Andersen T. 2002. Correction of common lead in U-Pb analysis that do not report 204Pb. Chemical Geology, 192:59-79.
Bernard E. Leake ARW, Charles E.S. Arps, William D. Brich. 1997. Nomenclature of amphiboles: report of the subcommittee on amphiboles of the International Mineralogical Association, Commission on New Minerals and Mineral Names. The Canadian Mineralogist, 35:219-246
Bhattacharyya C.1971. An evaluation of the chemical distinctions between igneous and metamorphic orthopyroxenes. Am. Mineral,56:499-506
Blundy JD and Holland TJB. 1990. Calcic amphibole equilibria and a new amphibole-plagioclase geothermometer. Contributions to Mineralogy and Petrology, 104(2): 208-224
BROWN M.1993. P-T-t evolution of orogenic belts and the causes of regional metamorphism. Journal of the Geological Society, 150(2):227-241.
Brown M.2009. Metamorphic patterns in orogenic systems and the geological record. Geological Society, London, Special Publications, 318(1):37-74.
Carter A, Roques D, Bristow C and Kinny P. 2001. Understanding Mesozoic accretion in Southeast Asia: significance of Triassic thermotectonism (Indosinian orogeny) in Vietnam. Geology, 29(3): 211,
Chen CH, Hsieh PS, Lee CY and Zhou HW. 2011. Two episodes of the Indosinian thermal event on the South China Block:Constraints from LA-ICPMS U-Pb zircon and electron microprobe monazite ages of the Darongshan S-type granitic suite. Gondwana Research,19(4): 1008-1023.
Deer WA, Howie RA and Zussman J,1997. Rock-forming minerals. 2nd Edition. Washington D.C. Geological Society Publishing House, 3-4
Deng P, Ren J, Ling H, Shen W, Sun L, Zhu B and Tan Z.2012. SHRIMP zircon U-Pb ages and tectonic implications for Indosinian granitoids of southern Zhuguangshan granitic composite, South China. Chinese Science Bulletin,57(13):1542-1552.
Ellis D and Green D. 1979. An experimental study of the effect of Ca upon garnet-clinopyroxene Fe-Mg exchange equilibria. Contributions to Mineralogy and Petrology, 71(1):13-22
Ernst W. 1988. Tectonic history of subduction zones inferred from retrograde blueschist PT paths. Geology, 16(12): 1081
Fletcher CJN, Chan LS and Sewell RJ.2004. Basement heterogeneity in the Cathaysia crustal block, southeast China CHRIS JN FLETCHER1, LUNG S. CHAN1, RODERICK J. SEWELL2, S. DIARMAD G. CAMPBELL2, DONALD W. DAVIS3 & JIESHOU ZHU4. Aspects of the tectonic evolution of China(226): 145.
Gerya T, Perchuk L, Triboulet C, Audren C and Sez'ko A. 1997. Petrology of the Tumanshet zonal metamorphic complex, Eastern Sayan. Petrology, 5(6): 503-533
Gilder SA, Gill J, Coe RS, Zhao X, Liu Z, Wang G, Yuan K, Liu W, Kuang G and Wu H.1996. Isotopic and paleomagnetic constraints on the Mesozoic tectonic evolution of south China. J. geophys. Res, 101(B7):16137.
Graham CM and Powell R. 1984. A garnet-hornblende geothermometer: calibration, testing, and application to the Pelona Schist, Southern California. Journal of Metamorphic Geology, 2(1): 13-31
Gupta S, Rodgers J, Hsu KJ, Shu S, Jiliang L, Haihong C, Haipo P and Sengor A. 1989. Comments and Reply on" Mesozoic overthrust tectonics in south China". Geology, 17(7):669-673.
Harley S. 1989. The origins of granulites: a metamorphic perspective. Geological Magazine, 126(03): 215-247.
Holdaway M.2000. Application of new experimental and garnet Margules data to the garnet-biotite geothermometer[J]. American Mineralogist, 85(7-8): 881-892.
Holdaway M.2001. Recalibration of the GASP geobarometer in light of recent garnet and plagioclase activity models and versions of the garnet-biotite geothermometer[J]. American Mineralogist, 86(10):1117-1129.
Holland T and Blundy J.1994. Non-ideal interactions in calcic amphiboles and their bearing on amphibole-plagioclase thermometry. Contributions to Mineralogy and Petrology, 116(4): 433-447
Hoskin PWO and Schaltegger U.2003. The composition of zircon and igneous and metamorphic petrogenesis. Reviews in Mineralogy and Geochemistry, 53(1):27-62
Hsu KJ, Li J, Chen H, Wang Q, Sun S and Sengor A.1990. Tectonics of South China: key to understanding West Pacific geology. Tectonophysics, 183(1-4):9-39.
K. Nandi. 1967. Garnets as indices of progressive regional metamorphism[J]. Mineral Mag., 36, London, 83-93.
Kohn MJ and Spear FS.1990. Two new geobarometers for garnet amphibolites, with applications to southeastern Vermont. American Mineralogist, 75(1-2): 89
Krogh EJ.1988. The garnet-clinopyroxene Fe-Mg geothermometer—a reinterpretation of existing experimental data. Contributions to Mineralogy and Petrology, 99(1):44-48
Li L-M, Sun M, Wang Y, Xing G, Zhao G, Cai K and Zhang Y. 2011a. Geochronological and Geochemical study of Palaeoproterozoic gneissic granites and clinopyroxenite xenoliths from NW Fujian, SE China: Implications for the crustal evolution of the Cathaysia Block. Journal of Asian Earth Sciences,41(2):204-212.
Li L-M, Sun M, Wang Y, Xing G, Zhao G, Lin S, Xia X, Chan L, Zhang F and Wong J. 2011b. U-Pb and Hf isotopic study of zircons from migmatised amphibolites in the Cathaysia Block: Implications for the early Paleozoic peak tectonothermal event in Southeastern China. Gondwana Research, 19(1): 191-201.
Li S, Xiao Y, Liou D, Chen Y, Ge N, Zhang Z, Sun S, Cong B, Zhang R and Hart SR. 1993. Collision of the North China and Yangtse Blocks and formation of coesite-bearing eclogites: timing and processes. Chemical Geology, 109(1-4):89-111.
Li WY, Ma CQ, Liu YY and Robinson PT. 2012. Discovery of the Indosinian aluminum A-type granite in Zhejiang Province and its geological significance. Science China Earth Sciences, 55(1):13-25.
Li X-H, Li Z-X, He B, Li W-X, Li Q-L, Gao Y and Wang X-C.2011c. The Early Permian active continental margin and crustal growth of the Cathaysia Block:In situ U-Pb, Lu-Hf and O isotope analyses of detrital zircons. Chemical Geology.
Li XH, Li ZX, Li WX and Wang Y. 2006. Initiation of the Indosinian orogeny in South China: Evidence for a Permian magmatic arc on Hainan Island. The Journal of Geology, 114(3): 341-353.
Li ZX, Li X, Zhou H and Kinny PD. 2002. Grenvillian continental collision in south China: New SHRIMP U-Pb zircon results and implications for the configuration of Rodinia. Geology, 30(2): 163.
Li ZX, Li XH, Wartho JA, Clark C, Li WX, Zhang CL and Bao C. 2009. Magmatic and metamorphic events during the early Paleozoic Wuyi-Yunkai orogeny, southeastern South China: New age constraints and pressure-temperature conditions. Geological Society of America Bulletin, 122(5-6): 772-793.
Liu R, Zhou H, Zhang L, Zhong Z, Zeng W, Xiang H, Jin S, Lu X and Li C.2010. Zircon U-Pb ages and Hf isotope compositions of the Mayuan migmatite complex, NW Fujian Province, Southeast China: Constraints on the timing and nature of a regional tectonothermal event associated with the Caledonian orogeny. Lithos, 119(3-4):163-180.
Nakano N, Osanai Y, Minh NT, Miyamoto T, Hayasaka Y and Owada M.2008. Discovery of high-pressure granulite-facies metamorphism in northern Vietnam:Constraints on the Permo-Triassic Indochinese continental collision tectonics. Comptes Rendus Geoscience, 340(2-3):127-138.
Nam TN, Sano Y, Terada K, Toriumi M, Van Quynh P and Dung LT. 2001. First SHRIMP U-Pb zircon dating of granulites from the Kontum massif (Vietnam) and tectonothermal implications. Journal of Asian Earth Sciences,19(1-2):77-84.
Nesbitt H and Young G. 1982. Early Proterozoic climates and plate motions inferred from major element chemistry of lutites. Nature, 299(5885): 715-717.
Newton R and Perkins D. 1982. Thermodynamic calibration of geobarometers based on the assemblages garnet-plagioclase-orthopyroxene (clinopyroxene)-quartz. American Mineralogist, 67(3-4): 203-222
O'Brien P and ROTZLER J. 2003. High-pressure granulites: formation, recovery of peak conditions and implications for tectonics. Journal of Metamorphic Geology, 21(1):3-20
POWELL R. 1985. Regression diagnostics and robust regression in geothermometer/geobarometer calibration:the garnet - clinopyroxene geothermometer revisited. Journal of Metamorphic Geology, 3(3): 231-243
Ravna EK.2000a. Distribution of Fe2+ and Mg between coexisting garnet and hornblende in synthetic and natural systems: an empirical calibration of the garnet-hornblende Fe-Mg geothermometer. Lithos, 53(3-4):265-277
Ravna K. 2000b. The garnet-clinopyroxene Fe2+-Mg geothermometer: an updated calibration. Journal of Metamorphic Geology, 18(2): 211-219.
Rietmeijer FJM.1983. Chemical distinction between igneous and metamorphic orthopyroxenes especially those coexisting with Ca-rich clinopyroxenes: a re-evaluation. Mineral. Mag, 47: 143-151
Roger F, Maluski H, Leyreloup A, Lepvrier C and Truong Thi P. 2007. U-Pb dating of high temperature metamorphic episodes in the Kon Tum Massif (Vietnam). Journal of Asian Earth Sciences, 30(3): 565-572.
Rogers JJW and Santosh M.2002a. Configuration of Columbia, a Mesoproterozoic supercontinent. Gondwana Research,5(1):5-22.
Rogers JJW and Santosh M. 2002b. Mesoproterozoic Supercontinent: Introduction. Gondwana Research, 5(1):3-4.
Rowley DB, Ziegler AM, Gyou N, Hsu KJ, Shu S, Jiliang L, Haihong C, Haipo P and Sengor A.1989. Comment and Reply on" Mesozoic overthrust tectonics in south China". Geology, 17(4): 384-387.
Shaw DM.1972. The origin of the Apsley gneiss, Ontario. Canadian Journal of Earth Sciences, 9(1):18-35.
Shu L-S, Faure M, Yu J-H and Jahn B-M.2011. Geochronological and geochemical features of the Cathaysia block (South China): New evidence for the Neoproterozoic breakup of Rodinia. Precambrian Research,187(3-4):263-276.
Salje E. 1986. Heat capacities and entropies of andalusite and sillimanite; the influence of fibrolitization on the phase diagram of the Al2SiO5 polymorphs. American Mineralogist, 71(11-12): 1366
Song S, Niu Y, Wei C, Ji J and Su L. 2010. Metamorphism, anatexis, zircon ages and tectonic evolution of the Gongshan block in the northern Indochina continent—An eastern extension of the Lhasa Block. Lithos,120(3-4):327-346.
Spear FS and Florence FP. 1992. Thermobarometry in granulites: pitfalls and new approaches. Precambrian Research,55(1-4):209-241
Spear FS, Kohn MJ and Cheney JT. 1999. P-T paths from anatectic pelites[J]. Contributions to Mineralogy and Petrology, 134(1):17-32.
Wan Y, Liu D, Xu M, Zhuang J, Song B, Shi Y and Du L. 2007. SHRIMP U-Pb zircon geochronology and geochemistry of metavolcanic and metasedimentary rocks in Northwestern Fujian, Cathaysia block, China: Tectonic implications and the need to redefine lithostratigraphic units. Gondwana Research, 12(1-2):166-183.
Wang Y, Fan W, Zhao G, Ji S and Peng T. 2007. Zircon U-Pb geochronology of gneissic rocks in the Yunkai massif and its implications on the Caledonian event in the South China Block. Gondwana Research, 12(4):404-416.
Wells PRA.1977. Pyroxene thermometry in simple and complex systems. Contributions to Mineralogy and Petrology, 62(2): 129-139
Winchester J and Floyd P. 1977. Geochemical discrimination of different magma series and their differentiation products using immobile elements. Chemical Geology, 20:325-343
Wu J, Liang H, Huang W, Wang C, Sun W, Sun Y, Li J, Mo J and Wang X.2012. Indosinian isotope ages of plutons and deposits in southwestern Miaoershan-Yuechengling, northeastern Guangxi and implications on Indosinian mineralization in South China. Chinese Science Bulletin, 57(9): 1024-1035.
Wu R, Zheng Y, Wu Y, Zhao Z, Zhang S, Liu X and Wu F.2006. Reworking of juvenile crust: Element and isotope evidence from Neoproterozoic granodiorite in South China. Precambrian Research, 146(3-4):179-212.
Xu X.2005. Relict Proterozoic basement in the Nanling Mountains (SE China) and its tectonothermal overprinting. Tectonics, 24(2).
Xu X, O'Reilly SY, Griffin WL, Wang X, Pearson NJ and He Z. 2007. The crust of Cathaysia: Age, assembly and reworking of two terranes. Precambrian Research, 158(1-2): 51-78.
Yao J, Shu L and Santosh M.2011. Detrital zircon U-Pb geochronology, Hf-isotopes and geochemistry—New clues for the Precambrian crustal evolution of Cathaysia Block, South China. Gondwana Research,20(2-3):553-567.
Yu JH, Zhou XM, Y.S.O'Reilly, et al.2005. Zircon U-Pb-Hf isotopic research on the formation time of the basement granulite facies metamorphic rocks and the characteristics of their protolith in the eastern Nanling[J]. Chinese Science Bulletin, 50(16):1758-1767.
Yu J, O'Reilly S, Wang L, Griffin W, Zhang M, Wang R, Jiang S and Shu L. 2008. Where was South China in the Rodinia supercontinent?::Evidence from U-Pb geochronology and Hf isotopes of detrital zircons. Precambrian Research,164(1-2):1-15.
Yu J, O'Reilly YS, Wang L, Griffin WL, Jiang S, Wang R and Xu X. 2007a. Finding of ancient materials in Cathaysia and implication for the formation of Precambrian crust. Chinese Science Bulletin, 52(1): 13-22.
Yu J, Wang L, O'Reilly SY, Shu L and Sun T. 2009a. Paleoproterozoic basement beneath the southern Jiangxi Province: Evidence from U-Pb ages and Lu-Hf isotopes in zircons from the Doushui lamprophyre. Chinese Science Bulletin, 54(9): 1555-1563.
Yu JH, O'Reilly SY, Zhao L, Griffin WL, Zhang M, Zhou X, Jiang SY, Wang LJ and Wang RC.2007b. Origin and evolution of topaz-bearing granites from the Nanling Range, South China: a geochemical and Sr-Nd-Hf isotopic study. Mineralogy and Petrology, 90(3-4): 271-300.
Yu JH, Wang L, O'Reilly S, Griffin W, Zhang M, Li C and Shu L.2009b. A Paleoproterozoic orogeny recorded in a long-lived cratonic remnant (Wuyishan terrane), eastern Cathaysia Block, China. Precambrian Research,174(3-4):347-363.
Yu J-H, O'Reilly SY, Zhou M-F, Griffin WL and Wang L. 2011. U-Pb geochronology and Hf-Nd isotopic geochemistry of the Badu Complex, Southeastern China: Implications for the Precambrian crustal evolution and paleogeography of the Cathaysia Block. Precambrian Research
Yu X, Hou M and Wang D. 2005. No evidence for a large Mesozoic overthrust in the Lantian area of Anhui Province, south China. Journal of Asian Earth Sciences,25(4):601-609.
Zhang Y, Shu L and Chen X.2011. Geochemistry, geochronology, and petro-genesis of the early Paleozoic granitic plutons in the central-southern Jiangxi Province, China. Science China Earth Sciences, 54(10):1492-1510.
Zhao G, Wilde SA, Cawood PA and Lu L. 1998. Thermal evolution of Archean basement rocks from the eastern part of the North China Craton and its bearing on tectonic setting. International Geology Review, 40(8):706-721.
Zhao G and Cawood P. 1999. Tectonothermal evolution of the Mayuan Assemblage in the Cathaysia Block; implications for Neoproterozoic collision-related assembly of the South China Craton. American Journal of Science,299(4):309-339.
Zhao G, Cawood PA, Wilde SA and Lu L. 2001. High-pressure granulites (retrograded eclogites) from the Hengshan Complex, North China Craton:petrology and tectonic implications. Journal of Petrology, 42(6):1141.
Zhao G, Cawood PA, Wilde SA and Sun M.2002. Review of global 2.1-1.8 Ga orogens: implications for a pre-Rodinia supercontinent. Earth-Science Reviews, 59(1-4): 125-162.
Zhao G, Sun M, Wilde SA and Li S.2003. Assembly, accretion and breakup of the Paleo-Mesoproterozoic Columbia supercontinent: records in the North China Craton. Gondwana Research, 6(3): 417-434.
Zhao G, Sun M, Wilde SA and Li S. 2004. A Paleo-Mesoproterozoic supercontinent: assembly, growth and breakup. Earth-Science Reviews, 67(1-2):91-123.
Zhao G, Sun M, Wilde SA and Sanzhong L. 2005. Late Archean to Paleoproterozoic evolution of the North China Craton: key issues revisited. Precambrian Research, 136(2): 177-202.
Zhao L, Guo F, Fan W, Li C, Qin X and Li H. 2010. Crustal evolution of the Shiwandashan area in South China: Zircon U-Pb-Hf isotopic records from granulite enclaves in Indo-Sinian granites. Chinese Science Bulletin,55(19):2028-2038.
Zheng JP, Griffin WL, Li LS, O'Reilly SY, Pearson NJ, Tang HY, Liu GL, Zhao JH, Yu CM and Su YP. 2011. Highly evolved Archean basement beneath the western Cathaysia Block, South China. Geochimica et Cosmochimica Acta,75(1):242-255.
Zhou XW, Wei CJ, Geng YS, et al.2004. Discovery and implications of the high-pressure pelitic granulite from the Qixia region in Jiaobei massif[J]. Chinese Science Bulletin,49(14):1424-1430.