Devonian Tectonic-Stratigraphic Realms and Lithostratigraphic Framework in China
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摘要: 泥盆纪是地球演化进程中最为关键的时段之一,如泥盆纪地球气候系统发生了重大转变、发生过多达25次的全球性海平面升降、泥盆纪晚期发生过生物大灭绝/更替事件、古亚洲洋俯冲消亡、古特提斯洋发生双向俯冲等,因此对中国泥盆纪进行构造‒地层区划、建立岩石地层格架具有十分重要的地质意义. 在分析泥盆纪全球洋陆重建、造山带对接缝合带和叠接缝合带洋板块地层分布与特征、地层序列完整性与接触关系、生物古地理区系、构造‒岩相古地理格局等的基础上,对中国泥盆系进行了构造‒地层区划,将中国泥盆系构造‒地层区划为12个大区和47个区;并编绘了泥盆纪构造‒地层区划图. 泥盆纪12个构造‒地层大区分别为阿尔泰‒兴蒙大区、佳木斯‒兴凯大区、额尔齐斯‒西拉木伦大区、天山‒准噶尔大区、南天山‒马鬃山大区、塔里木‒华北大区、秦祁昆大区、西昆仑‒布青山‒勉略大区、羌塘‒三江大区、班公湖‒双湖‒昌宁‒孟连大区、冈底斯‒喜马拉雅大区和华南大区. 在充分收集和利用地层剖面资料的基础上,建立了各构造‒地层区岩石地层格架.Abstract: Devonian is one of the key intervals in the Earth history and a critical period of many geological events, including great changes of climate system of the Earth, more than 25 global sea-level fluctuations, mass extinction/turnover events, closure and subduction of the Paleo-Asian Ocean, bidirectional subduction of paleo-Tethys ocean etc. Thus, it is of great significance to establish the Devonian tectonic-stratigraphic realms and lithostratigraphic framework in China. Based on the analyses of the reconstruction of global ocean and continent, ocean plate sequence distribution and characteristics of subordinate suture zone and main suture zone of orogenic belt, integrity and contact relation of striatigraphic sequence, paleobiogeographic province, tectonic-lithofacies paleogeographic framework etc., the Devonian tectonic-stratigraphic realm in China is divided into 12 super-realms and 47 realms, and the diagram of Devonian tectonic-stratigraphic realms was made. The 12 super-realms of the Devonian respectively are: Altai-Xing'an-Mongolian super-realm, Jiamusi-Xingkai super-realm, Irtysh-Xar Moron super-realm, Tianshan-Junggar super-realm, South Tianshan-Mazongshan super-realm, Tarim-North China super-realm, Qilian-Qinlin super-realm, West Kunlun-Buqingshan-Mianlue super-realm, Qiangtang-Sanjiang suoper-realm, Bangonghu-Shuanghu-Changning-Menglian super-realm, Gangdese-Himalaya super-realm and South China super-realm. On the adequately gathered data of the stratigraphic sequence, the lithostratigraphic framework or each tectonic-stratigraphic realm is established.
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图 1 中国泥盆纪构造-地层分区
a. 蛇绿岩及测年数据、引用的化石点及重要构造边界;b.泥盆纪构造-地层区划及引用的典型剖面分布,剖面说明同表 1.图中钻井据许杰等(2008)、辛仁臣(2011)、贾进华和申银民(2017)、马青等(2019). 审图号:GS(2025)1872号
Fig. 1. Devonian tectonic-stratigraphic realms in China
图 2 中国泥盆纪岩石地层格架——兴蒙‒天山、华北‒塔里木、秦祁昆
1.陆相‒海陆交互相‒滨海相碎屑岩;2.滨浅海碳酸盐岩夹(互层)碎屑岩;3.陆相‒滨浅海相火山岩夹(互层)碎屑岩、碳酸盐岩;4.浅海‒半深海相火山岩夹(互层)碎屑岩、碳酸盐岩;5.蛇绿混杂岩;6.深海(洋盆)浊积岩夹放射虫硅质岩;7.整合、平行不整合角度不整合接触;8.断层接触. 图中化石带说明:(1)大民山组:头足类①Manticoceras带,②Cheiloceras subpartitum带,③Platyclymenia wolcotti带;牙形石①Polygnathus varcus带,②Palmatolepis hassi下带.(2)北塔山组腕足类:Acrospirifer-Atrypa desquamata组合带和Mucrospirifer-Praewaagenoconcha组合带;珊瑚:Pachyfavosites polymorphus- Tyrganolites- Xinjiangolites组合带和Zonophyllum cylindricum组合带;植物Protolepidodendron-Psilophyton组合带.(3)托让格库都克组腕足类①Leptostrophia rotunda-Howellella组合带,②Acrospirfer-kozlowskiellina组合带,③Leptoenpyxis-Paraspirifer-Megakozlowskirellina组合带;珊瑚①床板珊瑚Squameofavosites-Placocoentes-Pseudofavosites组合带,②四射珊瑚Orthopaterophyllum sharburense-Schlotheimophyllum patellatum组合带.(4)洪古勒楞组牙形石:①Icriodus praealternatus ferus带,②Icrioduscornutus带,③Icriodus stenoancylus junggarensis带,④Icriodus plurinodosus带,⑤Neopolygnathus huijunae带,⑥Neopolygnathus communis communis带,⑦Alveognathus pomeranicus带,⑧Polygnathus cf. szulczewskii带,⑨Alveognathus pseudocommunis带(据王志宏等,2016;张欣松等,2019).(5)依克乌苏组头足类:①Anarcestes(Anarcestes)plebelus带(内蒙古自治区地质调查院,2024).(6)阿尔腾柯斯组放射虫组合带:Popofskyellum companella,Belodella cf. variabilis-Entactinia variospina,Entactinia vulgaris vulgaris-Astroentactinia multispinosa,Entactinosphaera palinbola,Astroentactinia crassata-Tetrentactinia braysphaera(刘羽等,1994);(7)中宁组-石峡沟组鱼类:①Quasipetalichthys-Bothriolepis niushoushanensis组合带,②Remigolepis zhongningensis-Sinolepis szei组合带(宁夏回族自治区地质调查院,2017).(8)查干合布组牙形石带Caudicriodus woschmidti woschmidti带,Ancyrodelloides delta带,Pedavis pesavis带,Eognathodus sulcatus带(王平,2006).(9)红岭山组牙形石:Palmatolepisgigas带,Ancyrognathustriangularis带,Po.asymmetricus带,K. disparilis带,S. hermani- Po.cristatus带,Po.varcus带(汪啸风和陈孝红,2005;甘肃省地质调查院,2024).(10)王冠沟组和葫芦山组植物Sublepidodendron mirabile-Lepidodendropsis hirmeri组合带(河南省地质调查院,2024).(11)铁山组腕足类-珊瑚:①Cyrtospirifer sinensis-Disphyllum kostetskae组合带,②腕足类Yunnanella-Yunnanellina组合带.(12)古道岭组Stringocephalus obesus-Undispirifer undiferus组合带.(13)石家沟组珊瑚、腕足类:Athyrisina-Utaratuia组合带(湖北省地质调查院,2024).(14)擦阔合组牙形石:Polygnathus asymmetricus带,Ancyrognathus triangnathus triangularis-Palmatolepis foliacea组合带;腕足类:Cyrtoirifer sinensis-Tenticoirifer cf.tenticulum组合带;珊瑚:Pseudozaphrentis conicum-Dihyllum dushanense组合带.(15)普通沟组‒尕拉组‒当多组‒下吾那组‒普莱组牙形石:①Icriodus woschmidti-Athognathodus remscheidensis组合带,②Polygnathus declinnatus带,③Eognathodus bipennatus montensis-Icriodus werneri组合带,④Icriodus regularicrescens带(?),⑤Icriodus arkonensis带(?),⑥Polygnathus aff. foliformis-Icriodus symmertricus组合带,⑦Ancyrognathus triangnathus triangularis-Palmatolepis foliacea组合带,⑧Polygnathus perplexus-athorognathus strigosus组合带. 竹节石:①Dicricoconus mosolovicus-Homoctenus tewoensis组合带,②Nowakia(N.)otomari-Homotenus tenuicinctus neglectus组合带,③Striatostyliolina raristriata-Homotenus tenuicinctus组合带(四川省地质调查院,2024;甘肃省地质调查院,2024)
Fig. 2. Devonian lithostratigraphic framework in China: Xing'an-Mongolian-Tianshan, North China-Tarim, Qinling-Qilian-Kunlun
图 3 中国泥盆纪岩石地层格架——青藏、扬子
1.台间海槽或台盆相、台缘斜坡相细碎屑岩夹(互层)硅质岩、碳酸盐岩;其他图例同图 2;图中化石带说明见附录
Fig. 3. Devonian lithostratigraphic framework in China: Qinghai‒Tibet, Yangtze
图 4 中国泥盆纪岩石地层格架——华夏
(1)洋湖组珊瑚Ceriphyllum elegantum-Caninia组合带;鱼类Asterolepis-Remigolepis组合.(2)麻山组腕足类Yunnanellina- Yunnanella组合带.(3)嶂岽组植物:①Leptophloeum rhombicum-Bothrodendron(Cyclostigma)kiltorkense组合带,②Leptophloeum rhombicum-Sublepidodendron mirabile组合带,③Sub. Mirabile-Lepidodendropsis hirmeri-Hamatophyton vertigillatum;腕足类Cyrtospirifer sinensis-Tenticospirifer组合带;鱼类Changyanophyton hupeiensis组合.(4)三门滩组腕足类Yunnanellina-Yunnanella组合带.(5)中棚组植物:①Protolepidodendron scharyanum-Barrandeina dusliana组合带,②Leptophloeum rhombicum-Bothrodendron(Cyclostigma)kiltorkense;鱼类:①Hunanolepis-Bothriolepis sinensis组合,②Bothriolepis lochangensi-B. kwangtungensis组合.(6)灵岩寺组植物Psilophytites-Taniocrada组合带(江西省地质调查院,2017).(7)余田桥组珊瑚Thamnopora-Disphyllum组合带.(8)吴家坊组腕足类Cyrtospirifer sinensis-Tenticospirifer组合带.(9)跳马涧组腕足类Desqumatia-Schizophoria striatula组合带(湖南省地质调查院,2017).(10)信都组腕足类Xenospirifer fonig带(广东省地质调查院,2024).(11)桃子坑组植物Leptophloeumrhombicum-Sublepidodendron mirabile组合带.(12)天瓦崠组植物Leptophloeum rhombicum-Cyclostigma kiltorkense组合带(福建省地质调查院,2016)
Fig. 4. Devonian lithostratigraphic framework in China: Cathaysian
表 1 构造-地层大区、区地层类型及主要特征
Table 1. Stratum types and main features of tectonic-stratigraphic super-realms and realms
大区 地层类型与特点 区 地层类型与特点 典型剖面 1阿尔泰‒兴蒙 以造山带地层为主 1-1阿尔泰区 岩浆弧或弧后盆地沉积,地层单元之间多以断层接触或角度不整合接触. 主要为滨浅海相中酸性‒中基性火山岩(双峰式火山岩)、火山碎屑岩夹陆源碎屑岩. 岩石变质变形较强(板岩、片岩),局部糜棱岩化较强 1、2、279、281 1-2漠河‒大兴安岭区 主要为滨浅海相(上泥盆统局部为海陆交互相)陆源碎屑岩夹火山碎屑岩;岩石浅变质(板岩、变砂岩、变质火山碎屑岩) 3、7~9、11~18 1-3二连‒贺根山区 以造山带洋板块地层为主,发育贺根山蛇绿混杂岩(380 Ma①;(403±27) Ma, 包志伟等,1994;(395.9±3.0) Ma,王成等,2018)及放射虫硅质岩 10、282 1-4锡林浩特区 岩浆弧,主要为滨浅海相(上泥盆统局部为海陆交互相)陆源碎屑岩夹火山碎屑岩;岩石浅变质(板岩) 1-5小兴安岭区 下中泥盆统主要为滨浅海相陆源碎屑岩夹火山碎屑岩;岩石浅变质(板岩);上泥盆统主要为中酸性火山岩、火山碎屑岩夹陆缘碎屑岩. 缺失早泥盆世早期和晚泥盆世晚期地层 19~24 1-6松辽隆起区 剥蚀区 2佳木斯‒兴凯 以造山带洋板块地层为主 2-1佳木斯区 以造山带洋板块地层为主,发育牡丹江增生杂岩带 2-2兴凯区 活动陆缘沉积,下泥盆统主要为滨浅海相陆源碎屑岩夹火山碎屑岩;岩石浅变质(板岩);中上泥盆统主要为中酸性火山岩、火山碎屑岩夹陆源碎屑岩,岩石浅变质(板岩) 25~27 3额尔齐斯‒西拉木伦 以造山带洋板块地层为主 3-1额尔齐斯区 发育斋桑蛇绿混杂岩、科克森套蛇绿混杂岩((405±4)Ma,滕宇翔等,2019)、乔夏哈拉蛇绿混杂岩(D3-C1,吴波等,2006;(368.4±2.9)Ma, 俞帅一,2020)、布尔根蛇绿混杂岩(363~355 Ma,王玉往等,2011);吐尔库班套蛇绿岩((380.0±2.2)Ma,王若梅,2014)等,伴生大量的放射虫硅质岩,岩石主体为半深海‒深海砂板岩+火山碎屑岩(双峰式火山岩),岩石浅变质,局部片岩化、糜棱岩化 4~6、283、284、301、305 3‒2西拉木伦区 发育索伦山蛇绿混杂岩((371.0±5.3)Ma,李尚林等,2012)、查干乌拉俯冲增生杂岩(蓝片岩) 28 4天山‒准噶尔 以造山带地层为主 4-1赛米斯台‒三塘湖区 岛弧环境沉积,主要为海陆交互相‒滨浅海相陆源碎屑岩夹中酸性‒中基性火山岩(双峰式火山岩)、火山碎屑岩,局部发育硅质岩、碳酸盐岩 32~35、285、287、288、299、256 4-2达拉布特‒卡拉麦里区 洋板块地层,发育达拉布特蛇绿岩((391.1±6.8)Ma,辜平阳等,2009;(395±1.2)Ma,张弛等,1992)、卡拉麦里蛇绿岩((398.5±1.7)Ma,李秉政,2019;(418.5±5.4)Ma;李现冰,2012;(416.7±3.2)Ma,黄岗等,2017),及放射虫硅质岩 31、36、37、286、259 4-3准噶尔区 剥蚀区 4-4巴音沟区 洋板块地层,发育巴音沟蛇绿岩((385.7±3.6)Ma,苏会平等,2014),及放射虫硅质岩. 主体岩性为一套半深海‒深海相陆源碎屑岩、硅质岩夹中基性火山岩、火山碎屑岩,岩石浅变质 40、271 4-5中天山区 岩浆弧或弧后盆地沉积,主体缺失下泥盆统,局部发育下统(大南湖组);中上统主体为海陆交互相‒滨浅海相基性‒酸性火山岩、火山碎屑岩夹陆源碎屑岩及少量碳酸盐岩、硅质岩,岩石浅变质(板岩、千枚岩,局部可达片岩、强蚀变玄武岩、片理化、糜棱岩化) 38、39、41、42、45、46、47 4-6伊犁区 剥蚀区 4-7北山区 岩浆弧或弧后盆地沉积,岩浆弧内雀儿山群为一套中基性-酸性火山岩(双峰式火山岩)、火山碎屑岩夹碎屑岩、碳酸盐岩的岩石组合;弧后盆地相沉积为一套滨浅海相碎屑岩夹碳酸盐岩、硅质岩沉积 49、50 5南天山‒马鬃山 以造山带洋板块地层为主 5-1那拉提‒南天山区 发育乌瓦门蛇绿岩(S3D1)、榆树沟蛇绿岩(S3D1)、库勒湖蛇绿岩((418.2±2.6)Ma,马中平等,2007)、吉根蛇绿岩((392±15)Ma,徐学义等,2003)、齐齐加纳克蛇绿岩((399±4)Ma,王莹等,2012;(397.3±3.9)Ma,王斌等,2016)、榆树沟蛇绿岩((378.2±6.3)Ma,姜常义等,2000). 下泥盆统主要为浅海相‒半深海相碎屑岩、碳酸盐岩夹火山岩组合,岩石变质变形较强,板岩、千枚岩、片岩、变粒岩. 中泥盆统为一套滨浅海相碳酸盐岩‒碎屑岩夹少量火山岩、火山碎屑岩组合,弱变质. 上泥盆统,西南天山整体为半深海浊积岩‒深海远洋沉积,发育大量的放射虫硅质岩,岩石浅变质;南天山中部主要为浅海台地相或滨海泻湖相碳酸盐岩夹碎屑岩、石膏层,浅变质;南天山东部为一套火山熔岩、火山碎屑岩夹少量正常碎屑沉积建造,岩石中等变质(片岩) 43、44、48、51~57、59、289、303、308、262 5-2红柳河‒恩格尔乌苏区 发育牛圈子‒红柳河‒洗肠井‒恩格尔乌苏蛇绿混杂岩((362.6±4.0)Ma,余吉远等,2012;(410.5±3.7)Ma,Tian et al.,2014). 下中泥盆统为一套滨浅海相碎屑岩夹中性、中酸性火山岩,上泥盆统为一套中酸性火山岩、火山碎屑岩沉积 290、291 6塔里木‒华北 以克拉通有序地层序列为主 6-1塔里木区 碎屑岩陆表海或混积陆表海,主体为滨浅海相碎屑岩夹碳酸盐岩沉积,下泥盆统局部为浅海相‒半深海相细碎屑岩夹碳酸盐岩沉积,偶夹火山碎屑岩;岩石未变质或浅变质,局部达中深程度变质,片岩、大理岩、变粒岩,片理、片麻理发育 58、292、290、291;钻井1~47 6-2敦煌区 陆缘裂陷盆地沉积,下中泥盆统为一套滨浅海相碎屑岩夹中性、中酸性火山岩,上泥盆统为一套中酸性火山岩、火山碎屑岩沉积 290、291 6-3阿拉善区 剥蚀区 6-4华北区 主体为剥蚀区,仅在西缘及北缘发育泥盆系. 西缘缺失下泥盆统,中上泥盆统为陆缘裂陷盆地(陆相);北缘缺失中泥盆统,下泥盆统为滨浅海碎屑岩夹碳酸盐岩沉积,岩石浅变质(板岩);上泥盆统为一套基性至中酸性熔岩、变火山碎屑岩,岩石中等变质(片岩、片理化) 29、30、71、72、309、73 7秦祁昆 以造山带地层为主 7-1阿尔金区 剥蚀区 7-2北祁连区 磨拉石建造,陆相坳陷盆地沉积,地层单元间多为不整合接触 70、74、293、294 7-3南祁连区 剥蚀区 7-4柴达木-昆北区 火山裂陷盆地沉积,主体为陆相(晚泥盆世局部为海陆交互相)火山岩、火山碎屑岩夹陆源碎屑岩 63、66~69、295 7-5北秦岭区 剥蚀区 7-6中秦岭区 缺失下泥盆统(局部发育晚期地层),为陆缘裂谷盆地沉积,主体为一套浅水复理石式细碎屑岩夹碳酸盐岩沉积,岩石浅变质(板岩、千枚岩),北部边缘南湾组局部变质程度较深,从低绿片岩相到角闪岩相变质 83~87、95、296、310 7-7南秦岭区 被动陆缘台地-台盆相碳酸盐岩夹细碎屑岩沉积,岩石未变质或浅变质(板岩) 75~79、81、82、88~94 8西昆仑‒布青山‒勉略 以造山带洋板块地层为主 8-1西昆仑区 缺失下泥盆统,中上泥盆统为混积台地相,主体为一套陆源碎屑岩夹碳酸盐岩沉积,岩石未变质;发育康西瓦‒苏巴什蛇绿混杂岩(Z-P)(温志刚等,2019),混杂岩中依克沙群上段为深海远洋浊积岩,含晚泥盆‒早石炭世放射虫(鲁浩等,2021) 60、61、270 8-2布青山区 缺失下泥盆统,中泥盆统为陆缘裂陷盆地碎屑岩夹灰岩、火山碎屑岩、硅质岩(含放射虫)、硅质板岩组合;上泥盆统为半深海‒深海相碎屑岩夹灰岩、硅质岩建造,多呈断块产出;发育布青山蛇绿混杂岩带:几克里阔勒蛇绿岩、阿克苏库勒蛇绿岩等(Pt3-P,裴先治等,2018) 64、65、302 8-3勉略区、8-4苏鲁区 整体为一套半深海‒深海浊积岩沉积(或类复理石沉积),局部上泥盆统为碳酸盐台地沉积(略阳组),岩石自西向东变质程度由浅(板岩、千枚岩)加深(片岩);发育勉略蛇绿混杂岩带(Pt3-T1) 80、313、149、269、314 9羌塘‒三江 北部甜水海‒巴颜喀拉以有序地层为主,南部以造山带地层为主 9-1甜水海‒巴颜喀拉区 被动陆缘,主要为一套陆缘碎屑岩、碳酸盐岩沉积,局部为陆缘斜坡相细碎屑岩、碳酸盐岩夹硅质岩、硅质泥岩沉积(石坊组、危关组、雪宝顶组) 96、97~99、105、106、137~139 9-2西金乌兰‒金沙江‒哀牢山区 洋板块地层为主,发育通天河蛇绿混杂岩、金沙江蛇绿混杂岩、甘孜‒理塘蛇绿混杂岩(DT2,王冬兵等,2012;西藏自治区地质调查院,2024);西藏兽形湖‒青海移山湖、玉树‒西藏芒康县‒四川巴塘主体为一套滨浅海‒半深海碳酸盐岩夹碎屑岩沉积,局部发育放射虫硅质岩;云南省墨江县碧溪乡‒绿春县大水沟乡一带主体为一套深海相类复理石沉积 100~102、109、111~117、264 9-3羌塘区 弧后盆地,玉树‒杂多‒江达一带主体为一套中酸性‒基性火山岩、火山碎屑岩夹碳酸盐岩、陆缘碎屑岩,岩石浅‒中等程度变质(千枚岩、片岩、大理岩);西藏芒康一带主要为一套台地相碳酸盐岩夹陆源细碎屑岩 103、104、107、108、110 9-4昌都‒思茅区 弧后盆地,北部昌都‒江达一带为一套中酸性‒基性火山岩、火山碎屑岩夹碳酸盐岩、陆缘碎屑岩,岩石浅‒中等程度变质岩(千枚岩、片岩、大理岩);南部巴塘‒中甸一带为一套台地相碳酸盐岩夹陆源细碎屑岩,晚泥盆世塔利坡组局部夹基性火山岩,岩石局部浅变质(板岩) 113、118 10班公湖‒双湖‒昌宁‒孟连 以造山带洋板块地层为主 10-1班公湖‒双湖区 发育类龙木措‒双湖‒南沧江蛇绿混杂岩带:桃形湖蛇绿混杂岩、果干加年山蛇绿混杂岩(O2-P)((367±3.3)Ma,吴彦旺,2013). 龙木措‒双湖一带为一套台地斜坡相碳酸盐岩夹细碎屑岩,发育角砾状灰岩,岩石浅变质(板岩、大理岩化灰岩);左贡县莫得‒梅里雪山‒贡山县一带为一套深海复理石沉积(莫得群),发育较多放射虫硅质岩,岩石未变质 119、120、268、307、311 10-2昌宁‒孟连区 发育铜厂街蛇绿混杂岩(O2-P)(潘桂棠等,2020),主体为一套深海浊积岩,发育较多放射虫硅质岩(莫得群、曼信组),岩石未变质 121、122、133、265、272 11冈底斯‒喜马拉雅 以克拉通有序地层序列为主 11-1冈底斯区 被动陆缘,为一套台地相或台地边缘相碳酸盐岩沉积,局部为混积台地相碳酸盐岩夹碎屑岩沉积,岩石局部变质为大理岩(松宗组) 126、128~130、297 11-2喜马拉雅区 被动陆缘,主要为一套滨浅海相陆源碎屑岩夹(互层)碳酸盐岩沉积,扎达‒玛旁雍错‒仲巴一带,岩石浅变质(板岩、千枚岩、大理岩化、变砂岩)‒中等变质(片岩、大理岩);定日‒措美‒墨脱一带岩石未变质 123~125、127 11-3保山‒腾冲区 被动陆缘,主体为一套碳酸盐岩台地相碳酸盐岩夹少量碎屑岩沉积,施甸县城西大寨门一带上泥盆统大寨门组为水体较深的台盆相硅质岩 131~134、298、312 12华南 以克拉通有序地层序列为主 12-1上扬子区 川中盆地及攀枝花‒楚雄一带缺失整个泥盆系,下泥盆统主要发育于滇东南‒桂西南、龙门山及滇西北地区,湘南及贵阳地区局部发育早泥盆世晚期地层,其中上扬子西南缘的丽江阿冷初、四川攀枝花、云南曲靖等为华南泥盆系与志留系连续沉积主要的地区之一;除川中盆地及攀枝花‒楚雄,整个上扬子均发育中上泥盆统,其中江汉‒张家界一带,发育上泥盆统,局部发育吉维特阶上部地层(云台观组下部). 整个上扬子区具复杂的台盆分异格局,这种分异格局表现为四种沉积地层类型:曲靖型、象州型、北流型和南丹型 135、136、141、219、273、140、142~148、150~217 12-2下扬子区 主体发育上泥盆统,仅仅在湖南长沙县跳马涧镇‒江西高安市黄沙岗乡一带发育中泥盆统,主要为海陆交互相‒滨浅海相碎屑岩,局部为碳酸盐岩;主要产植物、鱼类、腕足类、珊瑚等化石 220~232 12-3钦防区 发育与志留系连续沉积的主要地区之一,北部为一套台地相碳酸盐岩沉积,底部为碎屑岩;南部为一套半深海相粉砂岩、粉砂质泥岩、硅质泥岩、硅质岩 218、234、236 12-4华夏区 缺失下泥盆统洛赫考夫阶,局部缺失整个下泥盆统. 下中泥盆统主要为海陆交互相‒滨浅海相碎屑岩沉积,中上泥盆统主要为混积台地相碎屑岩夹碳酸盐岩沉积,怀集‒高州及韶关‒阳山一带局部发育较深水的台盆相(南丹型沉积)硅质泥岩、硅质团块灰岩 233、274~277、237~255 12-5台湾‒海南区 主体为剥蚀区,仅在海南省昌江县石碌镇鸡实村一带发育少量上泥盆统法门期地层,为局限台地相至潮坪环境下的碳酸盐岩与陆源碎屑岩的混合沉积 注:典型剖面代号同图 1. 含重要生物群剖面说明:29.内蒙古达茂旗敖日图斯查干合布组剖面(内蒙古自治区地质调查院,2024);40.新疆乌苏市巴音沟牧场安集海河上游依连哈比尔尕组(新疆维吾尔自治区地质调查院,2024);50.内蒙古额济纳旗卧驼山依克乌苏组、卧驼山组、西屏山组剖面(内蒙古自治区地质调查院,2024);62.新疆阿克陶县卡拉巴西塔克奇自拉夫组剖面(新疆维吾尔自治区地质调查院,2024);64、65. 据任军虎(2010);73.宁夏中宁县白马乡石狭沟组、中宁组剖面(宁夏回族自治区地质调查院,2017);77.四川省若尔盖县占哇乡普通沟普通沟组剖面;78.四川省若尔盖县占哇毕冈‒拉瓦尕拉组剖面);105.四川省松潘县黄龙乡河凤崖石坊组剖面;106.四川省松潘县黄龙乡张沟梁当多组、下吾那组、益哇沟组剖面(四川省地质调查院,2024);113.云南省中甸县银厂沟至冉家湾冉家湾组剖面;131.云南省施甸何元寨何元寨组剖面;132.云南省施甸大寨门大寨门组剖面;133.云南省昌宁温泉温泉组剖面;134. 云南省施甸向阳寺向阳寺组剖面(云南省地质调查院,2024);136.四川省北川县桂溪乡‒沙窝子平驿铺组‒茅坝组剖面;137.四川省北川县建设乡关磨‒小寨子沟口危关组剖面(四川省地质调查院,2024);142.云南省洱源县青山‒横阱长育村组剖面;143.云南省洱源县青山‒横阱莲花曲组剖面(云南省地质调查院,2024);155.四川省越西县碧鸡山黑巴已得坡松冲组‒曲靖组剖面(四川省地质调查院,2024);158.贵州省独山县猴儿山泥盆系丹林组‒邦寨组剖面;159.贵州省独山县摆读中上泥盆统独山组‒望城坡组剖面;161.贵州省紫云县火烘镇火烘组‒五指山组剖面;164.贵州省都匀市朱紫蟒山组剖面(贵州省地质调查院,2019);170.云南曲靖县翠峰山地区下西山村组、西屯组、桂家屯组剖面(郄文昆等,2019);172.广西南丹县大厂五指山组剖面(广西壮族自治区地质调查院,2024);178.湖南冷水江市锡矿山欧家冲锡矿山组剖面;179.湖南邵东佘田桥组剖面(郄文昆等,2019);186.据马学平等(2004);187.湖南省嘉禾县石古元水库巴漆组、榴江组剖面;188.湖南省新田县木井塘锡矿山组、孟公坳组剖面(湖南省地质调查院,2017);190.广西桂林城西老人山桂林组剖面;194.广西阳朔回龙上泥盆统额头村组剖面;196.广西鹿寨县寨沙镇榴江组‒五指山组剖面;199.广西象州大乐乡大乐组剖面;202.广西象州县妙皇上伦莲花山组‒大乐组剖面;203.广西象州县中平马鞍山东岗岭组剖面(广西壮族自治区地质调查院,2024);207.广西横县六景泥盆系莲花山组‒谷闭组正层型剖面;211.广西田林县八渡泥盆系剖;234.广西钦州市板城镇石梯水库组剖面;236.广西钦州市小董镇倒流村下泥盆统钦州组剖面(广西壮族自治区地质调查院,2024);256.新疆乌兰柯顺朱鲁木特组‒洪古勒楞组剖面(黄程,2015;王志宏,2016);257.广西天等把荷那叫组剖面(卢建峰,2013);259.新疆布龙果尔洪古勒楞组剖面(张欣松,2019);260. 据廖卫华等(2013);261.甘肃省迭部县当多沟普通沟组‒尕拉组‒当多组‒下吾那组‒普莱组‒擦阔合组剖面(甘肃省地质调查院,2019);262.新疆铁力买提达坂剖面(吴浩若,2013);263.广西桂林南边村剖面融县组(广西壮族自治区地质调查院,2024);264.据周晨等(2018);266.据纵瑞文等(2015);266、267.据李现冰(2012);268.据朱同兴等(2006);269.据王宗起等(1999);270.据方爱民等(2000);271~273.据王玉净等(2000, 2013);289.新疆拜城县黑英山乡阿尔腾柯斯河阿尔腾柯斯组剖面(新疆维吾尔自治区地质调查院,2024). 项目组实测剖面说明:258.广西桂林全州县东山瑶族乡古木村棋梓桥组‒锡矿山组实测剖面;274.广东省连南县三排镇唐家湾组‒桂林组‒东村组实测剖面;275.广东省阳山县江英镇长耳磅泥盆纪巴漆组实测剖面;276.广东省阳山县青莲镇瓦厂‒草屋坪泥盆系融县组实测剖面;277.广东省阳山县青莲镇鹿狮洞泥盆纪棋梓桥组实测剖面;278.湖南省安仁县排楼乡龙源村上泥盆统锡矿山组‒欧家冲组实测剖面. 其他剖面据2019‒2021年全国各省地质志. ①曹从周,杨芳林,田昌烈,等,1986.内蒙古贺根山地区蛇绿岩及中朝板块和西伯利亚板块之间的缝合带位置.见:中国北方板块构造论文集编委会编,中国北方板块构造论文集(1).北京:地质出版社,64‒86. 
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