Sedimentary di fferentiation characteristics of and the main factors controlling the Upper Devonian-Lower Carboni ferous sediments in the eastern Qaidam Basin

doi:10.13745/j.esf.sf.2020.5.11

Abstract

Abstract:

The Devonian-Carboniferous boundary is an extensive unconformity. In the eastern Qaidam Basin, typical sedimentary diversity developed in the Upper Devonian-Lower Carboniferous sediments, representing a large-scale sedimentary environmental change during the Late Devonian-Carboniferous period. To investigate the differences and inherent relations between the Upper Devonian and Lower Carboniferous, we compared the rock assemblage, distribution and lithofacies between the two, using petrologic methods, and described the spatial distribution characteristics of the Late Devonian-Early Carboniferous sediments. By combining the above results with geological background, we discussed the inherent factors for the sedimentary distribution difference. The results demonstrate not only obvious sedimentary differences but also inherent correlation between the Upper Devonian and Lower Carboniferous strata in the eastern Qaidam Basin according to material characteristics and paleogeomorphologic features. Although there is a depositional discontinuity between the two periods, the early-stage Early Carboniferous sediments display inherited paleogeomorphologic features of the Upper Devonian. Under the Late Caledonian NS-trending stress, a NS-differentiated geomorphologic framework started to emerge in the Late Devonian, and the area developed sedimentary systems featuring alluvial fan-volcano. In the early-stage Early Carboniferous paleogeomorphologic framework showing more obvious inheritance, the basic sedimentary composition was similar to that of the Late Devonian period. However, deplanation became dominant as orogeny weakened, and humid climate further altered sedimentary morphology. The rock assemblage evolved from the bottom oxide color upward to gray and grayish-black, and the lithofacies changed from discerning river to mixed tidal flat, accompanied by small-scale interbedding of transgressive and biological marls. The late-stage Early Carboniferous exhibited greater variety than inheritance until deplanation ended. The warming of climate caused glacier melting, and the changing sea level led to global large-scaled transgression. Thus, with the expansion of the Paleo-Asian and Paleo-Tethys oceans, seawater flooded northward across the study area. In addition, due to its low altitude location during that period, the Qaidam Basin experienced marine bloom under warm climate that eventually promoted sedimentary deposition of large-scale epicontinental marine carbonate rocks.

Key words: Qaidam Basin, Upper Devonian-Lower Carboniferous, sedimentary differentiation, controlling factor, inherited deposition

CLC Number:

PENG Bo, LIU Chenglin, QI Kening, LIU Dapeng, WANG Jiaqi, LI Zongxing, MA Yinsheng, HU Junjie. Sedimentary di fferentiation characteristics of and the main factors controlling the Upper Devonian-Lower Carboni ferous sediments in the eastern Qaidam Basin[J]. Earth Science Frontiers, 2021, 28(1): 104-114.

Figures/Tables 8

References 50

[1]	黄勇, 韩颖平, 白龙, 等. 滇西施甸地区泥盆系-石炭系接触关系新认识[J]. 地质通报, 2013, 32(11):1769-1776.
[2]	高联达. 长江下游地区晚泥盆世至早石炭世孢子带和泥盆系—石炭系界线[J]. 地球学报, 2015, 36(1):7-21.
[3]	彭中勤, 王传尚, 李志宏, 等. 黔南坳陷泥盆—石炭纪之交海平面变化及碳同位素异常[J]. 桂林理工大学学报, 2014, 34(2):235-244.
[4]	BÁBEK O, KUMPAN T, KALVODA J, et al. Devonian/Carboniferous boundary glacioeustatic fluctuations in a platform-to-basin direction: a geochemical approach of sequence stratigraphy in pelagic settings[J]. Sedimentary Geology, 2016, 337(5):81-99. DOI URL
[5]	魏小洁, 马寅生, 李宗星, 等. 柴达木盆地北缘上石炭统碎屑岩-碳酸盐岩高频转换过程及驱动机制[J]. 古地理学报, 2018, 20(3):409-422.
[6]	程荣, 肖永军, 林会喜, 等. 柴达木盆地北缘东段石炭系残留分布及控制因素[J]. 地学前缘, 2016, 23(5):75-85.
[7]	王训练, 高金汉, 张海军, 等. 柴达木盆地北缘石炭系顶、底界线再认识[J]. 地学前缘, 2002, 9(3):65-72.
[8]	汤良杰, 金之钧, 张明利, 等. 柴达木盆地构造古地理分析[J]. 地学前缘, 2000, 7(4):421-429.
[9]	杨超, 陈清华, 任来义, 等. 柴达木盆地构造单元划分[J]. 西南石油大学学报(自然科学版), 2012, 34(1):25-33.
[10]	孙娇鹏, 陈世悦, 刘成林, 等. 柴达木盆地东北部晚古生代盆地构造环境: 来自碎屑岩地球化学的证据[J]. 地学前缘, 2016, 23(5):45-55.
[11]	杨惠心, 禹惠民, 李鹏武. 柴达木地块古地磁研究及其演化[J]. 长春地质学院学报, 1992, 22(4):420-426.
[12]	吴汉宁, 刘池阳. 用古地磁资料探讨柴达木地块构造演化[J]. 中国科学: D辑, 1997, 27(1):9-14.
[13]	EYLES N. Glacio-epochs and the supercontinent cycle after similar to 3.0 Ga: tectonic boundary conditions for glaciation[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2008, 258(1):89-129. DOI URL
[14]	SCOTESE C R. Goal of the PALEOMAP Project[EB/OL]. (2019-10-12)[2020-01-25].http://www.scotese.com, 2002-02-03.
[15]	祁生胜. 青海省东昆仑造山带火成岩岩石构造组合与构造演化[D]. 北京: 中国地质大学(北京), 2015.
[16]	张胜. 野马泉地区磁测异常推断解释研究[D]. 北京: 中国地质大学(北京), 2013.
[17]	马寅生, 尹成明, 刘成林, 等. 柴达木盆地石炭系资源潜力评价[M]. 北京: 地质出版社, 2014.
[18]	何登发, 马永生, 蔡勋育, 等. 中国西部海相盆地地质结构控制油气分布的比较研究[J]. 岩石学报, 2017, 33(4):1037-1057.
[19]	江小均, 任纪舜, 周鼎武, 等. 东秦岭加里东期沉积-构造演化过程[J]. 地球科学, 2019, 44(1):88-108.
[20]	马青, 马涛, 杨海军, 等. 塔里木盆地上泥盆统—下石炭统滨岸-混积陆棚三级层序发育特征[J]. 石油勘探与开发, 2019, 46(4):666-674.
[21]	袁亚娟, 夏斌, 吕宝凤, 等. 柴北缘东段石炭纪沉积特征及原型盆地恢复[J]. 沉积与特提斯地质, 2012, 32(1):12-17.
[22]	青海省地质矿产局. 青海省区域地质志[M]. 北京: 地质出版社, 1991: 110-172.
[23]	吴因业, 宋岩, 贾承造, 等. 柴北缘地区层序格架下的沉积特征[J]. 地学前缘, 2005, 12(3):195-203.
[24]	PASCHALL O, CARMICHAEL S K, KÖNIGSHOF P, et al. The Devonian-Carboniferous boundary in Vietnam: sustained ocean anoxia with a volcanic trigger for the Hangenberg Crisis?[J]. Global and Planetary Change, 2019, 175(4):64-81. DOI URL
[25]	牛永斌, 钟建华, 段宏亮, 等. 柴达木盆地石炭系沉积相及其与烃源岩的关系[J]. 沉积学报, 2010, 28(1):140-151.
[26]	马帅, 陈世悦, 贾贝贝, 等. 柴达木盆地北缘早奥陶世台地-斜坡-盆地相沉积特征及控制因素[J]. 地学前缘, 2018, 25(4):185-197.
[27]	陈世悦, 毕明威, 孙娇鹏, 等. 柴北缘上古生界混合沉积特征及控制因素[J]. 地质通报, 2016, 35(21):282-292.
[28]	李社平. 准噶尔盆地西北缘阿舍勒附近泥盆纪火山机构及其地质意义[J]. 新疆有色金属, 2011, 34(2):23-27.
[29]	陈晔, 孙明新, 张新龙. 西准噶尔巴尔鲁克断裂东南侧石英闪长岩锆石SHRIMP U-Pb测年[J]. 地质通报, 2006, 25(8):992-994.
[30]	李忠, 高剑, 郭春涛, 等. 塔里木块体北部泥盆—石炭纪陆缘构造演化: 盆地充填序列与物源体系约束[J]. 地学前缘, 2015, 22(1):35-52.
[31]	赖绍聪, 邓晋福, 赵海玲. 柴达木北缘古生代蛇绿岩及其构造意义[J]. 现代地质, 1996(1):19-29.
[32]	杨超, 陈清华, 王冠民, 等. 柴达木地区晚古生代沉积构造演化[J]. 中国石油大学学报(自然科学版), 2010, 34(5):38-43.
[33]	杨超. 柴达木盆地构造特征及石炭系勘探前景[D]. 北京: 中国石油大学, 2010.
[34]	王宗秀, 李春麟, NIKOLAIJ P, 等. 西天山造山带构造单元划分及古生代洋陆转换过程[J]. 中国地质, 2017, 44(4):623-641.
[35]	吴浩若, 李忠. 南天山洋古地理及构造演化: 西南天山放射虫硅质岩与地层记录的再认识[J]. 古地理学报, 2013, 15(3):293-304.
[36]	代昆, 刘成林, 肖敦清, 等. 柴达木盆地欧龙布鲁克地区构造演化研究[J]. 地学前缘, 2016, 23(5):33-44.
[37]	MENNING M, ALEKSEEV A S, CHUVASHOV B I, et al. Global time scale and regional stratigraphic reference scales of Central and West Europe, East Europe, Tethys, South China, and North America as used in the Devonian-Carboniferous-Permian Correlation Chart 2003[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2006, 240(1):318-372. DOI URL
[38]	KAUFMANN B. Calibrating the Devonian time scale: a synjournal of U-Pb ID-TIMS ages and conodont stratigraphy(Article)[J]. Earth-Science Reviews, 2006, 76(3):175-190. DOI URL
[39]	COHEN K M, FINNEY S C, GIBBARD P L, et al. The ICS international Chronostratigraphic Chart[J]. Episodes 2013, 36(1):199-204. DOI URL
[40]	王训练. 从综合地层学观点论华南浅海相泥盆系-石炭系的分界[J]. 地质论评, 1997, 43(4):394-402.
[41]	吴祥和. 黔南泥盆-石炭系界线层层序和海退事件[J]. 地层学杂志, 1986, 10(3):204-211.
[42]	许伟, 孙知明, 裴军令, 等. 青藏高原北部柴达木块体晚二叠世古地磁结果及其构造意义[J]. 岩石学报, 2011, 27(11):3479-3486.
[43]	余辉龙, 邓宏文, 胡勇. 从古地磁资料看柴达木盆地古构造环境[J]. 石油勘探与开发, 2002, 29(6):41-44.
[44]	MII H S, GROSSMAN E L, YANCEY T E. Carboniferous isotope stratigraphies of North America: implications for Carboniferous paleoceanography and Mississippian glaciation[J]. Geological Society of America Bulletin, 1999, 111(7):960-973. DOI URL
[45]	SALTZMAN M R. Carbon isotope (δ¹³C) stratigraphy across the Silurian Devonian transition in North America: evidence for a perturbation of the global carbon cycle[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2002, 187(1):83-100. DOI URL
[46]	KAMMER T W, AUSICH W I. Stratigraphical and geographical distribution of Mississippian (Lower Carboniferous)Crinoidea from England and Wales[J]. Proceedings of the Yorkshire Geological Society, 2006, 56(2):91-109. DOI URL
[47]	WOLFENDEN E B. Paleoecology of the Carboniferous reef complex and shelf lime-stones in northwest Derbyshire, England[J]. Bulletin of the Geological Society of America, 1958, 69(7):871-898. DOI URL
[48]	EL-SHAZLY S H. Late Carboniferous macrofauna from Wadi Araba, Eastern Desert, Egypt, and their paleoecological implications[J]. Journal of African Earth Sciences, 2011, 61(5):369-394. DOI URL
[49]	SHI G R, CHEN Z Q, LEE S M, et al. Early Carboniferous spiriferoid brachiopods from the Qaidam Basin, Northwest China: Taxonomy, biostratigraphy and biogeography[J]. Palaeoworld, 2016, 25(4):581-599. DOI URL
[50]	马寅生, 尹成明, 刘成林, 等. 柴达木盆地石炭系油气资源调查评价进展[J]. 地球学报, 2012, 33(2):135-144.

统	组	岩性组合	岩石类型	典型剖面
下石炭统	怀头他拉组	礁灰岩发育带	礁灰岩、生屑灰岩、粉晶灰岩、微晶灰岩	石灰沟剖面、穿山沟剖面
	怀头他拉组	泥灰岩-颗粒灰岩发育带	泥灰岩、微晶灰岩、粉晶灰岩、颗粒灰岩、砂屑灰岩	死狼沟剖面
	城墙沟组	粉砂岩-泥岩发育带	粉砂岩、泥质粉砂岩、细砂岩、泥岩	城墙沟剖面、穿山沟剖面
	城墙沟组	砂砾岩-灰岩发育带	疙瘩状灰岩、生屑灰岩、生物灰岩、含砾粗砂岩、石英杂砂岩、粉砂质泥岩	尕海南山剖面
上泥盆统	牦牛山组	千枚岩-片岩发育带	千枚岩、片岩、大理岩	穿山沟剖面、阿尔格勒泰剖面
		砾岩发育带	砾岩、泥岩、粉砂质泥岩	城墙沟剖面、牦牛山剖面
		火山岩发育带	安山岩	尕海南山剖面、都兰剖面

统	组	岩性组合	岩石类型	典型剖面
下石炭统	怀头他拉组	礁灰岩发育带	礁灰岩、生屑灰岩、粉晶灰岩、微晶灰岩	石灰沟剖面、穿山沟剖面
	怀头他拉组	泥灰岩-颗粒灰岩发育带	泥灰岩、微晶灰岩、粉晶灰岩、颗粒灰岩、砂屑灰岩	死狼沟剖面
	城墙沟组	粉砂岩-泥岩发育带	粉砂岩、泥质粉砂岩、细砂岩、泥岩	城墙沟剖面、穿山沟剖面
	城墙沟组	砂砾岩-灰岩发育带	疙瘩状灰岩、生屑灰岩、生物灰岩、含砾粗砂岩、石英杂砂岩、粉砂质泥岩	尕海南山剖面
上泥盆统	牦牛山组	千枚岩-片岩发育带	千枚岩、片岩、大理岩	穿山沟剖面、阿尔格勒泰剖面
		砾岩发育带	砾岩、泥岩、粉砂质泥岩	城墙沟剖面、牦牛山剖面
		火山岩发育带	安山岩	尕海南山剖面、都兰剖面

统	组	岩性	地点	最小厚度/m	最大厚度/m	平均厚度/m	典型剖面
下石炭统	怀头他拉组	变质岩-火山岩相	宗务隆山以北	170.0	350.0	261.0	关角日吉、天峻南
	怀头他拉组	碳酸盐相	欧龙布鲁克—阿木尼克—阿拉格尔泰山一线广大地区	86.9	763.0	525.0	怀头他拉水库、柴页2、石灰沟、城墙沟、埃北1、夏日哈、关角牙
	城墙沟组	变质岩相	宗务隆山以北	22.0	164.0	98.0	宗务隆北坡、吉给申沟
	城墙沟组	碎屑岩-碳酸盐混积相	欧龙布鲁克—尕海南山一线;阿木尼克—都兰阿拉格尔泰山一线	0.0	425.0	172.0	城墙沟、石灰沟
上泥盆统	牦牛山组	碎屑岩相	欧龙布鲁克—乌兰牦牛山一线;阿木尼克山—夏日哈山一线	0.0	>3 000	2 650.0	夏日哈、牦牛山、城墙沟
上泥盆统	牦牛山组	火山岩相	怀头他拉—尕海南山点状出露;都兰关角牙点状出露	71.0	1 360.0	552.0	尕海南山、关角牙

统	组	岩性	地点	最小厚度/m	最大厚度/m	平均厚度/m	典型剖面
下石炭统	怀头他拉组	变质岩-火山岩相	宗务隆山以北	170.0	350.0	261.0	关角日吉、天峻南
	怀头他拉组	碳酸盐相	欧龙布鲁克—阿木尼克—阿拉格尔泰山一线广大地区	86.9	763.0	525.0	怀头他拉水库、柴页2、石灰沟、城墙沟、埃北1、夏日哈、关角牙
	城墙沟组	变质岩相	宗务隆山以北	22.0	164.0	98.0	宗务隆北坡、吉给申沟
	城墙沟组	碎屑岩-碳酸盐混积相	欧龙布鲁克—尕海南山一线;阿木尼克—都兰阿拉格尔泰山一线	0.0	425.0	172.0	城墙沟、石灰沟
上泥盆统	牦牛山组	碎屑岩相	欧龙布鲁克—乌兰牦牛山一线;阿木尼克山—夏日哈山一线	0.0	>3 000	2 650.0	夏日哈、牦牛山、城墙沟
上泥盆统	牦牛山组	火山岩相	怀头他拉—尕海南山点状出露;都兰关角牙点状出露	71.0	1 360.0	552.0	尕海南山、关角牙