Transpressional structure and its control on development of Yinchangping dolomite karst system in Lushui City, Yunnan
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摘要:
银厂坪岩溶系统由溶蚀洼地和溶洞系统组成,溶蚀洼地内发育15个规模和形态不同的落水洞以及多条溶沟。根据断层面擦痕反演构造应力张量和共轭剪节理反映的应力场特征, 结合区域地质背景,认为研究区于始新世—早中新世主要受 SEE-NWW 向挤压和 NNE-SSW 向拉张应力场控制,形成 NW 向左旋压扭性构造,其几何学和运动学特征符合里德尔剪切模式。走滑拉分阶区所形成凹陷具有汇水功能,利于岩溶作用形成溶蚀洼地,内部发育的共轭节理交汇部位是良好的导水构造,叠加在走滑微拉分阶区内,促进白云岩溶蚀作用形成落水洞。地下岩层受构造挤压发生层间滑动形成微裂隙,经溶蚀扩大,形成顺倾斜岩层发育的岩溶洞穴。左行走滑断裂造成地表河流和山脊发生系统左旋位错,发育断层崖于山脚处形成倒石堆,在构造抬升和剥蚀作用下,岩壁不断后退,地下河频繁袭夺使早期溶洞成为干洞,现代地下河于斜坡下游通过地下河出口转为明流。 Abstract:In this study, we conducted a detailed geological and geomorphological survey into the Yinchangping karst system in the dolomite strata of the Shazipo Formation of the middle-upper Permian in Lushui City, western Yunnan. The Yinchangping karst system consists of karst cave system and karst depression where develop 15 sinkholes and many karst trenches with different size and shape. The results of the inversion of the structural stress tensor from the striation on the fault plane and the characteristics of the stress field reflected by the conjugate shear joint as well as the regional geological background, show that the study area is mainly controlled by SEE-NWW compression and NNE-SSW tension stress field during the eocene-early Miocene, forming a NW-direction(N330°)left transpressional structural system,the geometry and kinematic characteristics of which conform to the Riddle shear mode. The depression with the function of water catchment, formed by the NW-direction(N330°)left transpressional structural fault is conductive to the formation depressions by karstification. The intersection of conjugate joints developing in the dissolution depression is a good water-conducting structure which is superimposed in the strike-slip micro-stretching zone to promote dolomite dissolution to form sinkholes. The underground rock strata compressed by tectonic compression slip between the layers form the micro-cracks which are expanded by dissolution to form karst caves developing along inclined rock strata. The river and ridge are systematically left-lateral offset by the left-lateral strike-slip fault, developing the fault cliff and followed by scree accumulation at the foot of the mountain. Under the effects of structural uplift and denudation, the rock walls continue to retreat, and the early karst caves have transformed into dry caves from the frequent attacks of underground rivers. The modern underground river turns into an open current at the downstream of the slope through the underground river outlet. -
Key words:
- Lushui City /
- dolomite karst system /
- transpressional structure /
- Riddle shear mode /
- genetic mechanism
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图 1 a.中国西部和东南部地貌图,b.滇西构造简图,年龄数据见正文,c.云南泸水市地质图,d.剖面图
Figure 1. a.DEM of western and southeastern China, b.Simplified structural map of the western Yunnan (see the text for chronology data of ductile shear zone), c.Geological map of Lushui City, d.Geological profile
图 2 断层面擦痕反演构造应力张量结果
Figure 2. Results of the inversion of the structural stress tensor from the striation on the fault plane
图 5 银厂坪溶蚀洼地和落水洞野外照片
Figure 5. Field picture of corrosion depression and doline of the Yinchangping
图 6 银厂坪溶蚀洼地内溶沟及其节理发育特征
Figure 6. Features of karst trenches and related joints in the depression of Yinchangping
图 7 银厂坪溶蚀洼地内落水洞和溶沟发育处节理统计分析结果
Figure 7. Statistical analysis results of joints in sinkholes and karst gullies in Yinchangping corrosion depression
图 8 银厂坪溶蚀洼地内干沟切面跌水素描图
Figure 8. Sketch drawing of water fall of dry ditch in Yinchangping corrosion depression
表 1 银厂坪溶蚀洼地内落水洞发育特征
Table 1.
Features of sinkholes in Yinchangping corrosion depression 落水洞编号 描述 平面椭圆长轴方向 主控构造 1 废弃的复合叠加落水洞(长14.6 m,宽6.8 m,深5.1 m) N39° NE向断裂 2 废弃的单体落水洞(长5.2 m,宽5.1 m,深2.2 m) N152° NW向断裂(M) 3 废弃的单体落水洞(长5.4 m,宽4.7 m,深2.3 m) N52° NE向断裂(R′) 4 复合叠加落水洞,被后期发育的落水洞所捕获,后期落水洞仍在汇水(长36.7 m,宽32.6 m,深8.7 m) 早期N160°,晚期N44° 早期受NW向断裂(M)控制,晚期受NE向断裂(R′)控制 5 单体落水洞,现在仍在汇水(长51.2 m,宽47.3 m,深26.9 m) N150° NW向断裂(M) 6 废弃的单体落水洞(长54.7 m,宽36.9 m,深12.2 m) N57° NE向断裂(R′) 7 被风化残积土覆盖,地面上只残留一很小凹坑 8 被风化残积土覆盖,地面上只残留一很小凹坑 这四个落水洞组成一个大的落水洞,受NW向断裂(M)控制,不断发育并捕获周围的落水洞 9 由微小的左行左阶拉分区形成的宽30 cm裂隙,水流汇聚于此并下渗 N151° 10 单体落水洞,现在仍在汇水(长6.3 m,宽5.7 m,深2.4 m) N153° 11 单体落水洞,现在仍在汇水(长5.3 m,宽4.9 m,深2.1 m) N151° 12 废弃的单体落水洞(长3.8 m,宽3.7 m,深1.3 m) N150° NW向断裂(M) 13 单体落水洞,现在仍在汇水,平面上呈点状,无法测量其规模 14 被风化残积土覆盖,地面上只残留一很小凹坑 15 废弃的单体落水洞(长7.4 m,宽6.9 m,深3.1 m) N61° NE向断裂(R′) 
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谭周地. 构造对岩溶的控制意义[J]. 长春地质学院学报, 1978(2): 43-47. 阎长虹, 王玉英, 罗国煜, 等. 压性构造对岩溶发育的控制作用[J]. 地质论评, 2008, 54(3): 343-347. FaulknerT. Tectonic inception in Caledonide marbles[J]. Acta Carsologica, 2006, 35(1): 7-21. SauroF, ZampieriD, FilipponiM. Development of a deep karst system within a transpressional structure of the Dolomites in north-east Italy[J]. Geomorphology, 2013, 184(FEB.15): 51-63. 陈清华, 刘池阳, 王书香, 等. 碳酸盐岩缝洞系统研究现状与展望[J]. 石油与天然气地质, 2002, 23(2):196-202. 艾合买提江·阿不都热和曼, 钟建华, 李阳, 等. 碳酸盐岩裂缝与岩溶作用研究[J]. 地质论评, 2008, 54(4): 485-493. 包亮. 碳酸盐岩裂缝与岩溶的关系分析[J]. 科技视界, 2015(15): 109-109. 黎志豪, 许光泉, 高加林, 等. 淮南地区构造特征及其对岩溶作用的影响[J]. 煤田地质与勘探, 2018, 46(3): 121-126. TîrlăL, VijulieI. Structural-tectonic controls and geomorphology of the karst corridors in alpine limestone ridges: Southern Carpathians,Romania[J].Geomorphology,2013,197:123-136. 董莹, 琚宜文, 张玉修, 等. 北京房山张坊岩溶区节理发育特征及其对岩溶作用的影响[J]. 中国科学院大学学报, 2014, 31(6): 783-790. 蒋玺, 龙克树, 刘纯军, 等. 贵州绥阳双河洞白云岩溶洞群成因研究[J]. 地质论评, 2018, 64(3): 674-684. 祝华龙. 浅析铜陵地区地质构造对岩溶发育的影响[J]. 地下水, 2020, 42(1):48-53. LiuZ, DreybrodtW. Kinetics and rate-limiting mechanisms of dolomite. Science in China Series B: Chemistry, 2011, 44(5): 500-509. LiuZ, YuanD, DreybrodtW. Comparative study of dissolution rate-determining mechanisms of limestone and dolomite. Environmental Geology, 2005, 49(2): 274-279. 唐伟, 曹建华, 杨会, 等. 外源水对碳酸盐侵蚀速率研究:以桂林毛村地下河为例[J]. 地球与环境,2014, 42(2):207-212. KristinaK, DavidD V, RosaM, et al. Current denudation rates in dolostone karst from central Spain: Implications for the formation of unroofed caves[J]. Geomorphology, 2016, 264(1) :1-11. 张远海, 朱德浩. 中国大型岩溶洞穴空间分布及演变规律[J]. 桂林理工大学学报, 2012, 32(1) : 20-28. 袁道先, 蒋勇军, 沈立成, 等. 现代岩溶学[M]. 北京: 科学出版社,2016:73-96. 蒋玺, 龙克树, 刘纯军,等. 贵州绥阳双河洞白云岩溶洞群成因研究[J]. 地质论评, 2018, 64(3): 674-684. 罗鼎, 熊康宁, 王恒松,等. 贵州施秉白云岩喀斯特洞穴特征与成因探究[J]. 黔南民族师范学院学报, 2016, 36(3):95-101. PetraŽ R, JožeČ, BoštjanR. Geological structure of the Divača area and its influence on the speleogenesis and hydrogeology of Kačna jama[J]. Acta Carsologica, 2015, 44(2):153-168. AntonelliniM, NannoniA, VignaB, et al. Structural control on karst water circulation and speleogenesis in a lithological contact zone: The Bossea cave system (Western Alps, Italy)[J]. Geomorphology, 2019, 345:1-21. 云南省地质矿产局. 云南省区域地质志[M]. 北京: 地质出版社, 1990. 杨学俊, 贾小川, 熊昌利, 等. 滇西高黎贡山南段公养河群变质基性火山岩LA-ICP-MS锆石U-Pb年龄及其地质意义[J]. 地质通报, 2012, 31(2-3):264-276. WangE, BurchfielB C. Interpretation of Cenozoic tectonics in the right-lateral accommodation zone between the Ailao Shan shear zone and the eastern Himalayan syntaxis[J]. International Geology Review, 1997, 39(3): 191-219. AkcizS, BurchfielB C, CrowleyJ L, et al. Geometry, kinematics, and regional significance of the Chong Shan shear zone, Eastern Himalayan Syntaxis, Yunnan, China[J]. Geosphere, 2008, 4(1):292-314. WangY, FanW, ZhangY, et al. Kinematics and 40Ar/39Ar geochronology of the Gaoligong and Chongshan shear systems, western Yunnan, China: Implications for early Oligocene tectonic extrusion of SE Asia[J]. Tectonophysics, 2006, 418(3-4):235-254. ZhangB, ZhangJ, ZhongD, et al. Polystage deformation of the Gaoligong metamorphic zone: Structures, 40Ar/39Ar mica ages, and tectonic implications[J]. Journal of Structural Geology, 2012, 37: 1-18. 中国地质学会岩溶地质专业委员会. 岩溶学词典[M]. 北京: 地质出版社, 1988. SustersicF, CarJ, SebelaD. Collector channels and deflector faults[J]. Nase Jame, 2003, 43: 8-22. 王宇. 岩溶高原地下水径流系统垂向分带[J]. 中国岩溶, 2018, 37(1):1-8. -
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