RT Journal Article
SR Electronic
T1 Determination of an intracontinental transform system along the southern Central Asian orogenic belt in the latest Paleozoic
JF American Journal of Science
JO Am J Sci
FD American Journal of Science
SP 851
OP 897
DO 10.2475/07.2022.01
VO 322
IS 7
A1 Zhang, Jin
A1 Qu, Junfeng
A1 Zhang, Beihang
A1 Zhao, Heng
A1 Zheng, Ronggou
A1 Liu, Jianfeng
A1 Hui, Jie
A1 Niu, Pengfei
A1 Yun, Long
A1 Zhao, Shuo
A1 Zhang, Yiping
YR 2022
UL http://www.ajsonline.org/content/322/7/851.abstract
AB Intracontinental transform structures are important forms of continental deformation, such as the Altyn Tagh fault on Tibetan Plateau. Although many intracontinental transform structures have developed throughout geological history, their identification is relatively difficult due to later deformation and sedimentary covering. Strike-slip faults played an important role in the formation and subsequent transformation of the Central Asian orogenic belt (CAOB). In this study, a group of nearly EW-trending dextral shear zones along the southern CAOB in the Beishan, Alxa, northern margin of the North China Craton and the Great Xing'an Mountains to the east, is reported. Regional strike-slip duplex systems were developed and strongly superimposed on the CAOB in the Beishan and Alxa regions. Meanwhile, to the west of the Beishan, coeval ductile shear zones with the same kinematics also developed along the CAOB. The ages of the shear zones range from 280 Ma to 230 Ma and become younger to the east. This megashear system may also connect with the shortening in the Ural Orogenic belt to the west and the convergence along the eastern margin of the Eurasian continent, which is approximately more than 9000 km long in the Asian continent and consists of an intracontinental transform structure in the central Pangea continent. Further west, the dextral shear system may also connect with the coeval shear zones with the same kinematics along the southern Variscan orogenic belt in Europe and even the South Appalachian Orogenic Belt in the southeastern North America, which we call the Intra-Pangean Megashear (IPM) after Irving (2004). The rotation and approach of the Baltic Craton and Siberian Craton and the northern Pangean lithosphere heated by mantle plumes and its lat.eral (eastward) spreading may have caused the development of the IPM and intracontinental deformation from Pangea B to Pangea A.