TY - JOUR
T1 - A crustal radially anisotropic shear-wave velocity model of Northwestern Australia
AU - Li, Tingzi
AU - Zhao, Liang
AU - Zhao, Rijin
AU - Murdie, Ruth E.
AU - Gessner, Klaus
AU - Xu, Xiaobing
AU - Wang, Kun
AU - Wan, Bo
AU - Ventosa, Sergi
AU - Yuan, Huaiyu
N1 - Publisher Copyright:
© 2024 Elsevier B.V.
PY - 2024/8/15
Y1 - 2024/8/15
N2 - The aim of this study is to investigate the crustal architecture of northwestern Australia during the Precambrian, encompassing the Pilbara Craton, the Canning Basin, and the Kimberley Craton. This region played a pivotal role in the formation of proto-Australia during the Proterozoic. However, the exact mechanisms and locations of assembly beneath the thick Phanerozoic Canning Basin remain heavily debated due to insufficient detailed regional crustal structural information. By developing a radially anisotropic shear wave velocity model of the regional crust, we directly visualize the deformation fabrics of the entire crust, which can be correlated with seismic anisotropy. Through spatial correlation with surface geology, we deduce potential ancient deformation scenarios unique to each crustal domain. Our new anisotropy model, characterized by rapidly changing and spatially distinct anisotropy patterns, reveals several significant findings. Subvertical deformation is associated with the northeast margin of the exposed Pilbara Craton and the western margin of the Kimberley basement, indicating collisional deformation in these Archean crustal segments. Strong horizontal deformation is inferred east of the Fenton fault in the Canning Basin, aligning with the multiple stages of extensional processes that formed the basin. This extensional signal extends into the west Lamboo Province of the Kimberley Craton. In the western Canning Basin, the Percival Lake Province, identified by its distinctive seismic, age, and isotopic characteristics in recent studies, lacks a clear extensional signal. Instead, two sub-crustal domains are favored, exhibiting opposing deformation fabrics. The newly revealed regional anisotropic architecture provides insights into the complex amalgamation processes between the Pilbara and Kimberley Cratons, as well as significant basin deformations following cratonization. Our study demonstrates that radial anisotropy offers direct lithospheric constraints, enhancing our understanding of the formation and evolution of Precambrian continents in concealed regions.
AB - The aim of this study is to investigate the crustal architecture of northwestern Australia during the Precambrian, encompassing the Pilbara Craton, the Canning Basin, and the Kimberley Craton. This region played a pivotal role in the formation of proto-Australia during the Proterozoic. However, the exact mechanisms and locations of assembly beneath the thick Phanerozoic Canning Basin remain heavily debated due to insufficient detailed regional crustal structural information. By developing a radially anisotropic shear wave velocity model of the regional crust, we directly visualize the deformation fabrics of the entire crust, which can be correlated with seismic anisotropy. Through spatial correlation with surface geology, we deduce potential ancient deformation scenarios unique to each crustal domain. Our new anisotropy model, characterized by rapidly changing and spatially distinct anisotropy patterns, reveals several significant findings. Subvertical deformation is associated with the northeast margin of the exposed Pilbara Craton and the western margin of the Kimberley basement, indicating collisional deformation in these Archean crustal segments. Strong horizontal deformation is inferred east of the Fenton fault in the Canning Basin, aligning with the multiple stages of extensional processes that formed the basin. This extensional signal extends into the west Lamboo Province of the Kimberley Craton. In the western Canning Basin, the Percival Lake Province, identified by its distinctive seismic, age, and isotopic characteristics in recent studies, lacks a clear extensional signal. Instead, two sub-crustal domains are favored, exhibiting opposing deformation fabrics. The newly revealed regional anisotropic architecture provides insights into the complex amalgamation processes between the Pilbara and Kimberley Cratons, as well as significant basin deformations following cratonization. Our study demonstrates that radial anisotropy offers direct lithospheric constraints, enhancing our understanding of the formation and evolution of Precambrian continents in concealed regions.
KW - Ambient noise tomography
KW - Crustal structures
KW - Precambrian Craton amalgamation
KW - Radial Anisotropy
KW - The Canning Basin
KW - The Northwestern Australia
UR - http://www.scopus.com/inward/record.url?scp=85195419691&partnerID=8YFLogxK
U2 - 10.1016/j.precamres.2024.107457
DO - 10.1016/j.precamres.2024.107457
M3 - Article
AN - SCOPUS:85195419691
SN - 0301-9268
VL - 410
JO - Precambrian Research
JF - Precambrian Research
M1 - 107457
ER -