Isolating active orogenic wedge deformation in the southern Subandes of Bolivia

详细信息    查看全文

• 作者：Jonathan R. Weiss ; Benjamin A. Brooks ; James H. Foster ; Michael Bevis ; Arturo Echalar ; Dana Caccamise ; Jacob Heck ; Eric Kendrick ; Kevin Ahlgren ; David Raleigh ; et al
• 刊名：Journal of Geophysical Research: Solid Earth
• 出版年：2016
• 出版时间：August 2016
• 年：2016
• 卷：121
• 期：8
• 页码：6192-6218
• 全文大小：12.8MB
• ISSN：2169-9356

文摘

A new GPS-derived surface velocity field for the central Andean backarc permits an assessment of orogenic wedge deformation across the southern Subandes of Bolivia, where recent studies suggest that great earthquakes (>M_w 8) are possible. We find that the backarc is not isolated from the main plate boundary seismic cycle. Rather, signals from subduction zone earthquakes contaminate the velocity field at distances greater than 800 km from the Chile trench. Two new wedge-crossing velocity profiles, corrected for seasonal and earthquake affects, reveal distinct regions that reflect (1) locking of the main plate boundary across the high Andes, (2) the location of and loading rate at the back of orogenic wedge, and (3) an east flank velocity gradient indicative of décollement locking beneath the Subandes. Modeling of the Subandean portions of the profiles indicates along-strike variations in the décollement locked width (W_L) and wedge loading rate; the northern wedge décollement has a W_L of ~100 km while accumulating slip at a rate of ~14 mm/yr, whereas the southern wedge has a W_L of ~61 km and a slip rate of ~7 mm/yr. When compared to Quaternary estimates of geologic shortening and evidence for Holocene internal wedge deformation, the new GPS-derived wedge loading rates may indicate that the southern wedge is experiencing a phase of thickening via reactivation of preexisting internal structures. In contrast, we suspect that the northern wedge is undergoing an accretion or widening phase primarily via slip on relatively young thrust-front faults.