Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard
The 900-km-long right-slip Red River fault of southernmost China and northern Vietnam is a profound structural discontinuity that is mechanically associated with the collision of the Indian and Eurasian plates. Although history records no large earthquakes resulting from slippage along at least the...
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sg-ntu-dr.10356-949452020-03-07T12:45:24Z Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard Yuan, Han Sieh, Kerry Zhang, Buchun Zhu, Chengnan Gillespie, A. R. Allen, Clarence R. DRNTU::Science::Geology::Volcanoes and earthquakes The 900-km-long right-slip Red River fault of southernmost China and northern Vietnam is a profound structural discontinuity that is mechanically associated with the collision of the Indian and Eurasian plates. Although history records no large earthquakes resulting from slippage along at least the principal segment of the fault in China, youthful landforms and disruptions of young sedimentary rocks indicate that it has generated large earthquakes during the Pleistocene and Holocene epochs. The historic quiescence thus must be regarded as being indicative of a current seismic gap, although the recurrence interval between major earthquakes is evidently much longer than for many other major active fault systems. That recent displacement has been primarily right lateral is indicated by consistently displaced drainages, ranging in offset from 9 m to 6 km, and the freshness of the smallest and most recent offsets implies repeated Holocene movements. Although physiographic features typical of active faulting such as scarps and drainage diversions are present throughout, the general absence of sag ponds reflects both the high rate of dissection of the fault by the Red River and its tributaries and the lower degree of activity as compared to highly active faults such as the San Andreas fault of California. In its middle 170 km, the fault zone is made up of two branches. The range-front branch demarcates the northeastern base of the Ailao Mountains and, at least locally, has an appreciable component of dip slip. The mid-valley branch, in large part previously unrecognized, traverses principally deeply dissected Cenozoic valley fill northeast of the range-front fault and has undergone almost pure lateral slip. Lateral postfill offsets along the range-front branch diminish toward the southeast, whereas those along the mid-valley branch diminish northwestward; the net effect is that the total postfill offset across both branches is almost uniform. The Red River and its major tributaries appear to have experienced about 5.5 km of right slip since the beginning of a major episode of incision that continues to the present day. Restoration of this offset provides a remarkable alignment of most large tributaries as well as removing a major kink in the course of the Red River itself. Using maximum credible rates of incision, we estimate an average fault-slip rate of 2 to perhaps 5 mm/yr. At this long-term rate of slip, the smallest offsets observed along the fault (9 m) would occur no more frequently than every 1,800 to 4,500 yr on the average. This is consistent with the historical record of fault dormancy for the past 300 yr. North of the Red River fault, there is a large seismically active region laced with numerous faults of north and northwesterly trends. Several of these faults display clear and even spectacular evidence of youthful normal faulting, and some appear to have left-lateral components as well. These faults, as well as the Red River fault itself, are accommodating regional east-west crustal extension and north-south shortening. 2013-03-11T07:53:07Z 2019-12-06T19:05:09Z 2013-03-11T07:53:07Z 2019-12-06T19:05:09Z 1984 1984 Journal Article Allen, C. R., Gillespie, A. R., Yuan, H., Sieh, K., Zhang, B., & Zhu, C. (1984). Red River and associated faults, Yunnan Province, China: Quaternary geology, slip rates, and seismic hazard. Geological Society of America Bulletin, 95(6), 686-700. 0016-7606 https://hdl.handle.net/10356/94945 http://hdl.handle.net/10220/9374 10.1130/0016-7606(1984)95<686:RRAAFY>2.0.CO;2 en Geological society of America bulletin © 1984 Geological Society of America |
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DRNTU::Science::Geology::Volcanoes and earthquakes Yuan, Han Sieh, Kerry Zhang, Buchun Zhu, Chengnan Gillespie, A. R. Allen, Clarence R. Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard |
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The 900-km-long right-slip Red River fault of southernmost China and northern Vietnam is a profound structural discontinuity that is mechanically associated with the collision of the Indian and Eurasian plates. Although history records no large earthquakes resulting from slippage along at least the principal segment of the fault in China, youthful landforms and disruptions of young sedimentary rocks indicate that it has generated large earthquakes during the Pleistocene and Holocene epochs. The historic quiescence thus must be regarded as being indicative of a current seismic gap, although the recurrence interval between major earthquakes is evidently much longer than for many other major active fault systems.
That recent displacement has been primarily right lateral is indicated by consistently displaced drainages, ranging in offset from 9 m to 6 km, and the freshness of the smallest and most recent offsets implies repeated Holocene movements. Although physiographic features typical of active faulting such as scarps and drainage diversions are present throughout, the general absence of sag ponds reflects both the high rate of dissection of the fault by the Red River and its tributaries and the lower degree of activity as compared to highly active faults such as the San Andreas fault of California.
In its middle 170 km, the fault zone is made up of two branches. The range-front branch demarcates the northeastern base of the Ailao Mountains and, at least locally, has an appreciable component of dip slip. The mid-valley branch, in large part previously unrecognized, traverses principally deeply dissected Cenozoic valley fill northeast of the range-front fault and has undergone almost pure lateral slip. Lateral postfill offsets along the range-front branch diminish toward the southeast, whereas those along the mid-valley branch diminish northwestward; the net effect is that the total postfill offset across both branches is almost uniform.
The Red River and its major tributaries appear to have experienced about 5.5 km of right slip since the beginning of a major episode of incision that continues to the present day. Restoration of this offset provides a remarkable alignment of most large tributaries as well as removing a major kink in the course of the Red River itself. Using maximum credible rates of incision, we estimate an average fault-slip rate of 2 to perhaps 5 mm/yr. At this long-term rate of slip, the smallest offsets observed along the fault (9 m) would occur no more frequently than every 1,800 to 4,500 yr on the average. This is consistent with the historical record of fault dormancy for the past 300 yr.
North of the Red River fault, there is a large seismically active region laced with numerous faults of north and northwesterly trends. Several of these faults display clear and even spectacular evidence of youthful normal faulting, and some appear to have left-lateral components as well. These faults, as well as the Red River fault itself, are accommodating regional east-west crustal extension and north-south shortening. |
format |
Article |
author |
Yuan, Han Sieh, Kerry Zhang, Buchun Zhu, Chengnan Gillespie, A. R. Allen, Clarence R. |
author_facet |
Yuan, Han Sieh, Kerry Zhang, Buchun Zhu, Chengnan Gillespie, A. R. Allen, Clarence R. |
author_sort |
Yuan, Han |
title |
Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard |
title_short |
Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard |
title_full |
Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard |
title_fullStr |
Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard |
title_full_unstemmed |
Red river and associated faults, Yunnan Province, China : quaternary geology, slip rates, and seismic hazard |
title_sort |
red river and associated faults, yunnan province, china : quaternary geology, slip rates, and seismic hazard |
publishDate |
2013 |
url |
https://hdl.handle.net/10356/94945 http://hdl.handle.net/10220/9374 |
_version_ |
1681039196507078656 |