PALEOSEISMOLOGIC STUDY ON THE YUEXI FAULT IN THE MIDSECTION OF THE DALIANGSHAN FAULT ZONE SINCE THE LATE QUATERNARY

doi:10.3969/j.issn.0253-4967.2023.02.002

Abstract

Abstract:

The Xianshuihe-Xiaojiang fault system(XXFS)is a strongly active left-lateral strike-slip fault zone on the eastern edge of the Qinghai-Tibetan plateau. It controls the eastern boundary of the Sichuan-Yunnan block, Which is one of the most active tectonic zones in the north-south seismic belts. There have been 36 destructive earthquakes since 1327AD. The historical strong earthquakes in the middle section of the XXFS fault system are mainly distributed along Anning River faults and Zemu River faults, such as M7.0 in 814AD, M7^1/2 in 1536AD, M6^3/4 in 1732AD, M7^1/2 in 1850AD and M6^3/4 earthquakes in 1952AD. However, as an important part of the middle of XXFS, the Daliangshan fault zone only recorded a magnitude of M5^1/2 in 1480AD, and there was a lack of earthquake records above a magnitude of 6 which may be due to the quiet period of earthquakes, or the location of remote mountainous areas where historical records are missing. The paleoseismic study revealed that there were surface rupture events along the Butuo and Jiaojihe faults in the southern section of the Daliangshan fault zone in 970-1510AD and 1310-1660AD respectively, with a magnitude of not less than 6.5; Along the Puxiong fault in the middle section of the Daliangshan fault zone, there was a surface rupture event in 927-1360AD, with a magnitude of not less than 7.0. However, there are no corresponding historical records of the earthquakes in these three historical periods, indicating that strong historic earthquakes in the Daliangshan fault zone may be missing.

The Yuexi fault is the only branch fault in the Daliangshan fault zone dominated by thrust slip. The fault spreads in an arc shape, with a total length of about 50km, and controls the quaternary basins such as Zhenxi, Xinmin, and Yuexi. The topographic height difference between the fault’s two sides is about 2 000m. The middle section of the fault is the eastern boundary fault of the Yuexi Basin, which cuts through the piedmont alluvial fan, forming fault scarps several meters to tens of meters high. Together with the Puxiong fault on the east side, which is dominated by left laterally slipping, a positive flower-type structure is formed in the middle section of the Daliangshan fault zone. There are previous discoveries about fault scarps of the Yuexi fault on the piedmont alluvial fans, but no paleoseismic research has been reported up to now.

On the basis of remote sensing interpretation and field geological and geomorphological survey of the Yuexi fault, a big trench was excavated across the 12m-high fault scarp on the late quaternary alluvial fan in the Yuexi Basin, which revealed four paleoseismic events since the late quaternary and the coseismic vertical slip of the last one is ~1.2m. Based on trench analysis, 14 stratigraphic units are defined from which carbon samples are acquired for geochronological analysis. Through radioactive carbon dating and correction of the dating data by the OxCal software, and OxCal model building to limit the age of paleoearthquake events, the ages of the four events were 25260-23880BC, 23930-23500BC, 20980-1400BC, and 270-1500AD. According to historical records, a destructive earthquake occurred in Yuexi County on September 13, 1480AD, which triggered landslides, 7 earthquakes on that day, and more than 20 aftershocks as of the 27th, with a tremor range of 150km. We consider that the latest event should be the Yuexi earthquake in 1480AD according to the historical records of earthquake damages. Based on the paleoearthquake research, this event very likely led to a coseismic rupture of the Yuexi and the Puxiong faults. According to the empirical scaling laws between magnitude and rupture length, the magnitude of the surface ruptured paleoearthquake is estimated to be more than M7.0. The results provide basic data for evaluating seismic activity and analyzing seismic risk in this area.

Key words: the Daliangshan fault zone, the Yuexi fault, Late Quaternary, Paleoearthquake

摘要：

越西断裂是青藏高原东缘大凉山断裂带中唯一一条以逆冲作用为主的分支断裂。该断裂控制了越西第四纪盆地, 断层2盘有2 000m的地形高差, 与其东侧以左旋走滑错动为主的普雄断裂构成了大凉山断裂带中段的正花状构造。前人发现了越西断裂在山前洪积扇上形成的断层陡坎, 但目前尚没有相关古地震的研究报道。文中在断错地貌调查的基础上, 通过槽探与放射性碳年代测定等方法揭露了越西断裂晚第四纪以来的4次古地震事件, 年代分别是25260-23880BC、23930-23500BC、20980-1400BC、1270-1500AD, 最新事件可能为1480年越西地震。根据普雄断裂已有的古地震研究结果分析, 这次历史地震可能导致越西断裂与普雄断裂同步破裂。

关键词: 大凉山断裂带, 越西断裂, 晚第四纪, 古地震

CLC Number:

P315.2

LIU Qing, LIU Shao, ZHANG Shi-min. PALEOSEISMOLOGIC STUDY ON THE YUEXI FAULT IN THE MIDSECTION OF THE DALIANGSHAN FAULT ZONE SINCE THE LATE QUATERNARY[J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 321-337.

刘庆, 刘韶, 张世民. 大凉山断裂带中段越西断裂晚第四纪古地震[J]. 地震地质, 2023, 45(2): 321-337.

Figures/Tables 9

Fig. 1 The distribution map of the Daliangshan fault zone.

Fig. 2 The spatial distribution of the Yuexi Fault.

Fig. 3 The faulted landforms near the Huayang village.

Fig. 4 Photo mosaic(a) and interpretation log(b) of the north wall of the Huayang Trench.

Fig. 5 Photo mosaic(a) and interpretation log(b) of the south wall of the Huayang Trench.

Table1 The strata units exposed by the trench

地层单元	地层描述
U1	槽洪相灰褐色含细砂砾石层。砾石直径2~10cm,次棱角状,分选差,层理不发育,其间夹有漫洪相黄褐色及灰褐色发育斜层理的细砂层。
U2-1	槽洪相褐黄色夹紫红色含细砂砾石层。砾石直径多为2~4cm,次棱角状。在探槽北壁,顶部炭屑(DH063)的¹⁴C测年结果为(26 960±120)a BP。
U2-2	黑色夹棕黄色淤泥层。含少量砾石,砾石直径1~3cm。在探槽南壁,顶部有机沉积物(DH096)的¹⁴C测年结果为(25 580±100)a BP。
U3-1	漫洪相褐黄色含砾细砂层。砾石直径2~10cm。
U3-2	漫洪相灰褐色粉砂层。顶部为褐黄色细砂层,发育斜层理。
U4	槽洪相黄褐色含细砂砾石层。砾石直径2~10cm,次棱角状,发育斜层理。在探槽南壁,底部漫洪相夹层中炭粒(DH078)的¹⁴C测年结果为(12 490±40)a BP。
U5	槽洪相灰褐色含细砂砾石层。砾石直径2~10cm,多为次棱角状,发育水平层理,其间夹有漫洪相黄褐色及灰褐色发育近水平层理的细砂层。在探槽南壁,下部漫洪相夹层中炭粒(DH102)的¹⁴C测年结果为(19 180±60)a BP;在探槽北壁,下部漫洪相夹层中炭屑(DH083)的¹⁴C测年结果为(22 890±90)a BP。
C1-1	崩积楔,砾石与砂土混杂,无分选,无层理。
C1-2	漫洪相灰褐色含黏土细砂层。含少量砾石,砾石直径2~4cm,多为次棱角状。在探槽南壁上部炭屑(DH026)的¹⁴C测年结果为(21 410±70)a BP;在探槽北壁,下部炭粒(DH029)的¹⁴C测年结果为(24 180±70)a BP。
U6-1	槽洪相灰褐色含砂砾石层,砾石直径2~20cm,多为次棱角状。
U6-2	漫洪相黄褐色细砂层。含少量砾石,砾石直径2~4cm,多为次棱角状,发育水平层理。在探槽北壁,下部炭屑(DH031)的¹⁴C测年结果为(25 110±120)a BP,与水平相变的C1-1地层单元的测年结果基本一致。
U7-1	槽洪相黄褐色含细砂砾石层,砾石直径2~4cm,多为次棱角状,发育斜层理。
U7-2	漫洪相灰褐色细砂层。含少量砾石,砾石直径2~4cm,多为次棱角状,发育水平层理。在探槽南壁,上部炭屑(DH020)的¹⁴C测年结果为(31 860±170)a BP。
U8-1	槽洪相浅灰色夹紫红色含砂砾石层。砾石直径2~15cm,局部最大可达30cm,多为次棱角状,发育近水平层理。
U8-2	漫洪相褐黑色夹深棕黄色淤泥层含少量砾石,砾石直径2~4cm,磨圆差。在探槽北壁,下部有机沉积物(DH045)的¹⁴C测年结果为(25 760±100)a BP。
U9-1	槽洪相浅灰色含细砂砾石层。砾石直径2~6cm,多为次棱角状,发育水平层理,其间夹有漫洪相浅灰黄色发育水平层理的含砾细砂层。
U9-2	漫洪相浅灰黄色含砾细砂层,砾石直径2~4cm,磨圆差,发育水平层理。
C2-1	崩积楔,砾石与砂土混杂,无分选,无层理。
C2-2	漫洪相灰褐色中砂层。含少量砾石,砾石直径1~2cm,发育近水平层理。在探槽南壁,炭屑(DH024)的¹⁴C测年结果为(21 300±70)a BP;在探槽北壁,炭屑(DH023)的¹⁴C测年结果为(20 990±80)a BP。
C2-3	坡积相红褐色含砾细砂层,砾石直径2~4cm,次棱角状。
C2-4	灰黑色古土壤层。含少量砾石,砾石直径2~4cm。在探槽南壁,靠近断层炭屑(DH018)的¹⁴C测年结果为(21 510±80)a BP;远离断层崩积楔坡脚上部有机沉积物(DH028)的¹⁴C测年结果为(1 970±30)a BP,其年龄明显偏年轻,层位靠近现代耕作层底部,受到后期污染;在探槽北壁,靠近断层炭屑(DH017)的¹⁴C测年结果为(19 080±80)a BP,远离断层的崩积楔坡脚上部有机沉积物(DH037)的¹⁴C测年结果为(2 020±30)a BP,其年龄明显较年轻,可能由于近地表,受到后期污染。
C3-1	崩积楔,砾石与砂土混杂,无分选,无层理。
C3-2	漫洪相灰褐色细砂层。含少量砾石,砾石直径2~4cm,发育近水平层理,近断层处发生拖曳变形。在探槽南壁,中部炭屑(DH016)的¹⁴C测年结果为(3 040±30)a BP;在探槽北壁,炭屑(DH013)的¹⁴C测年结果为(20 480±70)a BP。
C3-3	坡积相红褐色细砂层,含少量砾石,砾石直径2~4cm,次棱角状。
C3-4	灰黑色含砾古土壤。砾石直径4~8cm,局部最大可达25cm。在探槽南壁,下部有机沉积物(DH006)的¹⁴C测年结果为(1 280±30)a BP;在探槽北壁,下部有机沉积物(DH001)的¹⁴C测年结果为(1 340±30)a BP。
U10-1	槽洪相棕黄色夹紫红色含细砂砾石层。砾石直径2~12cm,局部最大可达35cm,多为次棱角状,水平层理不发育。
U10-2	灰黑色土壤化粉细砂层。顶部砾石近水平排列,砾石直径2~5cm,多为次棱角状。在探槽南壁下部获得的有机沉积物(DH032)的¹⁴C测年结果为(760±30)a BP;在探槽北壁下部获得的有机沉积物(DH041)的¹⁴C测年结果为(790±30)a BP。
U11	现代耕作层。灰黑色含砾砂土层,结构松散,砾石直径2~9cm,磨圆差。

Table1 The strata units exposed by the trench

地层单元	地层描述
U1	槽洪相灰褐色含细砂砾石层。砾石直径2~10cm,次棱角状,分选差,层理不发育,其间夹有漫洪相黄褐色及灰褐色发育斜层理的细砂层。
U2-1	槽洪相褐黄色夹紫红色含细砂砾石层。砾石直径多为2~4cm,次棱角状。在探槽北壁,顶部炭屑(DH063)的¹⁴C测年结果为(26 960±120)a BP。
U2-2	黑色夹棕黄色淤泥层。含少量砾石,砾石直径1~3cm。在探槽南壁,顶部有机沉积物(DH096)的¹⁴C测年结果为(25 580±100)a BP。
U3-1	漫洪相褐黄色含砾细砂层。砾石直径2~10cm。
U3-2	漫洪相灰褐色粉砂层。顶部为褐黄色细砂层,发育斜层理。
U4	槽洪相黄褐色含细砂砾石层。砾石直径2~10cm,次棱角状,发育斜层理。在探槽南壁,底部漫洪相夹层中炭粒(DH078)的¹⁴C测年结果为(12 490±40)a BP。
U5	槽洪相灰褐色含细砂砾石层。砾石直径2~10cm,多为次棱角状,发育水平层理,其间夹有漫洪相黄褐色及灰褐色发育近水平层理的细砂层。在探槽南壁,下部漫洪相夹层中炭粒(DH102)的¹⁴C测年结果为(19 180±60)a BP;在探槽北壁,下部漫洪相夹层中炭屑(DH083)的¹⁴C测年结果为(22 890±90)a BP。
C1-1	崩积楔,砾石与砂土混杂,无分选,无层理。
C1-2	漫洪相灰褐色含黏土细砂层。含少量砾石,砾石直径2~4cm,多为次棱角状。在探槽南壁上部炭屑(DH026)的¹⁴C测年结果为(21 410±70)a BP;在探槽北壁,下部炭粒(DH029)的¹⁴C测年结果为(24 180±70)a BP。
U6-1	槽洪相灰褐色含砂砾石层,砾石直径2~20cm,多为次棱角状。
U6-2	漫洪相黄褐色细砂层。含少量砾石,砾石直径2~4cm,多为次棱角状,发育水平层理。在探槽北壁,下部炭屑(DH031)的¹⁴C测年结果为(25 110±120)a BP,与水平相变的C1-1地层单元的测年结果基本一致。
U7-1	槽洪相黄褐色含细砂砾石层,砾石直径2~4cm,多为次棱角状,发育斜层理。
U7-2	漫洪相灰褐色细砂层。含少量砾石,砾石直径2~4cm,多为次棱角状,发育水平层理。在探槽南壁,上部炭屑(DH020)的¹⁴C测年结果为(31 860±170)a BP。
U8-1	槽洪相浅灰色夹紫红色含砂砾石层。砾石直径2~15cm,局部最大可达30cm,多为次棱角状,发育近水平层理。
U8-2	漫洪相褐黑色夹深棕黄色淤泥层含少量砾石,砾石直径2~4cm,磨圆差。在探槽北壁,下部有机沉积物(DH045)的¹⁴C测年结果为(25 760±100)a BP。
U9-1	槽洪相浅灰色含细砂砾石层。砾石直径2~6cm,多为次棱角状,发育水平层理,其间夹有漫洪相浅灰黄色发育水平层理的含砾细砂层。
U9-2	漫洪相浅灰黄色含砾细砂层,砾石直径2~4cm,磨圆差,发育水平层理。
C2-1	崩积楔,砾石与砂土混杂,无分选,无层理。
C2-2	漫洪相灰褐色中砂层。含少量砾石,砾石直径1~2cm,发育近水平层理。在探槽南壁,炭屑(DH024)的¹⁴C测年结果为(21 300±70)a BP;在探槽北壁,炭屑(DH023)的¹⁴C测年结果为(20 990±80)a BP。
C2-3	坡积相红褐色含砾细砂层,砾石直径2~4cm,次棱角状。
C2-4	灰黑色古土壤层。含少量砾石,砾石直径2~4cm。在探槽南壁,靠近断层炭屑(DH018)的¹⁴C测年结果为(21 510±80)a BP;远离断层崩积楔坡脚上部有机沉积物(DH028)的¹⁴C测年结果为(1 970±30)a BP,其年龄明显偏年轻,层位靠近现代耕作层底部,受到后期污染;在探槽北壁,靠近断层炭屑(DH017)的¹⁴C测年结果为(19 080±80)a BP,远离断层的崩积楔坡脚上部有机沉积物(DH037)的¹⁴C测年结果为(2 020±30)a BP,其年龄明显较年轻,可能由于近地表,受到后期污染。
C3-1	崩积楔,砾石与砂土混杂,无分选,无层理。
C3-2	漫洪相灰褐色细砂层。含少量砾石,砾石直径2~4cm,发育近水平层理,近断层处发生拖曳变形。在探槽南壁,中部炭屑(DH016)的¹⁴C测年结果为(3 040±30)a BP;在探槽北壁,炭屑(DH013)的¹⁴C测年结果为(20 480±70)a BP。
C3-3	坡积相红褐色细砂层,含少量砾石,砾石直径2~4cm,次棱角状。
C3-4	灰黑色含砾古土壤。砾石直径4~8cm,局部最大可达25cm。在探槽南壁,下部有机沉积物(DH006)的¹⁴C测年结果为(1 280±30)a BP;在探槽北壁,下部有机沉积物(DH001)的¹⁴C测年结果为(1 340±30)a BP。
U10-1	槽洪相棕黄色夹紫红色含细砂砾石层。砾石直径2~12cm,局部最大可达35cm,多为次棱角状,水平层理不发育。
U10-2	灰黑色土壤化粉细砂层。顶部砾石近水平排列,砾石直径2~5cm,多为次棱角状。在探槽南壁下部获得的有机沉积物(DH032)的¹⁴C测年结果为(760±30)a BP;在探槽北壁下部获得的有机沉积物(DH041)的¹⁴C测年结果为(790±30)a BP。
U11	现代耕作层。灰黑色含砾砂土层,结构松散,砾石直径2~9cm,磨圆差。

Fig. 6 The detail faults on the trench walls.

Table2 Radiocarbon ages and calibrated calendar dates of samples from the Huayang Trench

地层编号	样品编号	实验室编号	测试成分	初始年代	校正年代(2σ)
U2-1	DH063	603442	炭屑	(26960±120)a BP	29234-29090BC(95.4%)
U2-2	DH096	603432	有机沉积物	(25580±100)a BP	28158-27648BC(95.4%)
U4	DH078	603433	炭粒	(12490±40)a BP	13198-12229BC(95.4%)
U5	DH102	603431	炭粒	(19810±60)a BP	21301-20988BC(95.4%)
U5	DH083	603443	炭屑	(22890±90)a BP	25492-25184BC(94.7%)
					25592-25563BC(0.7%)
C1-2	DH026	603434	炭屑	(21410±70)a BP	23963-23709BC(95.4%)
C1-2	DH029	603435	炭粒	(24180±90)a BP	26724-26050BC(95.4%)
C2-2	DH023	603436	炭屑	(20990±80)a BP	23668-23175BC(95.4%)
C2-2	DH024	603424	炭屑	(21300±70)a BP	23193-23576BC(86.9%)
					23540-23393BC(8.6%)
C2-4	DH028	603426	有机沉积物	(1970±30)a BP	1BC-124AD(83.6%)
					41-9BC(11.9%)
C2-4	DH017	603437	炭屑	(19080±60)a BP	21662-20954BC(95.4%)
C2-4	DH018	603425	炭屑	(21510±80)a BP	24012-23765BC(95.4%)
C2-4	DH037	603438	有机沉积物	(2020±30)a BP	58BC-78AD(89.6%)
					98-70BC(5.4%)
					102-106AD(0.4%)
C3-2	DH016	603427	炭屑	(3040±30)a BP	1401-1216BC(95.4%)
C3-2	DH013	603439	炭屑	(20480±70)a BP	22981-22357BC(95.4%)
C3-4	DH006	603428	有机沉积物	(1280±30)a BP	662-777AD(90.8%)
					791-821AD(47%)
C3-4	DH001	603440	有机沉积物	(1340±30)a BP	656-775AD(95.4%)
U6-2	DH031	603444	炭屑	(25110±120)a BP	27874-27173BC(95.4%)
U7-2	DH020	603423	炭屑	(31860±170)a BP	34666-33820BC(95.4%)
U8-2	DH045	603445	有机沉积物	(25760±100)a BP	28264-27957BC(95.4%)
U10-2	DH032	603429	有机沉积物	(760±30)a BP	1222-1285AD(95.4%)
U10-2	DH041	603441	有机沉积物	(790±30)a BP	1215-1280AD(95.4%)
U11	DH002	603430	有机沉积物	(101.25±0.38)PMC

Fig. 7 Results of OxCal analysis of radiocarbon dates from the trench.

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