地质力学学报

The genesis and age of karst caves in Xinglong National Geopark, Hebei Province

ZHANG Haoyue, JIANG Qunou, ZHANG Xujiao, WANG Shan

Objective Karst caves, as an essential part of the Earth's Critical Zone, hold significant scientific and scenic value. However, previous studies have largely overlooked the tectonic factors influencing cave formation, and quantitative constraints on the age of cave formation remain scarce. This study aims to investigate the genesis and chronology of the Xinglong Karst Cave in the Taojiatai area of Hebei Province, elucidating the controlling factors and temporal constraints of cave development. Methods A comprehensive investigation of cave morphology, stratigraphic attitude, and tectonic characteristics was conducted, supplemented by mineralogical analysis using X-ray diffraction and geochemical element analysis. The study analyzed the relationship between cave formation and fault activity, while the geochemical composition of red clay deposits inside the cave was compared with external weathering crusts to constrain the formation age of the cave. Results The cave developed within Middle Proterozoic dolomitic limestone containing flint nodules, influenced by two major faults that facilitated differential dissolution along fault planes. The red clay deposits inside the cave share geochemical characteristics with external weathering crusts, indicating an exogenous origin. The enrichment of iron in red stalactites suggests leaching from surface water, further confirming the post-weathering deposition of the red clay. Regional comparisons reveal that the residual red clay outside the cave corresponds to the Tangxian planation period (3.1–3.7 Ma), indicating that the cave must have formed after this period. Conclusion This study provides new insights into the fault-controlled genesis of the Xinglong Karst Cave and establishes a minimum formation age of 3.7 Ma, significantly younger than the Middle Proterozoic age of the host rock. The findings correct the previous misconception that the cave formed during the Proterozoic and highlight the crucial role of tectonic activity in cave development. [ Significance ] This research enhances our understanding of the tectonic control and chronological constraints of karst cave formation, providing valuable references for the study of karst landscapes in other regions.

Formation mechanism and stability analysis of a landslide in altered ophiolite in the upper reaches of Jinsha River: A case study of the Duirongtong landslide

RAN Lina, ZHANG Yongshuang, REN Sanshao, LI Jinqiu

Objective The tectonic suture zone of the Qinghai-Tibet Plateau has a complex rock mass structure and special lithology combination and is thus prone for large landslides. However, many factors influence the formation and evolution of landslides in altered ophiolite. Their formation mechanism is not clear at present, which restricts an effective identification and disaster risk prevention. Methods Taking the Duirongtong (DRT) landslide in the Jinsha River tectonic suture zone as an example, field investigations, UAV mapping, geochronological analysis, ring-shear testing, and numerical simulation were performed to analyze the formation mechanisms of the landslide and evaluate the stability of the landslide deposits. Results The results show that: (1) The DRT landslide is a giant landslide formed in the late Pleistocene. The slope is mainly composed of basic-ultrabasic rocks, and several clay-altered ophiolitic bands are developed, forming a sliding-prone geo-structure. (2) The clay-altered ophiolite has low shear strength under natural conditions, and its shear strength drops sharply when exposed to water. The natural values of c and φ are 67.0 kPa and 20.3°, and the water-saturated values of cohesion(c) and angle of internal friction(φ) are 39.8 kPa and 13.83°. The DRT landslide is currently stable as a whole, but the leading edge of the landslide may experience movement under heavy rainfall. Based on numerical simulation, some preventive recommendations are proposed. Conclusion The study suggests that the formation and evolution of the DRT landslide are controlled by the combination of geological structure and clay-altered rock. [ Significance ] These findings have important implications for the slope stability analysis and disaster prevention in the tectonic suture zone of the Qinghai-Tibet Plateau.

InSAR coseismic deformation field and tectonic implications of the 2023 M_S 5.5 Subei Earthquake, Gansu, China

XIONG Guohua, JI Lingyun, CHEN Yuxin, ZHU Liangyu, LIU Chuanjin, XU Jing, JIANG Fengyun, XU Guobin

Objective On October 24, 2023, an M_S 5.5 earthquake occurred in Subei County, Jiuquan City, Gansu Province. The epicenter was located in the Qilian mountain seismic belt at the northeastern margin of the Qinghai-Tibet Plateau. Understanding the seismogenic mechanism of this earthquake and its relationship with the tectonic stress field is crucial for analyzing the seismic hazard in the region. Methods The InSAR coseismic deformation field of the M_S5.5 earthquake in Subei was obtained using ascending and descending Sentinel-1 SAR data, and the parameters of the seismogenic fault were determined based on a uniform slip model. Subsequently, a distributed slip inversion method was applied to obtain a detailed slip distribution of the seismogenic fault. Furthermore, the earthquake-induced changes in the Coulomb stress and the regional interseismic strain rate were determined. Results The results indicate that the surface deformation values generated by this earthquake reached 12 cm and 9 cm in the ascending and descending InSAR line of sight, respectively. The deformation primarily manifests as surface uplift; the seismogenic fault is a concealed fault located between the Shule Nanshan Fault and the northern margin fault of the Central Qilian, the strike is approximately 166.97°, the dip angle is around 68.69°, and the slip angle is about 110.39°; the fault slip is primarily concentrated within the depth range of 1.2 km to 4.9 km, with a maximum slip of 0.58 m occurring at a depth of approximately 2.56 km; the moment magnitude obtained from the inversion is M_W 5.6, and the coseismic rupture is primarily characterized by thrust motion with a minor component of right-lateral strike-slip. This seismic event resulted in regional Coulomb stress changes between the northern margin fault of the Central Qilian and the Shule Nanshan Fault, as well as in the northern area of the Shule River Fault Zone. Additionally, the regional surface strain rate exhibited a distinct compressive trend before the earthquake, with higher surface strain and maximum shear strain rates observed on the northern side of the seismic zone. Conclusion The continuous accumulation of strain leads to an increased seismic hazard, with historical earthquakes often occurring in gradient zones where strain values transition from high to low. Considering the regional strain distribution characteristics and seismic activity, the seismic hazard in this area remains significant in the future and should not be overlooked. [Significance] The research findings have a certain guiding significance for understanding the tectonic background of the Qilian Block and its seismic hazard.

Characteristics of in-situ stresses and engineering stability analysis on the south section of the Bohai Strait Cross-Sea Corridor project

QIAO Erwei, MA Xiumin, GUO Hualin, Sun Yao, JIANG Jingjie

Objective The Bohai Strait Cross-Sea Corridor is an important maritime traffic project which joins the Liaodong and the Shandong peninsulas. The state of geostress is an important reference for engineering design and construction decision-making. Method In order to better understand the present characteristics of the geostress and the distribution of the tectonic stress field in the southern section of the project, hydraulic fracturing tests were conducted for stress measurements at 0～300 m depth at Beigou Town, southwest Penglai District, Yantai City. Results The analysis of the measured data indicates that the in-situ stress field is controlled by horizontal tectonic stress in the study area, and the horizontal stress values are at an intermediate level compared with those obtained elsewhere in the Northeast−North China Stress Zone; S_H (the maximum horizontal principal stress), S_h (the minimum horizontal principal stress), and S_v (the vertical principal stress) change linearly with the depth of the BGZ borehole; in the depth range of the measurements, the shallow surface stress of the crust is mainly reverse fault type, that is, the relationship of the three principal stresses is S_H>S_h>S_v. The measured S_H average azimuth angle in the borehole, N75.3°E, is in good agreement with the direction of the tectonic stress field of the North China Stress Zone to which the study area belongs; and, it is basically consistent with the direction of the regional tectonic stress field revealed by the focal source mechanism solution and GPS measurement. The Coulomb friction sliding criterion and the measured data are used to preliminarily evaluate the current level of geostress accumulation in the study area and its impact on the engineering stability. It is believed that the overall level of stress accumulation in the region is relatively low, and the crust in the engineering area is currently relatively stable. In addition, based on the comprehensive discrimination criterion of rock burst danger,

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/R_c, the possibility of rock burst in the underground tunnel of the Bohai Strait Cross-Sea Corridor is discussed. Conclusion It is primarily concluded that there is currently no possibility of rock burst in the underground tunnel of the Bohai Strait Cross-Sea Corridor, and the rock surrounding the tunnel is stable. Significance The findings in this paper provide a scientific basis for the optimization of the design and the construction of the Bohai Strait Cross-Sea Corridor. The study also provides basic data for research on active faults, seismogeology, regional dynamics in the survey area, and others.

Analysis of ore-controlling structures of the Shimensi tungsten deposit, Dahutang ore field, northwest Jiangxi Province

CHEN Bailin, GAO Yun

Objective The Dahutang tungsten ore field, located in the nearly EW-trending Jiuling uplift belt in northwestern Jiangxi Province, is a recently discovered area of concentrated, world-class, super-large, hydrothermal polymetallic tungsten deposits. It consists of two large tungsten deposits, namely Shimensi, Kunshan, and three medium-sized tungsten deposits, namely the Shiweidong, Dalingshang, Xin’anli deposits. The large Shimensi tungsten deposit is located in the north of the ore field, and the ore bodies are developed in Neoproterozoic granodiorite and Yanshanian granite. The mineralization is of quartz vein type, disseminated veinlet type, and hydrothermal crypto-explosive breccia type, and the three mineralization types occur regularly around the ore-forming granite mass. The ore bodies in the Shimensi tungsten deposit are obviously controlled by structure, but there is little research. Structure is the important ore-controlling factor. The analysis of ore-controlling structures and the construction of tectonic ore-controlling models can help to reconcile the formation and evolution of ore-forming structures and identify the main ore-controlling factors, which can provide technical support for prospection and prediction. Methods This study conducts a detailed field investigation of the ore-bearing fracture system, analyzes the combination of different types of ore-bearing fractures, explores the ore-forming conditions, and constructs a structural ore-controlling model. Results The research shows that the ore-bearing structure is a multi-directional small fault structure with the main trend being EW, followed by NEE and NWW; all the ore-bearing structures are present in a nearly elliptical distribution with EW-trending long axes. The ore-bearing structures change from the outside to the inside of the ore-forming granite, from those with conjugate dip at medium dip angles to those with sole outward dip at medium dip angles, and those with high dip angles; then hydrothermal crypto-explosion breccia appears in the center of the deposit. Among them, the ore-bearing conjugate shear fractures (with an X-shape in the profile) formed in the magmatic emplacement period little before mineralization in a tectonic stress field with a vertical maximum principal stress and a horizontal intermediate principal stress. The ore-bearing solely outward-dipping fractures with medium or high dip angles were formed as non-conjugate shear fractures and tension-shear fractures in the metallogenic period by hydrothermal crypto-explosion in a tectonic stress field with a vertical maximum principal stress and a horizontal intermediate principal stress. The hydrothermal crypto-explosion center formed in a tectonic stress field with a vertical maximum principal stress and similarly-sized intermediate and minimum principal stresses. Conclusion The ore-controlling structures of the Shimensi tungsten deposit are the emplacement structure of the ore-forming magmatic rock with an almost EW(NWW)-trending long axis and the hydraulic fracturing structure of the post-magmatic ore-forming fluid. The emplacement structure of the ore-forming magmatic rock, which was formed a little earlier and distributed over a larger area, developed mainly in the overlying surrounding rock (Neoproterozoic granodiorite) on the top of the ore-forming granite rock mass. The hydraulic fracturing structure of the post-magmatic ore-forming fluid was formed in the metallogenic period within a narrow distribution area in the upper and overlying surrounding rocks of the ore-forming granite rock mass. The latent explosion and hydraulic fracturing of ore-forming fluid instantly reduced the pressure of the ore-forming fluid, leading to the precipitation of ore-forming materials and the crystallization of valuable minerals, forming the tungsten deposits. The emplacement structure of the granite rock mass and the hydraulic fracturing structure of the ore-forming fluid are the sites of the tungsten ore body and control the development of tungsten ore body. The near EW(NWW)-trend of the mining area belongs to a concealed petro-controlling basement structure. This structure causes the long axis of the ore-forming granite rock mass to extend nearly EW and plays an indirect ore-controlling role. The NWW-trending faults such as F20 are neither the ore-conducting structures, nor the ore-controlling structures. They are ore-breaking, post-mineralization structures, with sinistral movement and normal shear sense. The NNE-trending concealed structure in the ore-field controls the distribution of the ore-forming magmatic rock belts and is a high-level petro-controlling structure. [ Significance ] This research can not only guide the exploration of the deeper and peripheral parts of the deposits—that is, further prospection should first search for concealed ore bodies at depth in the plunging part of the eastern and western ends of the near EW(NWW)-trending ore-forming granite rock body, and then search for other granites and fluid metallogenic systems in the area where the concealed ore-forming granite rock mass develops—but also has a demonstrative effect for studies of ore-controlling structures in similar deposits in southern China, enriching the theory of ore-controlling structures for high-temperature hydrothermal deposits.

Cover Page

2025, 31(2).

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Contents

2025, 31(2): 1-2.

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Special Section Dedicated to the 30^th Anniversary

Analysis of ore-controlling structures of the Shimensi tungsten deposit, Dahutang ore field, northwest Jiangxi Province

CHEN Bailin, GAO Yun

2025, 31(2): 169-196. doi: 10.12090/j.issn.1006-6616.2024106

Abstract (54) HTML (7) PDF (10973KB)(7)

Characteristics of in-situ stresses and engineering stability analysis on the south section of the Bohai Strait Cross-Sea Corridor project

QIAO Erwei, MA Xiumin, GUO Hualin, Sun Yao, JIANG Jingjie

2025, 31(2): 197-210. doi: 10.12090/j.issn.1006-6616.2023169

Abstract (147) HTML (18) PDF (3996KB)(5)

Earthquake-induced fissures and their formation mechanisms in the 2023 M_S 6.2 Jishishan Earthquake

ZHANG Bo, WANG Aiguo, YAO Yunsheng, HE Xiaolong, YAO Saisai, ZHU Junwen, CAI Yimeng

2025, 31(2): 211-222. doi: 10.12090/j.issn.1006-6616.2024114

Abstract (241) HTML (10) PDF (12241KB)(37)

Crustal Stress & Tectonic Stress Field

Static stress triggering of Morocco M 6.9 earthquake on 9 September 2023

WANG Runyan, WAN Yongkui, GUAN Zhaoxuan, HUANG Shaohua, GU Peiyuan, SONG Zeyao, ZHOU Mingyue

2025, 31(2): 223-234. doi: 10.12090/j.issn.1006-6616.2024039

Abstract (66) HTML (7) PDF (3700KB)(5)

Energy Resources Geology

Study on the coupling between the hanging- and foot-wall beds and the gas content of deep coal seams in the Linxing area, eastern margin of the Ordos Basin

HUO Shaowei, FENG Xingqiang, WU Jian, ZHANG Shouren, ZHOU Lei, QIAN Zhuliang, CHAO Weiwei

2025, 31(2): 235-247. doi: 10.12090/j.issn.1006-6616.2024124

Abstract (63) HTML (5) PDF (1696KB)(10)

Factors controlling enrichment and accumulation of Devonian–Carboniferous shale gas in the Yaziluo rift trough in the Yunnan–Guizhou–Guangxi region

WANG Yufang, ZHAI Gangyi, SHI Wanzhong, WANG Jinzhu, ZHANG Jiazheng, KANG Haixia, ZHANG Yunxiao, ZHOU Hui, ZHANG Shuting

2025, 31(2): 248-266. doi: 10.12090/j.issn.1006-6616.2024059

Abstract (25) HTML (5) PDF (9679KB)(2)

Geo-hazards & Engineering Geology

Formation mechanism and stability analysis of a landslide in altered ophiolite in the upper reaches of Jinsha River: A case study of the Duirongtong landslide

RAN Lina, ZHANG Yongshuang, REN Sanshao, LI Jinqiu

2025, 31(2): 267-277. doi: 10.12090/j.issn.1006-6616.2024084

Abstract (65) HTML (15) PDF (3539KB)(6)

Quaternary Geology & Environment

The genesis and age of karst caves in Xinglong National Geopark, Hebei Province

ZHANG Haoyue, JIANG Qunou, ZHANG Xujiao, WANG Shan

2025, 31(2): 278-286. doi: 10.12090/j.issn.1006-6616.2024136

Abstract (194) HTML (15) PDF (6623KB)(4)

Active Tectonics & Earthquake

InSAR coseismic deformation field and tectonic implications of the 2023 M_S 5.5 Subei Earthquake, Gansu, China

XIONG Guohua, JI Lingyun, CHEN Yuxin, ZHU Liangyu, LIU Chuanjin, XU Jing, JIANG Fengyun, XU Guobin

2025, 31(2): 287-300. doi: 10.12090/j.issn.1006-6616.2024127

Abstract (69) HTML (8) PDF (3126KB)(7)

Study on the activity of the Cuona-Woka Fault Zone, Qinghai-Tibet Plateau, and geological safety risks and prevention methods

QIANG Xingang, GUO Changbao, SUN Dongxia, HAN Jian’en, ZHANG Guangze, ZHANG Min, QIU Zhendong, HE Ping

2025, 31(2): 301-312. doi: 10.12090/j.issn.1006-6616.2024093

Abstract (56) HTML (11) PDF (8031KB)(11)

Tectonic stability of the Nanpu sag: Evidence from temporal and spatial characteristics of seismic activity

ZHANG Yang, SHANG Lin, WANG Miao, WU Haitao, DUAN Bin

2025, 31(2): 313-324. doi: 10.12090/j.issn.1006-6616.2024036

Abstract (144) HTML (17) PDF (9184KB)(5)

Fundamental Geology & Regional Geology

Monazite U-Pb age, geochemistry, and genesis of ore-bearing granites in the Zhukeng tungsten deposit, southern Jiangxi Province

GAO Yuan, WANG Ying, WANG Hai, XU Zhe, ZHANG Yong, ZHOU Yu, ZHANG Fangrong, SUN Chao, HE Bin, ZHANG Siyuan, ZHANG Fushen

2025, 31(2): 325-339. doi: 10.12090/j.issn.1006-6616.2024083

Abstract (80) HTML (4) PDF (2901KB)(8)

Research Express

Identification of high-purity quartz raw materials from granites in the Xixia area, east Qinling orogenic belt

HE Chengguang, ZHAI Wenjian, WANG Yanhui, REN Jiande, ZHANG Shiqi, WANG Kun, HUANG Yehao

2025, 31(2): 340-344. doi: 10.12090/j.issn.1006-6616.2025013

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Analysis of historical seismic parameters based on geological hazards from the Xiaonanhai earthquake

doi: 10.12090/j.issn.1006-6616.2025001

[Abstract](0) [PDF 3736KB](0)

Abstract:
[Objective] As the largest historical seismic event in Chongqing region, the Xiaonanhai Earthquake holds significant scientific value for deciphering seismogenic parameters to inform regional seismic hazard assessment and anti-seismic fortification standards. Addressing the critical challenge of observational data scarcity in historical earthquake research. [Methods] A novel methodology for inverting seismic parameters through characteristic earthquake relics has been developed, systematically reconstructing the historical seismic parameters of the Xiaonanhai earthquake.. High-precision remote sensing interpretation and field investigations of seismically induced geo-hazards reveal that the landslide clusters triggered by the Xiaonanhai Earthquake exhibit a dominant near-N-S spatial distribution , consistent with the elliptical major axis direction of historically documented felt areas. [Results] This spatial congruence suggests the NNW-striking Yangtoushan Fault as the seismogenic fault. Detailed remote sensing analyses of landslide orientations, sliding directions, and deposit distributions demonstrate, for the first time, coherent SE-directed motion features across multiple landslide masses, indicating a southeastward coseismic rupture propagation. Comparative analysis with the spatial correlation between geo-hazards and seismogenic structures observed in the Ludian Earthquake, coupled with seismotectonic mechanisms in southeastern Chongqing, further validates the rationality of the derived seismic parameters. [Conclusion] The study innovatively identifies a "karst-tectonic" composite mechanism: Under persistent NW-SE tectonic stress, bead-like karst caves developed along the fault zone or dominant joint directions form natural weakening zones, inducing stress concentrationand ultimately triggering left-lateral strike-slip motion with thrust components. This dual mechanism explains the unique seismic characteristics blending tectonic rupture and karst collapse. [Significance] The proposed "geo-morphodynamic inversion" methodology advances historical earthquake parameter reconstruction and provides critical insights for seismic risk evaluation in karst terrains.

Study on pore structure characteristics and formation mechanism of high quality shale oil reservoirs in Chang 7 Member of Ansai Oilfield

doi: 10.12090/j.issn.1006-6616.2025011

[Abstract](12) [PDF 2913KB](2)

Abstract:
The Yanchang Formation's seventh member in the AnSai Oilfield is a crucial development layer, with the genesis and pore structure of its reservoir playing a significant role in controlling reservoir quality, which in turn has a profound impact on shale oil production. The AnSai Oilfield faces challenges such as a lack of conventional resource potential and considerable difficulty in reserves replacement. Currently, the primary objective for reserve augmentation is the shale oil reservoir; therefore, understanding the pore structure and genesis of different reservoirs is of great importance for the exploration and development of the oilfield. This study focuses on the interbedded shale oil reservoir of the seventh member of the Yanchang Formation in the AnSai Oilfield, located in the Ordos Basin. Through the use of scanning electron microscopy, cast thin sections, low-temperature nitrogen adsorption, high-pressure mercury injection, and nuclear magnetic resonance experiments, we elucidate the impact of varying pore sizes on reservoir quality and reveal the genesis of different reservoirs from the perspectives of depositional environment and diagenesis.The results indicate that: (1) The main types of reservoir pores include feldspar dissolution pores, residual intergranular pores, intergranular dissolution pores, clay intercrystalline pores, and a small number of microfractures. Notably, feldspar dissolution pores primarily develop micron-sized pores, whereas clay intercrystalline pores are predominantly nanometer-sized. (2) The overall drainage pressure of the reservoir is relatively high, with lower mercury saturation and a predominant throat radius in the nanometer range. Pores with diameters under 500 μm tend to exhibit open, plate-like, and fissure-like geometries, with a small quantity of ink-bottle-shaped pores also developed. (3) Reservoir pore diameters are mainly below 300 μm, and as the physical properties of the samples improve, the proportion of larger pores within the reservoir gradually increases. (4) The genesis of high-quality reservoirs can be primarily categorized into two types: The first type, located to the northeast near the sediment source, experiences strong hydrodynamics and good particle sorting, facilitating the development of chlorite films, which protect the original intergranular pores between particles and preserve a substantial number of residual intergranular pores following compaction, thereby forming high-quality reservoirs. The second type, situated to the southwest away from the sediment source, is characterized by increased water depth and weakened hydrodynamics. This area, being close to hydrocarbon source rock development zones, is prone to organic acid dissolution from the source rock, leading to the development of numerous dissolved pores and the formation of a significant amount of high-quality reservoir.

Tectonic geomorphological evidence of Late Quaternary segmental activity of North Lajishan Fault

doi: 10.12090/j.issn.1006-6616.2024125

[Abstract](30) [PDF 6294KB](6)

Abstract:
Lajishan-Jishishan is an important arc-shaped tectonic belt that extends to NE in the northeastern margin of the Tibetan Plateau, which is controlled by two extrusion thrust fault zones, the North Lajishan Fault and the South Lajishan Fault. Since the Late Cenozoic, the Lajishan area has strong tectonic activity, forming a significant basin-mountain coupling tectonic landform pattern, which is an ideal area to study the development and evolution of geomorphology and tectonic activities by using tectonic geomorphological methods. In this paper, using DEM data with a resolution of 30m, based on ArcGIS and MatLab platforms, plug-in tools and open-source code packages, the river steepness index (Ksn) values of 105 small and micro channels located above the fault at the outfall of the northern margin of Lajishan, and the HI values of 54 small and micro channels located in the bedrock area at the head of the river along the fault were extracted, and the area-elevation integral value (HI) interpolation value of the Lajishan-Jishishan area was calculated. According to the distribution of Ksn values, the uplift rate of the northern margin of the Lajishan showed an overall upward trend from west to east, but there was a local low value in the NE turning part of the fault on the northern margin of the Lajishan, which was speculated to be related to the weakening of the influence of the eastward thrust of the Dextel strike-slip fault in the Riyueshan from west to east, which also revealed the complexity, difference and segmentation of tectonic activities in this area. According to the results of Ksn value statistics, the Jishishan section has the fastest uplift rate and the strongest activity, which is likely to be an important reason for the occurrence of the 6.2 magnitude earthquake in Jishishan in 2023. Combined with the results of the geological survey of the route and the comprehensive interpretation of the oil exploration profile, the HI value shows that the Late Quaternary tectonic activity in the fault zone on the northern margin of the Lajishan has extended to the NE in addition to its own continuous activity, showing the characteristics of reverse fault and folding, resulting in more than ten moderate and strong earthquakes in the basin, and the migration characteristics and seismic activity of this tectonic activity are worthy of attention.
　　Kaywords: Lajishan;Jishishan;Channel Steepness Index;Hypsometric Integral;Tectonic-geomorphology

Deformation and geochronology of a ductile shear zone on the south side of Foping Dome in the South Qinling

doi: 10.12090/j.issn.1006-6616.2025008

[Abstract](38) [PDF 6528KB](10)

Abstract:
The Foping area in the Qinling orogenic belt is characterized by the concentrated development of granulite-migmatite-gneiss domes, making it a crucial region for studying the rheological mechanisms of the middle to lower continental crust and the Mesozoic tectonic evolution of the Qinling Mountains. The Yangtianba-Shimudi ductile shear zone, located at the southern margin of the Foping dome, preserves abundant information on mid- to deep-level structural deformation during the orogenic process. Multi-scale structural analysis and kinematic vorticity analysis indicate that this shear zone is dominated by pure shear with a right-lateral ductile shear deformation. In the felsic mylonites, quartz primarily exhibits prism <a> and prism <c> slip systems, suggesting deformation occurred under amphibolite facies conditions at approximately 550-650 °C. The characteristics of the metamorphic mineral assemblages and the garnet-biotite-plagioclase thermobarometry results indicate a clockwise P-T path, with peak metamorphic conditions of 568-611 °C/5.2-5.3 kbar and 630-654 °C/7.1-7.9 kbar. The isothermal decompression stage M2 recorded conditions of 590-616 °C/3.5-4.5 kbar. Zircon U-Pb dating of the leucosomes in the migmatites within the shear zone yielded an age of 180.8±3.8 Ma, representing the lower limit of the ductile shear deformation. Integrated with regional geological data, the metamorphic and deformational evolution of the study area can be reconstructed as follows: Prior to ~210 Ma, the central segment of the South Qinling tectonic belt was dominated by collisional orogenesis, leading to crustal thickening and the development of progressive metamorphism (M1) in the Foping area. During 210-200 Ma, the Foping region transitioned into a tectonic regime shifting from collisional orogenesis to post-collisional extension. This transitional phase was characterized by a bidirectional stress regime combining horizontal shortening and vertical collapse, which triggered ductile shear deformation (D1) in the Yangtianba-Shimudi area and initiated the isothermal decompression metamorphic event (M2). By 180 Ma, the region had fully entered the post-collisional extensional stage, during which a decompression-induced partial melting event developed in the northern part of the study area. Subsequently, during the exhumation of the shear zone, the mylonitic foliation and metamorphic foliation (S1) were overprinted by late-stage folding and crenulation cleavage, resulting in foliation transposition (D2).

Genesis of the Gneissic Biotite Granite in Lanhe, Northern Guangdong: Constraints from Zircon U-Pb Geochronology, Hf Isotopes, and Geochemistry

doi: 10.12090/j.issn.1006-6616.2024137

[Abstract](59) [PDF 2648KB](9)

Abstract:
[Objective] The Lanhe pluton in northern Guangdong is located at the southeastern margin of the Zhuguangshan pluton, primarily composed of gneissic biotite granite, whose petrogenesis has not yet been clearly defined. [Methods] In this study, LA-ICP-MS zircon U-Pb geochronology, rock geochemistry, and zircon Hf isotope analyses were conducted on the Lanhe gneissic biotite granite. [Results] U-Pb dating results indicate that the emplacement age of the Lanhe gneissic biotite granite is 427 ± 2 Ma, representing a product of the Caledonian magmatic activity. The geochemical characteristics show that the granite has SiO₂ contents ranging from 71.53% to 75.41%, high total alkali contents (K₂O + Na₂O = 7.57%–8.23%), and A/CNK values (1.00–1.06). It is enriched in Rb, Th, U, and K, but depleted in Ba, Y, Nb, Ta, Sr, and Yb. The LREE/HREE ratios range from 9.49 to 28.15, with significant Eu negative anomalies (δEu = 0.21–0.76). The zircon ε_Hf(t) values of the samples are all negative (-11.8 to -5.2), with corresponding t_DM2 values of 1806–2129 Ma. [Conclusion]Based on the geochemical and isotopic characteristics, the Lanhe gneissic biotite granite is identified as a highly fractionated I-type granite, primarily formed by partial melting of crustal metasedimentary rocks, including metagraywacke and metapelite. It is likely a product of the multi-stage reworking of the Paleoproterozoic basement during the Neoproterozoic to Early Paleozoic. The comprehensive study suggests that the Lanhe gneissic biotite granite formed in a syn-collisional tectonic setting during the Early Paleozoic in South China. [Significance] Integrating with the Zhuguang magmatic system and regional geological data, the Lanhe pluton likely represents a product of the transition from compressional thickening to post-collisional extension during the Caledonian orogeny in South China. This transition may have been associated with intracontinental tectonic reorganization or external subduction-collision processes.

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Supervisor： China Geological Survey

Sponsor： Institute of Geomechanics, Chinese Academy of Geological Sciences; Geological Society of China (GSC)

Editor-in-Chief： Deng Jun

ISSN 1006-6616

CN 11-3672/P

Post Issue Number 82-124

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