A 3D Geological Model Constrained by Gravity and Magnetic Inversion and its Exploration Implications for the World‐class Zhuxi Tungsten Deposit, South China

Yan, Jiayong; Lü, Qingtian; Qi, Guang; Fu, Guangming; Zhang, Kun; Lan, Xueyi; Guo, Xin; Jin, Wei-Tao; Luo, Fan; Hao, Wang Zhi; Xu, Wang

doi:10.1111/1755-6724.14602

Cited by 5 publications

(6 citation statements)

References 10 publications

(10 reference statements)

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“…This method facilitates the effective construction of basic profiles, cooperation between researchers, and incorporation of researchers' geological knowledge to improve efficiency and reliability. The high applicability of this method has been proved in much research work [8][9][10][11][12][13][14], but this method is more suitable for ore concentration areas with relatively rich geological data and good stratigraphic continuity. It is difficult to reflect the actual geological situations in ore concentration areas with sparse data and complex geological structures, particularly the actual geological situations of the deep geological structures perpendicular to the profiles and in areas with sparse data.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Geological–Geophysical Modeling and Prospecting Indications of the Ashele Ore Concentration Area in Xinjiang Based on Irregular Sections

Guo

Yan

et al. 2023

Minerals

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The Ashele ore concentration area is an important area for polymetallic ore concentration in Xinjiang, China. Scholars have made progress in understanding the ore-controlling structures, ore-bearing horizons, and metallogenic age of this area. However, there are still uncertainties about the 3D distributions of plutons, fault structures, and ore-bearing strata, which restrict the development of deep and peripheral ore prospecting and the discovery of new ore bodies in the area. This study proposes a geological–geophysical modeling method based on irregular sections and uses this method to establish a 3D geological–geophysical model based on physical property data, boreholes, surface geological maps, and geophysical data. The model shows that the study area has many hidden rock masses with various depths and shapes and fracture structures with complex shapes. The fault structure in the area is complex, and the ore bodies are controlled by the faults. The ore-bearing geological units (Ashele Formation) exhibit an obvious east–west-trending W-shaped fold structure. The deep part of the northern Ashele Formation extends northward slightly, and the southern Ashele Formation has thick strata, with depths generally greater than 2 km. Based on the information on deep structures provided by the model, three metallogenic prospective areas are predicted, which points out the direction for further prospecting work in the ore concentration area and shows that the adopted modeling method and process have good applicability for constructing 3D models of ore concentration areas with sparse data, large area, and complex geological structures. The proposed modeling method provides technical support for ore prospecting, particularly in the overburden area or ore concentration area with sparse data.

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional Geological–Geophysical Modeling and Prospecting Indications of the Ashele Ore Concentration Area in Xinjiang Based on Irregular Sections

Guo

Yan

et al. 2023

Minerals

Self Cite

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“…Gravity exploration is characterized by great depth, low cost and high efficiency, and has been widely used in the study of the internal structure of the earth's crust and the exploration of the distribution of deep minerals and oil and gas resources (Guillen and Menichetti, 1984;Li and Oldenburg, 1998;Nabighian et al, 2005;Nabighian et al, 2010;Afshar et al, 2018;Yan et al, 2020;Ming et al, 2021). Gravity anomaly information is a comprehensive reflection of all density information of the stratum from top to bottom, so much so that the vertical resolution is not high, and only by stripping away the influence of the surface and shallow layers can the information of the specified destination layer be obtained.…”

Section: Introductionmentioning

confidence: 99%

Binary structure constrained gravity inversion based on seismic first arrival travel time data

Deng,

Zhang,

Zhang

2023

Front. Earth Sci.

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Gravity exploration method is one of the important methods for deep mineral resource exploration, but gravity data inversion has limited resolution ability in the vertical direction. In order to improve the vertical resolution of gravity data inversion, we propose a binary structure constrained gravity inversion method based on seismic first arrival travel time data. This method effectively reconstructs a density model with high vertical resolution by transferring the structural information of a high-resolution velocity model reconstructed by seismic data inversion to gravity data inversion through the binary structure constrained technique. This strategy eliminates the need to integrate both gravity and seismic methods into a single inversion framework, avoiding both the difference in convergence speeds between the two methods, as well as getting rid of the complexity associated with calculating structural coupling terms. Theoretical simulations show that the fuzzy c-means cluster analysis technique can accurately extract the target region of the velocity model reconstructed by seismic data inversion. Under the constraint of seismic structural information, the resolution of reconstructed density model is much higher than that of separate gravity data inversion, which proves that high resolution seismic information can improve the vertical resolution of gravity data inversion. Compared with the traditional cross-gradient joint inversion, the binary structure constrained gravity inversion method can further improve the resolution of the density model, especially in the reconstruction of the anomaly interface, which verifies that the method has certain effectiveness.

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“…Magnetic exploration is a kind of geophysical exploration method that uses the magnetic field changes (magnetic anomalies) caused by the magnetic differences between various rocks (ore) in the crust to find useful mineral resources and study the underground structure [1][2][3]. Magnetic prospecting is widely used to search for useful mineral resources [4][5][6]. In the late 1950s and early 1960s, the Soviet Union and the United States began ocean magnetic surveys, and continental drift theory entered a new historical stage.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Limited-Memory BFGS Inversion of Magnetic Data Based on a Multiplicative Objective Function

Liu,

Tan,

Peng

et al. 2023

Applied Sciences

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At present, the traditional magnetic three-dimensional inversion method has been fully developed and is widely used. Magnetic exploration is a kind of geophysical exploration method that uses the magnetic field changes (magnetic anomalies) caused by the magnetic differences between various rocks in the crust to find useful mineral resources and study the underground structure. Traditional magnetic three-dimensional inversion is relatively inefficient. Moreover, the traditional additive objective function (data fitting difference term plus regularization term and logarithmic obstacle term), which causes the regularization factor selection to be more complicated, is implemented in this method. Therefore, it is necessary to establish a new efficient three-dimensional magnetic inversion algorithm and optimize the selection of regularization factors. In this paper, based on the limited-memory BFGS (L-BFGS) method, the three-dimensional magnetic inversion of a multiplicative objective function is realized. The inversion test is conducted in this paper using both theoretical synthesis data and measured data. The results demonstrate that the limited-memory BFGS method significantly enhances the inversion efficiency and yields superior inversion outcomes compared to traditional magnetic three-dimensional inversion methods. Additionally, the multiplicative objective function-based three-dimensional magnetic inversion method simplifies the process of selecting weight factors for regularization terms.

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A 3D Geological Model Constrained by Gravity and Magnetic Inversion and its Exploration Implications for the World‐class Zhuxi Tungsten Deposit, South China

Cited by 5 publications

References 10 publications

Three-Dimensional Geological–Geophysical Modeling and Prospecting Indications of the Ashele Ore Concentration Area in Xinjiang Based on Irregular Sections

Three-Dimensional Geological–Geophysical Modeling and Prospecting Indications of the Ashele Ore Concentration Area in Xinjiang Based on Irregular Sections

Binary structure constrained gravity inversion based on seismic first arrival travel time data

Three-Dimensional Limited-Memory BFGS Inversion of Magnetic Data Based on a Multiplicative Objective Function

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