Your search keyword '"DIKES (Geology)"' showing total 2,858 results

1. Shock petrographic and numerical modeling constraints on the morphology and size of the Morokweng impact structure, South Africa.

Author

Gibson, Roger L., Wela, S'lindile S., Rae, Auriol S. P., and Andreoli, Marco A. G.

Subjects

*SPHENE, *HYDROTHERMAL alteration, *EROSION, *BRECCIA, *DIABASE, *APATITE, *DIKES (Geology)

Abstract

The 369 m deep M4 drill hole, located ~18 km NNW of the center of the 146 Ma Morokweng impact structure (MIS), intersects shocked Archean granitoid gneisses and subsidiary dolerite intrusions that are cut by faults, cataclasites and mm‐ to m‐wide suevitic and pseudotachylitic breccia dikes. The shock features in quartz in the gneisses and breccia dikes include decorated planar deformation features (PDFs), planar fractures, feather features, and toasting. Other minerals show features that may be shock‐related, such as multiple sets of planar features and alternate twin ladder structures in feldspars, kink bands in biotite, and planar features in titanite, apatite, and zircon; however, these are variably annealed and/or overprinted by hydrothermal alteration effects, and confirmation of their origin awaits further study. Universal Stage measurements of PDF sets in quartz from 12 gneissic target rocks and from lithic and mineral clasts in three suevitic and three pseudotachylitic breccia dikes reveal four dominant sets: (0001), {101¯3$$ 10\overline{1}3 $$}, {101¯4$$ 10\overline{1}4 $$} and {101¯2$$ 10\overline{1}2 $$}. Based on these observations, the average peak shock pressure in these rocks is estimated at ≤16 GPa, which supports the original proximity (within one transient cavity radius) of these rocks to the point of impact. No discernible depth‐dependent shock attenuation was noted in the core. These shock levels and the elevated structural position of the rocks in the M4 core relative to the impact melt sheet intersected in drill holes closer to the center of the MIS suggest that the M4 lithologies represent part of the parautochthonous peak ring volume that subsequently experienced 1.5–2 km of post‐impact erosion before it was buried beneath younger sediments. Numerical modeling using the iSALE‐2D code suggests that the original Morokweng crater had a rim‐to‐rim diameter of between 70 and 80 km, and that the rocks in the M4 core were originally located at a depth of 7–8 km and a radial distance of 8–9 km from the point of impact. [ABSTRACT FROM AUTHOR]

Published

2024

2. Dike-induced aquifer models derived from high-resolution multi-spectral satellite imagery.

Author

Radebe, Samkelo and Clark, Martin

Subjects

*REMOTE-sensing images, *GROUNDWATER management, *GROUNDWATER flow, *DIABASE, *ARID regions, *DIKES (Geology), *AQUIFERS

Abstract

The Main Karoo Basin in South Africa is a typical example of an expanding arid region dependent on groundwater resources. Dolerite dikes in the region, analogous to dolerite dikes worldwide, are known to influence subsurface groundwater flow and spatially relate to high-yielding boreholes. Here, the effect of dolerite dikes on groundwater flow is remotely assessed using the Modified Soil Adjusted Vegetation Index derived from high-resolution multi-spectral satellite imagery. From imagery collected during the wet and dry seasons of 2018 and 2021, two aquifer models relating to 505 dikes were identified; (1) barrier-controlled aquifers are induced by ~ 56% of dikes, (2) fractured aquifers are induced by ~ 35% of dikes. Surficial areas overlying aquifers are also shown to sustain vegetation growth through dry seasons. This research demonstrates the efficacy of vegetation indices to rapidly characterise dike-related aquifer models and their seasonal sustainability, critical for effective groundwater exploration and management. [ABSTRACT FROM AUTHOR]

Published

2024

3. Geochemistry of Mafic Rocks From the Nagrota–Kathindi Section, Himachal Pradesh, Northwestern Himalaya: A Probable Example of Plume–Lithosphere Interaction.

Author

Singh, M. Rajanikanta, Singh, Paramjeet, Sethy, Pratap C., and Singh, A. Krishnakanta

Subjects

*RARE earth metals, *CHLORITE minerals, *MAFIC rocks, *PETROLOGY, *GEOCHEMISTRY, *DIKES (Geology)

Abstract

ABSTRACT The Northwest Himalayan region has a record of several phases of mafic magmatic activity spanning from Precambrian to Cenozoic in a dynamic tectonic setting. Here, we studied detailed petrography and new whole‐rock geochemistry of mafic volcanic and dykes from the Nagrota–Kathindi Section (NKS), Himachal region of the NW Himalaya, to understand the petrogenesis and possible tectonic setting. Both rock types have comparable mineralogical compositions (clinopyroxene + plagioclase + actinolite‐tremolite + chlorite + iron oxides ± hornblende ± epidote ± quartz ± carbonates) overprinted by greenschist to lower amphibolite facies metamorphism. The mafic volcanic and dykes of NKS exhibit subalkaline basalts to basaltic andesites and a typical tholeiite compositional character. The chondrite‐normalized rare earth element pattern exhibits similar LREE‐enrichment and strong HREE‐fractionation, whereas primitive mantle‐normalized multi‐element patterns show pronounced LILE‐enrichment of Rb, Ba, Th, LREE, and HFSE depletion of Nb, K, P, and Ti. The Zr–Y–Nb–Th relationships indicate that both rock types were derived from the plume source, whereas low Nb/La (< 1), similar high large‐ion lithophile element concentrations, and pronounced negative Nb, Zr, P, and Ti anomalies suggest that components other than mantle plume must have been involved in the generation and evolution of both rock types, that is, most likely plume and subcontinental lithosphere mantle (SCLM) interaction. The genesis of parent magma for the NKS volcanic and dykes was derived by 4%–6% and 10%–20% partial melting from the spinel + garnet lherzolite stability field. The majority of the studied samples correspond to spinel + garnet peridotite melting on (Gd/Yb)N versus CaO/Al2O3 diagram, thereby corroborating residual garnet in the mantle restite. All the basalts and dykes from the NK section did erupt/intrude in an intracontinental rift setting based on geochemical discrimination. The key petro‐tectonic processes attributed to the formation of these rocks are as follows: (i) the melting of the ascending plume by adiabatic decompression; (ii) the partial melting of this plume–SCLM source in the melting regime, which produces basaltic magma with a tholeiitic composition; and (iii) the release of heat that provides the thermal condition for melting of SCLM and interaction between upwelling mantle plume and subduction metasomatized SCLM. [ABSTRACT FROM AUTHOR]

Published

2024

4. Occurrence of Mafic Rocks within Ediacaran Strata in the Aksu Region, NW Tarim Craton, and its Geological Implications.

Author

XIE, Hongzhe, ZHU, Xiangkun, WANG, Xun, HE, Yuan, and SHEN, Weibing

Subjects

*MAFIC rocks, *STRATIGRAPHIC correlation, *DIABASE, *BASALT, *PRECAMBRIAN, *DIKES (Geology)

Abstract

The Tarim Craton is an ancient Precambrian continental block, and detailed knowledge of its thermo‐tectonic history is crucial for understanding the early history of continental evolution. Abundant layered mafic rocks, which have commonly been regarded as basalts, occur within the Ediacaran Sugetbrak Formation (Fm.) in the Aksu region of the northwestern Tarim Craton. Clear intrusive features have now been discovered, including mafic rocks truncating Ediacaran sedimentary layers, exhibiting an intrusion‐baked margin where they interact with both the overlying and bottom wall rocks, and displaying a fine‐grained transition zone from their interior to their margins. The new findings demonstrate that these mafic rocks within the Aksu Ediacaran strata were not erupted basalts but instead are intrusive diabase dykes. Therefore, these mafic rocks cannot be used to constrain the timing of the Sugetbrak Fm. in the Aksu area, nor as marker layers for regional stratigraphic correlation. Furthermore, the Ediacaran thermo‐tectonic evolution in this region, deduced from the assumption that the mafic rocks are lavas, needs to be revised. [ABSTRACT FROM AUTHOR]

Published

2024

5. Mineralogy and Geochemistry of Upper Miocene Igneous Rocks, Kos Island, Greece: Extension during Strike-Slip Faulting and Subduction Rollback.

Author

Pe-Piper, Georgia, Piper, David J. W., and Tsoukalas, Nikolaos

Subjects

*IGNEOUS rocks, *IGNEOUS intrusions, *LAMPROPHYRES, *MINERALOGY, *MONZONITE, *DIKES (Geology)

Abstract

Upper Miocene volcanic and plutonic rocks on Kos island preserve a record of magmatic and tectonic events in the transition zone between the Aegean and Anatolian microplates. Their field setting, syn-intrusion deformation, mineralogy, and geochemistry were investigated. Volcanic rocks, including trachyandesite flows and trachyandesite to rhyolite domes, were extruded on a central E–W horst and directly overlie Alpine basement. Thick successions of trachytic flow tuffs are interbedded with fluvial and lacustrine basinal sediments to the south of this horst. Volcanism was synchronous with the emplacement of the Dikeos monzonite pluton, which is geochemically similar to some lithic clasts in the thick flow tuffs and is cut by mafic dykes including lamprophyres. Two main types of mafic magma were present: a K-rich lamprophyric magma that evolved to trachyandesite and more calc-alkaline magma similar to mafic enclaves in the monzonite. Syn-intrusion structures in the monzonite indicate emplacement during E–W sinistral strike-slip faulting that created local transtensional deformation, providing accommodation for a Dikeos magma reservoir. A change in the style of deformation in the Late Miocene led to NW-striking extension in the footwall, occupied by mafic dykes and mineralized veins, and extensional detachment of the hanging wall, resulting in unroofing of the monzonite. [ABSTRACT FROM AUTHOR]

Published

2024

6. A statistical analysis of volcano-tectonic earthquake swarms in the off Nicobar region of the Andaman Sea.

Author

Chingtham, Prasanta, Sharma, Babita, and Aswini, Karanam Kattil

Subjects

*EARTHQUAKE swarms, *AKAIKE information criterion, *ISLAND arcs, *MAXIMUM likelihood statistics, *STATISTICS, *DIKES (Geology), *SUBMARINE volcanoes

Abstract

The present research work is primarily carried out to select the suitable and better variants or functions of ETAS models to describe the energetic offshore earthquake swarms following 26 December 2004 (MW 9.1) and 21 March 2014 (MW 6.5) along the Andaman–Sumatra subduction zone. An attempt has also been made to inspect the variability of the selected model parameters from this robust estimation to discuss the physical mechanism differences between the SSE-related and fluid- or magma-related swarm sequences. For this purpose, different variants of ETAS models, such as single ETAS model, combined ETAS model, Boxcar swarm model, and exponential swarm model, are utilized for investigating the seismic anomalies by estimating the model parameters from the earthquake occurrence times using maximum likelihood method. The estimated AIC (Akaike information criterion) values for all these models suggest that the exponential swarm model outperforms the other models in successfully explaining the transient changes of background seismicity for the five energetic earthquake swarms triggered by the volcano-tectonic activities in the Andaman Sea. The reason is undoubtedly related to the localized nature of magmatic intrusion or fluid migration that caused the swarms and the exponential decay patterns of earthquakes after the initiation of the swarms. Although the swarms exhibit the shape of exponential function, the background seismicity shown by the parameter μ increases by one order during the swarm as compared to the pre-swarm period in the sub-catalogue. Therefore, the procedure of identifying improved variants or functions of ETAS models and estimating model parameters using earthquake occurrence times enhances our understanding of earthquake-triggering mechanisms, potential swarm activity patterns, and the intricate interplay between seismicity and volcanic processes in submarine volcanic arcs. While this approach might not facilitate real-time forecasting, it remains instrumental in characterizing seismic patterns and providing essential information for effective hazard assessment and the formulation of mitigation strategies within the coastal areas of the Andaman–Nicobar Islands region. [ABSTRACT FROM AUTHOR]

Published

2024

7. Paleomagnetic Constraints on the Rapid Plate Shift of North China Block During the Jurassic From ∼155 Ma Dykes and Sills.

Author

Wang, Pengfei, Yi, Zhiyu, Meert, Joseph G., Liu, Yu‐Shu, Yang, Silin, Wang, Fei, Li, Zaijun, and Huang, Baochun

Subjects

POLAR wandering, PLANETARY rotation, PALEOGEOGRAPHY, PALEOMAGNETISM, FACIES, DIKES (Geology)

Abstract

A large‐scale apparent polar wander occurred during the Jurassic interval, which is interpreted as true polar wander (TPW). As the motion is nearly orthogonal to the TPW axis, the North China Block (NCB) experienced the largest latitudinal and environmental changes and provides unique constraints on Jurassic TPW. However, due to the lack and uneven quality of paleomagnetic data, TPW records in North China are controversial. Here, we report a new paleomagnetic pole (80.8°N, 13.0°E, A95 = 7.4°) from the late Jurassic sills and dykes that intrude the Nandaling and Xiahuayuan formations in the NCB. The new pole places the NCB at 36.8° ± 7.4°N at 155 ± 3.4 Ma, using Beijing as the reference site. Combined with the reliable Jurassic poles, our study reveals a large, steady southward shift of 37.3° ± 7.2° for the NCB during the Middle and Late Jurassic, and reflects a component of TPW. The position of ∼155 Ma pole also supports significant TPW prior to ∼160 Ma and agrees with proposals attributing the diachronous 165–155 Ma aridification across the Eastern Asian blocks. Plain Language Summary: True polar wander (TPW) refers to the rotation of a planet's upper solid shell relative to the spin axis, which helps stabilize its rotation and may result in rapid plate shift and environmental change. A large‐scale TPW occurred in the Jurassic but the configuration of which is controversial. Due to its unique location, North China provides unique constraints on Jurassic TPW, including paleolatitudinal, rotational and facies changes. Here we report new paleomagnetic data from a suite of sills and dykes in the North China Block (NCB). Combined with the available Jurassic paleomagnetic data, our study reveals a large, steady southward shift of ∼4,000 km for NCB between ∼174 and 147 Ma, and reflects a component of a proposed monster Jurassic TPW. The plate motion of the NCB also supports significant TPW prior to ∼160 Ma, that is compatible with the diachronous aridification through East Asia between ∼165 and 155 Ma. Key Points: A new paleopole reported from the late Jurassic sills and dykes positions the North China Block (NCB) at ∼37°N at ∼155 MaThe NCB experienced a huge, steady southward shift of ∼4,000 km during ∼174–147 Ma, reflecting a component of true polar wander (TPW)The plate shift of the NCB supports considerable TPW prior to ∼160 Ma, which is compatible with the ∼165–155 Ma aridification across East Asia [ABSTRACT FROM AUTHOR]

Published

2024

8. Dyke detection as the main target of groundwater exploration using Magnetometry and Electromagnetic data.

Author

Ghari, Hosseinali and Mahdavi, Maryam

Subjects

*DIKES (Geology), *MAGNETOMETERS, *ELECTROMAGNETISM, *DIABASE

Abstract

Dolerite structures, such as dykes and sills are the main target for groundwater exploration in the Karoo Supergroup area which is the main stratigraphic unit in South Africa. Morgenzon Farm is one of the sites in the Karoo Supergroup, including a dolerite dyke, which is of interest here. The magnetization/susceptibility and resistivity of the dolerite dyke are significantly larger than those of the encompassing sedimentary materials. Therefore, the low induction number electromagnetic (EM-LIN) and magnetometry approaches may be useful for its detection. The EM-LIN is composed of three techniques: EM38, EM31, and EM34, with the latter being manipulated. Since both EM34 and magnetometry inverse problems are linear, a regularized weighted minimum length solution algorithm is utilized for their inverse modelling, but with one main discrepancy: the model weighting function for the magnetometry method is attained from the multiplication of depth weighting and compactness constraints, while the model weighting function is only equal to depth weighting for the EM34 approach. Recovered susceptibility and conductivity sections derived respectively from magnetic and EM34 data sets show high consistency. Inverted models represent a dolerite dyke in the middle of the profile with a depth range of 4 to 15m. [ABSTRACT FROM AUTHOR]

Published

2024

9. Design considerations for ash pond dyke construction in the Hilly terrain for high concentrated slurry disposal: a case study.

Author

Goyal, Anurag and Gupta, Anjali

Subjects

*DIKES (Geology), *SLURRY, *TOPOGRAPHY, *SUBSOILS, *GEOTECHNICAL engineering, *SOIL classification

Abstract

Designing an ash pond for the High Concentrated Slurry Disposal (HCSD) in hilly terrains poses a unique set of challenges. In such regions, the availability of barren land adjacent to the project sites is limited, making it difficult to locate suitable sites for ash pond construction. Furthermore, the hilly terrain and complex topography demand careful planning and design to ensure the long-term stability and safety of the ash pond and associated infrastructure. This paper discusses the design considerations for the construction of ash pond dykes in a hilly region of Vietnam for the HCSD disposal. The case study highlights detailed geotechnical design investigations, such as soil type, slope stability and groundwater conditions. In addition, geotechnical instrumentation to monitor the performance of ash pond dykes and the subsoil supporting it during and after construction is also discussed. The paper also examines the environmental and hydrological design aspects of the ash pond, including the development of drainage and channelization concept along the hilly terrain to manage storm water and prevent the mixing of rain water with ash slurry. Such mixing could otherwise create an environmental hazard. [ABSTRACT FROM AUTHOR]

Published

2024

10. Geological conditions and fluid flow history that lead to the development of large clastic dykes in basins: A case study from Kushiro, Japan.

Author

Tamamura, Shuji, Murakami, Takuma, Kaneko, Katsuhiko, Yoneda, Tetsuro, Sato, Tsutomu, Aizawa, Jun, Matsumoto, Hiroyuki, Uchida, Kagemi, Suzuki, Yoshiaki, and Igarashi, Toshifumi

Subjects

*CARBONATE minerals, *FLUID flow, *CHANNEL flow, *CLAY minerals, *OSTWALD ripening, *DIKES (Geology), *KAOLINITE

Abstract

Large clastic dykes (the Harutori‐Taro and Harutori‐Jiro dykes) and smaller dykes are exposed in the underground Kushiro Coal Mine (KCM), Japan. This study examines these dykes as a case study to investigate the geological conditions and fluid flow history that lead to the development of large clastic dykes in basins. The composition of the dykes indicates the Beppo and/or Harutori formations as their parent unit. Crystallite size distribution (CSD) analysis reveals Ostwald ripening of the kaolinite in the kaolinitised feldspar from the dykes, suggesting stagnant conditions in the parent unit before the dyke was formed. In contrast, smectite CSDs and the high carbonate content of the dykes suggest that large volumes of fluid flowed through the dykes along the established hydraulic gradient, which was triggered by the breaking of the upper seal. The isotopic and chemical compositions of the calcite and aragonite in the dykes, with moderate siderite and rhodochrosite content, indicate the fluid was a warm (>30°C) mixture of freshwater and saltwater, which was transferred from deeper levels of the parent unit towards the crest of an anticline. Immediately after sand injection, the semi‐closed system of the parent unit near the root of the large dyke was transformed into a major flow channel for overpressurised fluids. Subsequently, a large volume of fluid flowed along the vertical conduit (or dyke) over a long period of time (>1 Myr), which removed fluid from a widespread area (i.e., several hundred square kilometres) of the basin. The results show that thin parent units, poor lateral continuity of the upper seal, and spatially heterogeneous overpressurisation do not preclude the formation of large dykes. [ABSTRACT FROM AUTHOR]

Published

2024

11. The Permian Cornubian granite batholith, SW England; Part 1: Field, structural, and petrological constraints.

Author

Searle, Michael P., Shail, Robin K., Pownall, Jonathan M., Jurkowski, Christopher, Watts, Anthony B., and Robb, Laurence J.

Subjects

*ARSENOPYRITE, *CASSITERITE, *MUSCOVITE, *LAMPROPHYRES, *SMALL capitalization stocks, *DIKES (Geology)

Abstract

The Permian Cornubian granite batholith (295–275 Ma) in SW England includes seven major plutons and numerous smaller stocks extending for ∼250 km from the Isles of Scilly in the WSW to Dartmoor in the ENE. The granites are peraluminous and classified as crustal melt S-type, predominantly two-mica granites, and biotite or tourmaline monzo- and syenogranites, with subordinate minor topaz granite and lithium mica granite. The granites and their host rocks are pervasively mineralized with tin (cassiterite), tungsten (wolframite, ferberite), copper (chalcopyrite, chalcocite, bornite), arsenic (arsenopyrite), and zinc (sphalerite) mineralized lodes. Quartz-muscovite selvedges (greisen-bordered) also contain enrichment of lithophile elements such as boron (tourmaline), fluorine (fluorite), and lithium (lithium-micas such as lepidolite and zinnwaldite). They are derived from both muscovite and biotite dehydration melting of pelitic-psammitic rocks and intruded from a common source along the length of the batholith. Pressure estimates from andalusite and cordierite-bearing hornfels in the contact metamorphic aureole (150 ± 100 MPa) show that the granites intruded to 3 km depth. Cupolas around the Land’s End and Tregonning granites show aplite-pegmatite dikes and tourmaline + quartz + muscovite veins (greisen) that are frequently mineralized. Synchronous intrusions of lamprophyre dikes suggest an additional heat source for crustal melting may have been from underplating of alkaline magmas. The lack of significant erosion means that the source region is not exposed. In an accompanying paper (Part 2; Watts et al., 2024), gravity modeling reveals possible solutions for the shape and depth of the granite and the structure of the lower crust. We present a new model for the Land’s End, Tregonning, and Carnmenellis granites showing a mid-crustal source composed of amphibolite facies migmatites bounded by prominent seismic reflectors, with upward expanding dikes feeding inter-connected granite laccoliths that show inflated cupolas with shallow contact metamorphism. The Cornubian granites intruded >90 m.y. after obduction of the Lizard ophiolite complex, and after Upper Devonian–Carboniferous Variscan compressional, and later extensional, deformation of the surrounding Devonian country rocks. Comparisons are made between the Cornubian batholith and the Patagonian batholith in Chile, the Himalayan leucogranites, and the Baltoro granite batholith along the Karakoram range in northern Pakistan. [ABSTRACT FROM AUTHOR]

Published

2024

12. Devonian intrusions of southwestern New Brunswick, Canada: U-Pb geochronology, petrogenesis and genetic constraints on gold mineralization.

Author

Heidarian, Hassan, Lentz, David R., Thorne, Kathleen G., and McFarlane, Christopher R. M.

Subjects

*GEOLOGICAL time scales, *IGNEOUS intrusions, *DIKES (Geology), *PETROGENESIS, *GOLD, *LASER ablation inductively coupled plasma mass spectrometry, *MINERALIZATION

Abstract

The Clarence Stream intrusion-related gold deposit is hosted within metasedimentary and metavolcanic sequences of the Ordovician Cookson and Silurian Mascarene groups that were intruded by several phases of the Late Silurian to Early Devonian Saint George Plutonic Suite. Based on geochemical and geochronological data, the intrusive rocks in the deposit are categorized into three distinct suites, including gabbroic, granitoid, and Whittier Ridge Granite (WRG). The gabbroic suite is the same as the East Branch Brook metagabbro intrusion, which exhibits a subalkaline mafic composition fractionated from a depleted mantle in a suprasubduction zone setting. The granitoid suite shows the same geochemical characteristics and age as the metaluminous to slightly peraluminous Magaguadavic Granite and its fractionated phases. The WRG suite reflects characteristics of calc-alkaline, metaluminous to peraluminous I-type granites in the area, such as Sorrel Ridge and Mount Douglas granitic plutons. In situ U-Pb zircon geochronology yielded an age of 419.5 ± 3.8 Ma for a monzodiorite from the gabbroic suite. Porphyritic granite and alkali granite from granitoid suite yielded U-Pb zircon age of 402.4 ± 1.8 Ma and 394.3 ± 3.8 Ma, respectively. Geochronologic data from the WRG suite reflect two different crystallization ages of 383.8 Ma (382.4 ± 3.1 to 385.1 ± 4) and 372.4 Ma (367.4 ± 1.3 to 377.1 ± 1.9). Several pieces of evidence demonstrate that the gold mineralizing events occurred after the emplacement of the East Branch Brook metagabbroic dykes and are linked to the various intrusive phases of the nearby syntectonic Early Devonian Magaguadavic Granite. The absence of gold and sulphide mineralization in felsic dykes related to the WRG confirms that this plutonic body formed adjacent to the gold zones after the main gold mineralizing event. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Comparative Study of Ore‐bearing Dikes and a Barren Dike in the Zaozigou Gold Deposit, Western Qinling: Zircon Morphology, U‐Pb Chronology and Geochemical Constraints.

Author

LIU, Jiawang, WANG, Shuzhi, WANG, Tao, CAO, Chong, QIU, Junting, and XIE, Fenquan

Subjects

*TONALITE, *DIORITE, *FAULT zones, *PORPHYRY, *CRYSTAL morphology, *DIKES (Geology)

Abstract

The Zaozigou gold deposit lies south of the Xiahe—Hezuo regional fault zone in the western Qinling orogenic belt and contains many intermediate to felsic dikes. Diorite porphyry, quartz diorite porphyry and biotite diorite porphyry are mineral‐bearing dikes, whereas granite porphyry is unrelated to gold mineralization. To compare the relationship between different dikes and mineralization, this study analyzed the cathodoluminescence (CL) of zircon crystals in all four types of dikes exposed in the Zaozigou deposit, using a zircon typological classification. The formation temperature of the granite porphyry (734°C) was higher than the average temperature of the other three types of dikes (704°C), whereas the former's alkalinity index (395) was lower than the average alkalinity index of the other three dikes (425). The ΣREE amount of granite porphyry (147.18 ppm) was smaller than the average ΣREE amount of the other three dikes (246.80 ppm) and its δEu value (0.33) was larger than the average δEu values of the other three dikes (0.30). The U‐Pb ages of zircon in the four types of dikes were relatively consistent with the crystallization ages of approximately 240 Ma, which indicates that all four types of dikes intruded in the Middle Triassic. Compared to the other three ore‐bearing dikes, the morphology of the zircon crystals in the barren dikes evolved from S13 to S5 and then returned to S13. These results indicate that the barren dike underwent an increase in temperature and a decrease in alkalinity, which may be an important reason for the absence of mineralization. [ABSTRACT FROM AUTHOR]

Published

2024

14. Magnetic fabrics of west coast dyke swarm from Deccan volcanic province, Maharashtra, India and their relationship with magma flow direction.

Author

Lakshmi, B. V., Deenadayalan, K., and Dimri, A. P.

Subjects

MAGNETIC anisotropy, MAGNETIC susceptibility, ADVECTION, HYSTERESIS loop, MAGMAS, DIKES (Geology)

Abstract

Dykes are one of the primary subvolcanic bodies that transport magma from the shallow magma chamber or from the deep-seated magma reservoir. The mechanism of magma transport and emplacement in dyke swarms can contribute precious details on source and how magma has associated with crustal rocks. Here we are presenting the results obtained from the Anisotropy of magnetic susceptibility (AMS) on their mode of emplacement and to understand magma flow direction. AMS and rock magnetic studies were performed on 33 dykes located on the West coast of Maharashtra, (India) to determine the magma flow direction using magnetic fabric. Thermomagnetic curves and hysteresis loop measurement indicates that titanomagnetite of associated pseudo-single-domain/multi-domain grain sizes are responsible for the magnetic fabrics. Based on the clustering of the principal AMS axes, three types of AMS fabrics were recognized, (i) Normal fabric, interpreted as due to magma flow characterised by clustering of K1–K2 axes on the dyke plane and K3 axes are nearly perpendicular to it, (ii) Inverse fabric with K2–K3 plane parallel to the dyke plane and K3 is perpendicular to it and (iii) Intermediate fabric, with K1–K3 axes clustering close to dyke plane. The inclination of the K1 axis (IK1) of Normal fabric is the most important to determine the flow of magma for the studied dyke swarm. The IK1 of the studied dykes were fed dominantly by horizontal (IK1 < 30°), inclined (30° < IK1 < 60°) up to vertical fluxes (IK1 > 60°). These results suggest that the dykes may be closer to the magma source and horizontal magma flow inferred from the dykes reveals source is located further away. The present AMS study along with geophysical, geochemical and petrological study supports the evidence of feeder fed mechanism. [ABSTRACT FROM AUTHOR]

Published

2024

15. Paleomagnetism and Geochronology of 2.68 Ga Dyke from Murmansk Craton, NE Fennoscandia: New Data for Earth's Magnetic Field Regime in the Neoarchean.

Author

Veselovskiy, R. V., Samsonov, A. V., Stepanova, A. V., Larionova, Yu. O., Arzamastsev, A. A., Travin, A. V., Egorova, S. V., Erofeeva, K. G., Kosterov, A. A., Shcherbakova, V. V., Shcherbakov, V. P., Zhidkov, G. V., and Zakharov, V. S.

Subjects

*GEOMAGNETISM, *MAGNETIC flux density, *REMANENCE, *GEOCHEMISTRY, *PALEOMAGNETISM, *DIKES (Geology)

Abstract

We present new results of geochronological, rock magnetic, paleomagnetic and paleointensity studies of the olivine gabbro dyke located at the northern part of the Murmansk craton, NE Fennoscandia (the Kola Peninsula). According to its geochemistry, petrographic and geochronology features, the dyke belongs to the 2.68 Ga dyke swarm, as confirmed by Sm-Nd mineral isochron. We find a significant difference in the rock magnetic and paleomagnetic characteristics of the central and marginal parts of the dyke, which is independently supported by petrography and geochemistry. It is shown that the rocks of the central part of the dyke retained not only their primary mineral composition, but also the primary component of the natural remanent magnetization. We use its direction to determine the 2.68 Ga virtual geomagnetic pole for the Murmansk craton: Slat = 68.64292° N, Slong = 37.7945° E, N = 41 specimens, Plat = –73.5°, Plong = 138.9°, dp/dm = 3.2°/3.4°, paleolat = –65.9°. We also obtain reliable estimates (17 samples) of the Earth's magnetic field intensity at ca. 2.68 Ga: VDM value is found to be 1.85 × 1022 A m2 corresponding to the geomagnetic field several times weaker than the present-day field. [ABSTRACT FROM AUTHOR]

Published

2024

16. Paleozoic Multi-Stage Magmatic Events Related to Proto-Tethys and Paleo-Tethys Evolution: Insights from Intrusive Rocks in the Eastern Altyn Orogen, NW China.

Author

Li, Jiyong, Xia, Yanqing, Zhang, Xilong, Jiang, Haoyuan, Lei, Tianzhu, Wang, Yongchao, Liu, Yanhong, Liu, Shanpin, and Zhang, Xiaobao

Subjects

*TETHYS (Paleogeography), *PALEOZOIC Era, *CONTINENTAL crust, *GEOCHRONOMETRY, *SLABS (Structural geology), *ADAKITE, *DIKES (Geology)

Abstract

Abundant mafic-felsic intrusions distributed in the Altyn Orogen record orogenic histories related to Proto-Tethys and Paleo-Tethys evolution. Zircon U-Pb dating of the intrusive rocks in the eastern Altyn Orogen identifies at least three major tectono-magmatic episodes, yielding ages of ∼426, ∼376–373 and ∼269–254 Ma. The first two emplacement episodes correspond to the post-collisional magmatism in the Altyn Orogen. The ∼426 Ma granitoids possess adakitic characteristics coupled with enriched isotopes, suggesting that they originated from partial melting of thickened lower continental crust induced by upwelling asthenospheric mantle after slab break-off of the South Altyn Ocean Plate. Next, the ∼376–373 Ma mafic-intermediate rocks and coeval granitoids represent a large thermal event that involved mantle melting with induced new juvenile lower continental crust melting in a post-collisional extensional setting. Finally, the ∼254 Ma diabase dykes intruded into the ∼269 Ma granitoids, which were related to the widespread Late Paleozoic magmatism resulting from Paleo-Tethys Ocean subduction. Post-collisional magmatism in the Altyn Orogen significantly enhances understanding of the tectono-magmatic evolution in the northern Tibetan Plateau. The penetrative influence of Paleo-Tethys Ocean subduction was more extensive than previously thought. [ABSTRACT FROM AUTHOR]

Published

2024

17. Interactions Between River Floods and Human Activities on Sediment Transport in a Macrotidal Estuary.

Author

Yan, Yuhan, Song, Dehai, Huang, Junbao, Han, Yu, Xie, Dongfeng, and Bao, Xianwen

Subjects

SUBMARINE geology, ESTUARINE sediments, WATERSHEDS, FISH migration, RIVER channels, DIKES (Geology), SEDIMENT transport

Abstract

River floods and human activities would impact land‐to‐sea sediment transport, which is essential for understanding the evolution of the global sediment cycle in the Anthropocene era. This study focused on investigating how river floods and a dike constructed in 2005 along a river channel influence sediment transport from the Ou River Estuary to the East China Sea. A validated three‐dimensional sediment transport model based on the Finite Volume Community Ocean Model was utilized for this study. The presence of the dike obstructs alongshore currents and fish migrations, leading to negative effects on marine ecology. Therefore, selective dismantling and ecological restoration measures are deemed necessary. Three scenarios were considered in this study: no‐dike, dike‐constructed, and dike‐partially‐removed conditions, along with various types of river floods. The findings indicate that the monthly sediment flux to the sea decreased by 7.7% from 8.11 × 106 to 7.49 × 106 t following dike construction, while the proportion of cross‐shore sediment flux to the total flux increased from 37% to 59%. The dike consistently has a greater impact than river floods in their interactions. However, partially removing the dike reduces its influence and restores sediment transport to pre‐dike levels, the effectiveness of which is more pronounced with more frequent floods, larger volumes, and rising sea levels. This study provides valuable insights into the interplay between river floods and dikes on sediment transport, thereby enhancing our understanding of the repercussions of human interventions on sediment dynamics. Plain Language Summary: Global warming is expected to cause an increase in sea levels and a rise in the frequency and volume of river floods, which will change the delivery of riverine sediment to the ocean. Human construction of dikes for various purposes has also changed modern estuarine sediment transport patterns. These alterations are significant as they affect the natural sediment cycling of the Earth, influencing marine geology and marine ecosystems. Through a case study of the Ou River Estuary in southeastern China, numerical sensitivity tests have shown that dikes constructed along river channels disrupt natural flow patterns, resulting in decreased sediment transport to the sea and redirection toward deeper oceanic areas. The presence of dikes is crucial in their interaction with river floods on sediment transport. However, removing sections of dikes can help restore sediment transport to conditions without dikes. The increasing frequency, larger volumes, and faster discharge rates of river floods, as well as dam‐controlled river floods and rising sea levels, may all play a role in restoring natural sediment transport dynamics. This study examines how floods and dikes collectively impact sediment transport in estuaries with drainage areas larger than the estuary area. Key Points: A dike redirects sediment transport from the alongshore to the cross‐shore from the Ou River to the East China SeaMetrics are proposed to quantify the interaction between various river flood conditions and dike configurations on sediment transportFrequency, pattern, and duration of river floods, as well as partial dike removal and sea‐level rise, impact the interaction [ABSTRACT FROM AUTHOR]

Published

2024

18. Proterozoic mafic dyke swarms of Bundelkhand Craton, North India: A connection to Columbia supercontinent.

Author

Raju, S., Bodas, M. S., Anshu, R., and Neogi, Susobhan

Subjects

*DIKES (Geology), *PROTEROZOIC Era, *PETROLOGY, *GEOCHEMISTRY, *GEOLOGICAL time scales, *SUBDUCTION

Abstract

The present paper addresses petrography, geochemistry and Ar‐Ar geochronology of a significant number of mafic dykes from the Paleo‐ to Neoarchean Bundelkhand Craton in central India. The majority of the dykes are NW‐SE oriented (with a few NE‐SW and ENE‐WSW) with tholeiitic, sub‐alkaline and basalt to basaltic andesite composition. The trace element geochemistry of these dykes indicates an island arc setting during emplacement. The Ar‐Ar mineral dating (plagioclase) of three representative dykes reveals an emplacement age between 1.53 and 1.46 Ga. This finding and earlier reports (2.1–1.73 Ga) point to sustained mafic magmatism throughout the Bundelkhand Craton in a preferred structural orientation between 2.1 and 1.46 Ga. Mafic magmatism was episodic and can be linked to the perpetual subduction accretion processes between the central Indian Archean continents during the development of the Columbia supercontinent. The mafic dykes were emplaced at 45° to the maximum compression direction (E‐W), that is, along the line of no finite longitudinal strain. This time equivalent widespread NW‐SE and NE‐SW trending mafic dyke system is also relatable along the adjacent continents (Singhbhum, Bastar) and thus opened up a new paradigm for the dyke's emplacement across the Indian cratons. [ABSTRACT FROM AUTHOR]

Published

2024

19. Fracture evaluation of the plutonic basement in the Upper Magdalena Basin: Implications for the development of naturally fractured reservoirs in the Northern Andes.

Author

Rodríguez‐Cuevas, Maryi, Cardona, Agustín, Monsalve, Gaspar, Zapata, Sebastián, and Valencia‐Gómez, Juan Camilo

Subjects

*IGNEOUS intrusions, *ROCK deformation, *HYDROCARBON reservoirs, *BASEMENTS, *RESERVOIR rocks, *DIKES (Geology)

Abstract

Plutonic rocks typically have negligible matrix porosity and permeability. However, fractures and mineral alterations create storage space and flow pathways that turn plutonic rocks into fluid reservoirs. Despite significant hydrocarbon discoveries, naturally fractured reservoirs in plutonic rocks have been poorly studied. In most Colombian basins, the crystalline basement has undergone multiple deformational events and is thrust over the Cretaceous to Cenozoic source and reservoir rocks of the conventional petroleum system. This structural configuration is ideal for the migration of oil into a fractured basement. A multiscale fracture analysis, including field, petrographical and petrophysical techniques was conducted on the Permian and Jurassic plutonic basement of Upper Magdalena Basin in order to understand the controls on brittle deformation, the development of fracture networks and their potential to form hydrocarbon reservoirs. The results indicate that protolith textures and structures, including magmatic and mylonitic foliation, favours fracturing. Dykes exhibit higher fracture density (7–48 fractures/m), porosity (mean = 0.4%) and permeability (mean = 125,818.75 mD) than the host rock (2–25 fractures/m; 0.23%; 12,066.09 mD). Intersection zones from regional faults, are characterized by the highest fracture and lineament intensity. Our results suggest that dyke swarms and interacting damage zones can significantly enhance the reservoir quality of plutonic rocks by providing storage in fractures and fluid pathways to the host rock. [ABSTRACT FROM AUTHOR]

Published

2024

20. Reconstructing Single Side of Riverbanks Minimizes Adverse Effects on Sailfin Suckers' Habitat.

Author

Li, Pengcheng, Li, Yike, Han, Yu, Bao, Meixia, Wang, Yihang, and Yao, Weiwei

Subjects

*RIPARIAN areas, *FISH habitats, *HABITATS, *STREAM restoration, *FLOOD control, *DIKES (Geology), *HYDRODYNAMICS

Abstract

River reconstructions, encompassing flood and erosion control along with the restoration of fish habitat, can alter hydrodynamics within the constructed channel, thereby impacting fish habitat. This study aimed to assess the influence of specific river reconstruction practices, particularly spur dikes, on both hydrodynamics and fish habitat, to optimize the design of spur dike constructions for fish habitat restoration. The study utilized ecohydraulic modeling to examine the design of river reconstruction strategies and provide valuable insights on their efficacy, with a focus on refining these practices to enhance the suitability of habitat for Myxocyprinus asiaticus (Chinese Sailfin Sucker) in the Yangtze River. We used various flow rates and time periods to test hydrodynamic and habitat responses and long-term stability of the restoration schemes. The results suggested that the habitat quality of all the tested cases increased with flow rates and then decreased. Modelling results indicated a ranking of the habitat status from high to low in the following scenarios: baseline channel without riverbank constructions, with straight or T-shaped spur dikes installed on a single riverbank, and with straight or T-shaped spur dikes installed on both riverbanks. For post-effects of the restoration strategies, each approach would scour the riverbed. Installing spur dikes on both riverbanks would severely degrade the fish habitat suitability level, with the overall suitability index decreasing over time. In summary, installation of spur dikes along a single riverbank minimized the impact on the suitability of fish habitats and was the preferred scenarios to optimize habitat suitability for Chinese Sailfin Sucker. [ABSTRACT FROM AUTHOR]

Published

2024

21. Contrasting constraints on the temporal and spatial extents of normal faults from the Hilltop and Lewis mining districts, northern Shoshone Range, Nevada, USA.

Author

Richardson, Carson A. and Seedorff, Eric

Subjects

*MINING districts, *STRUCTURAL geology, *SEDIMENTARY rocks, *HYDROTHERMAL alteration, *GEOLOGICAL time scales, *DIKES (Geology)

Abstract

Mapping of rock types, structural geology, and hydrothermal alteration, supported by geochronology and thermochronology, sheds light on the original spatial relationships of hydrothermal systems to intrusions in the northern Shoshone Range in north-central Nevada. Rocks in the Hilltop district are tilted ~35–40°E, as indicated by orientations of flattened pumice fiamme and bedding in sedimentary rocks along a single set of presently low-angle normal faults that initiated at 60–70°W dips. New U-Pb zircon geochronology from two sets of dikes in the Lewis district could suggest late Eocene–early Oligocene extension, but definitive crosscutting relations are lacking to demonstrably support this potential earlier period of normal faulting. Reinterpretation of previously reported apatite fission-track cooling ages with a new palinspastic restoration in the Lewis mining district concurs with middle Miocene extension as documented to the south at the Caetano caldera; however, the depth of burial of the Lewis district—and thus the significance of the apatite fissiontrack cooling ages—is uncertain. The comparable orientations and tilting history, supported by fault scaling relations, suggest that the temporally coincident extension in the Caetano caldera to the south represents the along-strike continuation of the same system of normal faults as in the Hilltop and Lewis districts, with changes in observed offset, percent extension, and fault spacing attributed to the gradual tipping out of the fault system northward. [ABSTRACT FROM AUTHOR]

Published

2024

22. Multi‐geophysical methods for characterizing fractures in an open pit mine, western Bushveld Complex, South Africa.

Author

Rapetsoa, Moyagabo K., Gomo, Sikelela, Manzi, Musa S. D., James, Ian, Dildar, Jureya, Sihoyiya, Mpofana, Mutshafa, Ndamulelo, and Durrheim, Raymond J.

Subjects

*COMPOUND fractures, *SEISMIC reflection method, *ROCK slopes, *FAULT zones, *GEOPHYSICAL surveys, *SLOPE stability, *DIKES (Geology), *ELECTRICAL resistance tomography

Abstract

In the Bushveld Complex, South Africa, open pit mines are faced with a challenge of rock slope stability due to geological structures (fractures, faults and dykes) that compartmentalize the rock mass. Geophysical surveys (seismics, magnetics and electrical methods) were conducted in a 0.2 km2 area at Tharisa mine, with the goal to delineate fractures that may be potential conduits for water migration into the pit. Special processing techniques were applied to the dataset to obtain good quality seismic, magnetic and resistivity models. The P‐wave velocity models show distinct low velocities in the centre of the seismic profile, indicating the presence of weak zones associated with faulting or fracturing. Seismic reflection method was used to image the deeper discontinuities and mineralization contacts. Near surface reflections are observed throughout the profiles and are correlated with the contact between the chromitite and host rock. Ground magnetic surveys were conducted to delineate dykes and fractures. De‐trending and de‐culturing techniques were applied on the magnetic data for correcting regional and temporal variations. The low magnetic regions indicate the presence of fracture systems in the subsurface, whereas the high magnetic region is correlated with the dolerite dyke that crosscuts the pit. The electrical resistivity tomography exhibits linear low resistivity contrast zones that differentiate between the fractured and undisturbed hard rock at an estimated depth of 4–10 m. Resistivity shows discontinuities that suggests the presence of fracturing and dyke‐host rock contacts. Correlation among magnetics, P‐wave velocity models, resistivity section and seismic data is evident when overlaying the different datasets, implying that the low magnetic regions are highly weathered and prone to fracturing. The integration of geophysical data is encouraging, because it was able to image the depth to the bedrock, fractures within the host rock and dyke in a complex mining environment. [ABSTRACT FROM AUTHOR]

Published

2024

23. Placing constraints on the age and origin of basaltic dykes on the Ghaap Plateau, Griqualand West, South Africa.

Author

Ngobeli, R., Wabo, H., Vorster, C., and de Kock, M. O.

Subjects

IGNEOUS provinces, PETROLOGY, GEOLOGICAL time scales, MINERALOGY, GEOCHEMISTRY, DIKES (Geology)

Abstract

Well-preserved strata of the Ghaap Plateau along the western margin of the proto-Kalahari Craton have been intruded by a large number of mafic dykes. Owing to the scarcity of outcrops, these dykes are generally not well documented and intrusion ages remain poorly understood. In order to address this lack of knowledge, a total of seventeen Ghaap Plateau dykes that included seven north-northeast to northeast-trending dykes, eight northwest-trending dykes and two east to east-northeast-trending dykes were sampled for this study. Here, we report on the petrography and whole rock geochemistry of these dykes. We also report three new U-Pb baddeleyite ages along with some palaeomagnetic data. The mineralogy of the dykes is dominated by clinopyroxene and plagioclase showing varying degrees of alteration. Whole rock geochemical data identify the dykes as basalts with MORB, E-MORB or within plate-like signatures, suggesting an asthenospheric magma source. Our study indicates that the Ghaap Plateau dykes represent several magmatic events of markedly different age. Based on their whole rock geochemical composition, all but one of the dyke samples are tentatively arranged into four distinct groups (Groups A to D). Group A dykes (four dykes) are compositionally similar to the Umkondo Large Igneous Province (LIP). Two north-northeast-trending dykes of this Group yielded overlapping U-Pb baddeleyite ages of 1 103 ± 84 Ma and 1 112 ± 55 Ma, thereby adding to the known footprint of the Umkondo LIP along the western margin of the proto-Kalahari craton. In Group B (four dykes), one northeast-trending dyke yielded a U-Pb baddeleyite age of 1 929 ± 17 Ma. Its palaeomagnetic signature (Lat. 24.5°, Long. 317.6°, A95= 14.20°) is supported by a positive baked contact test and agrees well with the ~1.93 Ga Hartley LIP palaeopole. Group B dykes are thus interpreted to be related to the Hartley LIP, with our new 1 929 ± 17 Ma age supporting a wider extent for the Hartley magmatism than previously known. A new palaeopole for the Hartley LIP (Lat. 22.3°, Long. 327.4°, A95 = 9.25°) was calculated by combining the data of our 1 929 Ma dyke with data reported previously from other sites. Whole rock geochemical data for the remaining dykes are consistent with the Karoo magmatism (two east to east-northeast-trending dykes of Group D) or the ~2.4 Ga Ongeluk LIP (north-trending dyke). The final four dykes (Group C) are difficult to match with other known mafic units. Precise geochronology is needed to confirm the exact age of these unassigned dykes. [ABSTRACT FROM AUTHOR]

Published

2024

24. Tracking magma pathways and surface faulting in the Southwest Rift Zone and the Koaʻe fault system (Kīlauea volcano, Hawai 'i) using photogrammetry and structural observations.

Author

Mannini, Stefano, Ruch, Joël, Hazlett, Richard W., Downs, Drew T., Parcheta, Carolyn E., Lundblad, Steven P., Anderson, James L., Perroy, Ryan, and Oestreicher, Nicolas

Subjects

*FAULT zones, *VOLCANOES, *RIFTS (Geology), *MAGMAS, *PHOTOGRAMMETRY, *DIKES (Geology)

Abstract

Volcanic islands are often subject to flank instability, resulting from a combination of magmatic intrusions along rift zones and gravitational spreading causing extensional faulting at the surface. Here, we study the Koaʻe fault system (KFS), located south of the summit caldera of Kīlauea volcano in Hawaiʻi, one of the most active volcanoes on Earth, prone to active faulting, episodic dike intrusions, and flank instability. Two rift zones and the KFS are major structures controlling volcanic flank instability and magma propagation. Although several magmatic intrusions occurred over the KFS, the link between these faults, two nearby rift zones and the flank instability, is still poorly studied. To better characterize the KFS and its structural linkage with the surrounding fault and rift zones, we performed a detailed structural analysis of the extensional fault system, coupled with a helicopter photogrammetric survey, covering part of the south flank of Kīlauea. We generated a high-resolution DEM (~ 8 cm) and orthomosaic (~ 4 cm) to map the fracture field in detail. We also collected ~ 1000 ground structural measurements of extensional fractures during our three field missions (2019, 2022, and 2023). We observed many small, interconnected grabens, monoclines, rollover structures, and en-echelon fractures that were in part previously undocumented. We estimate the cumulative displacement rate across the KFS during the last 600 ~ 700 years and found a decrease toward the west of the horizontal component from 2 to 6 cm per year, consistent with GNSS data. Integrating morphology observations, fault mapping, and kinematic measurements, we propose a new kinematic model of the upper part of the Kīlauea's south flank, suggesting a clockwise rotation and a translation of a triangular wedge. This wedge is bordered by the extensional structures (ERZ, SWRZ, and the KFS), largely influenced by gravitational spreading. These findings illustrate a structural linkage between the two rift zones and the KFS, the latter being episodically affected by dike intrusions. [ABSTRACT FROM AUTHOR]

Published

2024

25. Petrogenesis and Tectonic Setting of the Baluogenguole Mafic Dykes, Zongwulong Belt: Implications for Evolution of the Northern East Paleo-Tethys Ocean.

Author

Chen, Min, Pan, Tong, Zhao, Wen-Tao, Wang, Yan-He, Xue, Chun-Ji, Wang, Bing-Zhang, and Xia, Chu-Lin

Subjects

*PALEOZOIC Era, *PETROGENESIS, *OCEAN, *URANIUM-lead dating, *FIELD research, *DIKES (Geology), *PLAGIOCLASE

Abstract

The late Paleozoic tectonic setting of the Zongwulong Belt (ZWLB), a significant unit located in the northern Qaidam margin, Qinghai province, remains uncertain. Diabase dykes in the western part of the Zongwulong Belt offer insights into this issue. Field investigations reveal that the dips of the dykes are almost vertical, and they have sharp boundaries with the host rocks. These dykes consist of plagioclase, clinopyroxene, and opaque minerals exhibiting a characteristic porphyritic texture and massive structure. Zircon U-Pb dating of the dykes yields a weighted 206Pb/238U age of 289 ± 1 Ma. The dykes exhibit relatively high concentrations of TFeO, K2O + Na2O, and TiO2, while the SiO2 and MgO concentrations are relatively low. They display relative light-over-heavy REE enrichment, and lack negative Nb-Ta and Eu anomalies. The dykes underwent negligible crustal contamination, and experienced extensive fractional crystallization of olivine, clinopyroxene, and Fe-Ti oxides. Originating from the spinel–garnet transition zone at depths of approximately 75 km, the dykes result from garnet facies low-degree melting (5%–10%) in a continental rift setting. Combining these findings with regional geological data, we propose that the ZWLB likely experienced a continental rift in the west and exhibited a narrow oceanic environment in the east in the late Paleozoic period, potentially representing the most distant north branch of the East Paleo-Tethys Ocean. [ABSTRACT FROM AUTHOR]

Published

2024

26. Mantle Sources and Geochemical Evolution of the Picture Gorge Basalt, Columbia River Basalt Group.

Author

Cahoon, Emily B., Streck, Martin J., Carlson, Richard W., and Bindeman, Ilya N.

Subjects

*BASALT, *FLOOD basalts, *GORGES, *GEOCHEMICAL modeling, *ISOTOPIC signatures, *VOLCANISM, *DIKES (Geology)

Abstract

The Columbia River Basalt Group (CRBG) is the youngest continental flood basalt province, proposed to be sourced from the deep-seated plume that currently resides underneath Yellowstone National Park. If so, the earliest erupted basalts from this province, such as those in the Picture Gorge Basalt (PGB), aid in understanding and modeling plume impingement and the subsequent evolution of basaltic volcanism. Using geochemical and isotopic data, this study explores potential mantle sources and magma evolution of the PGB. Long known geochemical signatures of the PGB include overall large ion lithophile element (LILE) enrichment and relative depletion of high field strength elements (HFSE) typical of other CRBG main-phase units. Basaltic samples of the PGB have 87Sr/86Sr ratios on the low end of the range displayed by other CRBG lavas and mantle-like δ18O values. The relatively strong enrichment of LILE and depletion of HFSE coupled with depleted isotopic signatures suggest a metasomatized upper mantle as the most likely magmatic source for the PGB. Previous geochemical modeling of the PGB utilized the composition of two high-MgO primitive dikes exposed in the northern portion of the Monument Dike swarm as parental melt. However, fractionation of these dike compositions cannot generate the compositional variability illustrated by basaltic lavas and dikes of the PGB. This study identifies a second potential parental PGB composition best represented by basaltic flows in the extended spatial distribution of the PGB. This composition also better reflects the lowest stratigraphic flows identified in the previously mapped extent of the PGB. Age data reveal that PGB lavas erupted first and throughout eruptions of main-phase CRBG units (Steens, Imnaha, Grande Ronde Basalt). Combining geochemical signals with these age data indicates cyclical patterns in the amounts of contributing mantle components. Eruption of PGB material occurred in two pulses, demonstrated by a ~0.4 Ma temporal gap in reported ages, 16.62 to 16.23 Ma. Coupling ages with observed geochemical signals, including relative elemental abundances of LILE, indicates increased influence of a more primitive, potentially plume-like source with time. [ABSTRACT FROM AUTHOR]

Published

2024

27. Petrology and lithogeochemistry of Paleozoic alkalic magmatism in the Selwyn Basin, Yukon, Canada.

Author

Scanlan, Emma J., Leybourne, Matthew I., Layton-Matthews, Daniel, Van Wagoner, Nancy, Paradis, Suzanne, Piercey, Steve, and Crowley, James L.

Subjects

*PETROLOGY, *RARE earth metals, *VOLCANIC ash, tuff, etc., *PALEOZOIC Era, *GEOCHEMISTRY, *MAGMATISM, *DIKES (Geology)

Abstract

Alkalic magmatism occurred in the Selwyn Basin, Yukon, Canada throughout the Paleozoic, concurrent with extension during passive margin sedimentation. To examine magmatism associated with this extension, geochemical data were obtained from several locations in the Selwyn Basin (MacMillan Pass, Anvil District, Keno Hill, and the Misty Creek Embayment). Volcanic rocks from the Anvil District and the Misty Creek Embayment are dominated by alkalic basalts with light rare earth element (LREE)-enriched geochemical signatures, whereas metavolcanic and dike samples from Keno Hill comprise subalkaline basalts with enriched mid-ocean ridge basalt (E-MORB) signatures. The Early Ordovician Menzie Creek volcanic rocks of the Anvil District display trace element geochemical signatures intermediate between ocean island basalt (OIB) and E-MORB, whereas the Middle–Late Ordovician volcanic rocks from the Misty Creek Embayment have OIB signatures. Differences in the trace element geochemistry of the sample suites are attributed to the degree of partial melting. The Menzie Creek volcanic rocks formed from large volume melts of enriched mantle that diluted incompatible element signatures in the Early Ordovician. Late Ordovician magmatism produced the Misty Creek Embayment samples, where restricted melt volumes of an enriched mantle source resulted in the most enriched samples geochemically. The Keno Hill samples represent the shallowest melting of the analysed samples and may have resulted from melting of heterogenous subcontinental lithospheric mantle. Magmatic zircons from a Keno Hill metavolcanic sample analysed by chemical abrasion thermal ionization mass spectrometry resulted in a primary deposition age of c. 296 ± 0.36 Ma (Early Permian), during a period with little magmatism in the Selwyn Basin and representing a previously unknown unit in the area. [ABSTRACT FROM AUTHOR]

Published

2024

28. Dynamics of the oceanic dike–gabbro transition revealed by petrology and geochemistry of the Yunzhug ophiolite, central Tibet.

Author

Liu, Tong, Liu, Chuan-Zhou, Zhang, Zhen-Yu, Zhang, Wei-Qi, Ji, Wen-Bin, Zhang, Chang, and Mitchell, Ross N.

Subjects

PETROLOGY, DIKES (Geology), DIABASE, GABBRO, PLAGIOCLASE, OCEANIC crust

Abstract

The dynamics and magma transport at the boundary between the upper and lower oceanic crusts (i.e., the dike–gabbro transition) are crucial for understanding the crustal accretion beneath mid-ocean ridges, which however have been studied at quite a few sites such as the East Pacific Rise and ophiolites like Troodos and Oman. Here we present detailed geological, petrological, and geochemical data for the dike–gabbro transition and associated basalts in the Yunzhug ophiolite, central Tibet, to constrain the complex magmatic processes in this specific horizon. The Yunzhug ophiolite contains a large (~ 20 km2) well-exposed sheeted dike complex, which is rooted in a dike–gabbro transition that consists of diverse lithologies, including diabase, gabbro, and minor porphyritic diabase. Petrographically, the Yunzhug gabbros could be grouped into the dominant Plg (plagioclase)-euhedral gabbros (euhedral–subhedral plagioclases enclosed in clinopyroxene oikocrysts) and a small amount of Cpx (clinopyroxene)-euhedral gabbros (with abundant euhedral clinopyroxenes). Plagioclases and their equilibrated melts of the two types of gabbros are similar, whereas clinopyroxenes and their equilibrated melts of the Cpx-euhedral gabbros are more primary and depleted than those of the Plg-euhedral gabbros. These petrographic and geochemical features suggest an earlier crystallization of clinopyroxene for the Cpx-euhedral gabbros, which is best explained by occasional water input in the magmatic system. Nevertheless, the modeled equilibrated melts of the two types of gabbros have compositions indistinguishable from the whole rock compositions of diabases and basalts, indicating a direct genetic linkage between these rocks. The unusual porphyritic diabases, on the other hand, provide evidence supporting for plagioclase accumulation and aggregation during magma upward migration, thus may have served as a unique way for magma to transport from the lower to upper crust. Studies of the Yunzhug ophiolite thus provide some key constraints on the complex magmatic processes in the oceanic dike–gabbro transition, regarding its dynamic accretion and magmatic plumbing mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

29. Banding in the Margins of Basaltic Dykes Indicates Pulsatory Propagation During Emplacement.

Author

Allgood, C., Llewellin, E. W., Humphreys, M. C. S., Mathias, S. A., Brown, R. J., and Vye‐Brown, C.

Subjects

*DIKES (Geology), *SURFACE of the earth, *VOLCANIC eruptions, *CRUST of the earth, *MAGMAS

Abstract

Basaltic fissure eruptions, which are the most common type of eruption on Earth, are fed by dykes which mediate magma transport through the crust. Dyke propagation processes are important because they determine the geometry of the transport pathway and the nature of any geophysical signals associated with magma ascent. Here, we investigate small‐scale (mm–cm wide) banding features at the margins of dykes in the Teno Massif (Tenerife, Spain) and the Columbia River Basalt Province (CRBP) (USA). Similar marginal bands have been reported for dykes in numerous localities around the world. Dyke margins record valuable information about propagation because they are the first material to solidify against the host rock at the propagating dyke tip. We find that the marginal bands are defined by cyclic variations in phenocryst concentration and vesicularity, and we infer that these cyclic variations in texture are a product of cyclic variations in magma flow rates and pressures within the dyke tip. This indicates that dyke emplacement occurs in pulses, with propagation repeatedly hindered by the rapid cooling and solidification of magma in the narrow dyke tip. Using a 1D conduction model, we estimate the time taken for each band to cool and solidify, which provides a timescale of several minutes to tens of minutes for the pulses. The occurrence of similar bands in various volcanic settings suggests that pulsatory propagation is a common, if not ubiquitous, process associated with dyke emplacement. Plain Language Summary: Dykes are cracks in the Earth's crust through which magma rises, sometimes feeding volcanic eruptions. Here, we investigate small‐scale banding features that are commonly found in solidified magma in dykes, using examples from the Teno Massif (Tenerife, Spain) and the Columbia River Basalt Province (USA). The bands form at the margin of the dyke, against the crack wall, which means that they record what happened when the dyke first formed; that is, when magma first flowed into the crack. We find that the bands are defined by repeated variations in the amount of crystals and bubbles, which we infer to have resulted from variations in magma flow rates and pressures in the dyke tip. This shows that the dykes formed in steps, rather than all in one go. By calculating the time taken for the bands to cool and solidify, we find that each propagation step lasts several minutes to tens of minutes. The occurrence of similar bands in various volcanic settings around the world suggests that most or all dykes form this way. This is important because the stepwise formation of the cracks might create small earthquakes that can be detected as the magma rises toward the Earth's surface. Key Points: Banded textures at dyke margins are the result of pulsatory magma flow in the tip of the propagating dykeDyke propagation is not continuous, but occurs in steps via a cycle of cooling, stalling, inflating, rupturing and propagatingCooling and solidification of magma in the narrow dyke tip has a strong influence on dyke propagation [ABSTRACT FROM AUTHOR]

Published

2024

30. Soft‐sediment deformation structures and Neptunian dykes across a carbonate system: Evidence for an earthquake‐related origin (Norian, Dolomia Principale, Southern Alps, Italy).

Author

Berra, Fabrizio

Subjects

*DIKES (Geology), *DEFORMATIONS (Mechanics), *SALT tectonics, *METEORITES, *SEDIMENTATION & deposition, *CARBONATES, *SEISMITES, *PALEOSEISMOLOGY

Abstract

Identification of the processes producing soft‐sediment deformation structures, common in siliciclastic deposits and less abundant in carbonate successions, is complex, because different processes may produce similar structures. Thus, interpreting the origin of these structures may be challenging: it requires both a detailed sedimentological study, and the knowledge of the depositional environment and stratigraphic evolution, in order to provide hints to identify the processes affecting sediments after deposition. Among the potential causes of the formation of soft‐sediment deformation structures, seismic shock is one of the possibilities, but their origin could be also related to other triggering mechanisms, such as volcanic activity, sediment loading, salt tectonics, fluid expulsion, meteorite impacts and mass movements. Although it is a plausible option, the interpretation of these structures as 'seismites' is not obvious: it must be supported by different lines of evidence, considering that the correct interpretation of soft‐sediment deformation structures as a consequence of seismic shocks acquires important implications in palaeoseismology studies. The occurrence of diverse soft‐sediment deformation structures in a fault‐controlled basin (i.e. in a geological setting characterized by syndepositional tectonics) preserved in different subenvironments of a Norian carbonate system in the Southern Alps of Italy provides the chance to characterize different types of soft‐sediment deformation structures along a platform‐to‐basin depositional profile. Presence of pseudonodules in basinal resedimented limestone, sedimentary dykes and clinostratified breccias with unlithified clasts in slope settings and liquefaction of inner platform facies at the platform top testify to an origin compatible with multiple seismic shocks, repetitively affecting the same stratigraphic intervals. The diverse types of soft‐sediment deformation structures in the studied carbonate system provide a rich catalogue of structures related to seismic shocks, representing a possible reference for other similar settings. [ABSTRACT FROM AUTHOR]

Published

2024

31. Age, origin and tectonic controls on rapid recent exhumation of the Sibela Mountains, Bacan, Indonesia.

Author

Hennig-Breitfeld, Juliane, Hall, Robert, White, Lloyd T., Breitfeld, H. Tim, Forster, Marnie A., Armstrong, Richard A., and Kohn, Barry P.

Subjects

*METAMORPHIC rocks, *IGNEOUS rocks, *DIKES (Geology), *NEOGENE Period, *FLEXURE, *SUBDUCTION, *SCHISTS

Abstract

The Sibela Mountains of the island of Bacan in eastern Indonesia contain one of the Earth's youngest metamorphic complexes that is now exposed at elevations up to 2000 m. New mica 40Ar/39Ar and apatite (U–Th–Sm)/He data from metamorphic and igneous rocks indicate that these rocks were rapidly exhumed in the Pleistocene (c. 0.7 Ma). Exhumation of the metamorphosed Permo-Triassic basement (c. 249–257 Ma) was accompanied by metamorphism (recorded by schists) as well as partial melting (recorded by c. 1.4 Ma granitic dykes). These processes must have occurred at extremely high cooling and exhumation rates. The rapid exhumation on land was associated with significant subsidence in adjacent basins offshore that reach depths up to 2.4 km. Neogene metamorphic core complexes and other metamorphic complexes are well-known from eastern Indonesia, but they usually record much higher exhumation rates than those reported from older classic metamorphic core complexes found in other parts of the world and require a different formation mechanism. Unlike classic metamorphic core complexes that are characterized by low-angle detachment faults, the Bacan metamorphic rocks were exhumed on steep bounding normal faults forming a rectilinear block pattern. We suggest such complexes are termed metamorphic block complexes (MBC). The Bacan MBC is exceptionally young and like the other east Indonesian complexes was rapidly exhumed during subduction rollback. A flexure formed during arc-arc collision as the Sangihe forearc loaded the Halmahera forearc which reactivated steeply-dipping faults in a rectilinear chocolate block pattern. [ABSTRACT FROM AUTHOR]

Published

2024

32. Experimental Study on Piping of Dike Foundation with Suspended Plastic Cutoff Wall Under Vertical Load.

Author

Feng, Ling-Yun, Liu, Han-Dong, and Chen, Jia-Xing

Subjects

NUMERICAL analysis, PLASTICS, MATERIAL plasticity, MUD, DATA analysis, DIKES (Geology)

Abstract

In this study, the influence of a vertical load on the deformation of a suspended plastic cutoff wall and the evolution of the piping of a dike foundation were studied through model tests and numerical analysis methods. The results of the numerical analysis were in good agreement with those of the model tests. Under vertical load and seepage force, the suspended plastic cutoff wall has well co-deformation with soil, and the mud permeable zone plays the role of "bridge"; the vertical load can increase the critical hydraulic gradient and failure hydraulic gradient and the corresponding upstream waterhead of dike foundation, and the influence of failure hydraulic gradient is greater than that of critical hydraulic gradient. In addition, the numerical analysis method obtains the distribution and variation in the hydraulic gradient along the piping channel from the pre-set orifice to the inlet, which provides reliable data support for the analysis of the evolution mechanism of dike foundation piping. The study also proves that the mud penetration belt plays a synergistic and auxiliary role in the prevention of dike foundation piping by the suspended cutoff wall, which provides strong support for further understanding of the mechanism of preventing dike foundation piping by the cutoff wall. [ABSTRACT FROM AUTHOR]

Published

2024

33. Fracturing and tectonic stress drive ultrarapid magma flow into dikes.

Author

Sigmundsson, Freysteinn, Parks, Michelle, Geirsson, Halldór, Hooper, Andrew, Drouin, Vincent, Vogfjörd, Kristín S., Ófeigsson, Benedikt G., Greiner, Sonja H. M., Yilin Yang, Lanzi, Chiara, De Pascale, Gregory P., Jónsdóttir, Kristín, Hreinsdóttir, Sigrún, Tolpekin, Valentyn, Friðriksdóttir, Hildur María, Einarsson, Páll, and Barsotti, Sara

Subjects

*DIKES (Geology), *MAGMAS, *STRESS fractures (Orthopedics)

Abstract

Many examples of exposed giant dike swarms can be found where lateral magma flow has exceeded hundreds of kilometers. We show that massive magma flow into dikes can be established with only modest overpressure in a magma body if a large enough pathway opens at its boundary and gradual buildup of high tensile stress has occurred along the dike pathway prior to the onset of diking. This explains rapid initial magma flow rates, modeled up to about 7400 cubic meters per second into a dike ~15-kilometers long, which propagated under the town of Grindavík, Southwest Iceland, in November 2023. Such high flow rates provide insight into the formation of major dikes and imply a serious hazard potential for high-flow rate intrusions that propagate to the surface and transition into eruptions. [ABSTRACT FROM AUTHOR]

Published

2024

34. Geochronology, geochemistry, and Sr–Nd isotopes of Permian dike swarms in the Beishan orogenic belt, southernmost Central Asian Orogenic Belt: Petrogenesis and implications for geodynamic setting.

Author

Peng, Ren, Zhang, Guishan, Zhao, Zhi-Qi, and Meng, Qiankun

Subjects

*OROGENIC belts, *GEODYNAMICS, *GEOCHEMISTRY, *GEOLOGICAL time scales, *RARE earth metals, *ADAKITE, *DIKES (Geology), *PETROGENESIS

Abstract

Permian mafic dikes crop out widely within Beishan area in the southernmost Central Asian Orogenic Belt (CAOB). These mantle-derived products provide important clues for elucidating the genesis and geodynamic setting of Permian magmatism. The mafic dikes within the Beishan area display zircons U–Pb ages of 281 ± 4 Ma. Characterized by low SiO2 (44.88–47.73 wt.%) and high Mg# values (62.2–68.6), the type 1 dikes are relatively depleted in light rare earth elements (LREEs; (La/Yb)n = 0.72–1.43) but enriched in large ion lithophile elements (LILEs). They show high positive εNd(t) values (6.6–8.5) with a range of (87Sr/86Sr)i (0.703477–0.705789) ratios. In contrast, the type 2 dikes have higher SiO2 content (47.47–51.13 wt.%) and lower Mg# (40.9–63.0). They are enriched in LREEs ((La/Yb)n = 1.79–5.02) and LILEs, and have lower εNd(t) values (3.8–7.4) with a variable range of (87Sr/86Sr)i (0.702873–0.706949) ratios. Thus, the type 1 dikes resulted from lower degrees of fractional crystallization and contamination than the type 2 dikes. Considering the LILEs and Pb enrichments, high field strength elements depletions, and high Ba/Th (86–460) ratios, the mantle source was metasomatized by subduction-related fluids. These dikes should be derived from high degrees (>20%) of partial melting of a Sr–Nd isotope-depleted, phlogopite-bearing spinel lherzolite lithospheric mantle according to their high Rb/Sr (0.04–0.24), low Ba/Rb (0.9–3.3), low La/Sm, and constant Sm/Yb ratios in addition to Sr–Nd depletion. Combined with the coeval evidence of regional geology and novel tectonic discriminate diagrams, we suggest that the mafic dikes in Beishan area formed in arc-related setting rather than intracontinental setting during the Permian. The metasomatized lithospheric mantle by subduction-related fluids were heated by upwelling asthenosphere mantle triggered by the slab roll-back, resulting in the formation of the parental magma of the mafic dikes. [ABSTRACT FROM AUTHOR]

Published

2024

35. Comment on 'The Generation of Eocene Mafic Dike Swarms During the Exhumation of a Core Complex, Biarjmand Area, NE Iran' by Azizi et al. (2023), Journal of Petrology, 64, 1–18.

Author

Malekpour-Alamdari, Ahmadreza

Subjects

*EOCENE Epoch, *PETROLOGY, *DIKES (Geology), *STRUCTURAL geology, *GRAVITATIONAL instability, *URANIUM-lead dating

Abstract

Azizi, H., Daneshvar, N., Asahara, Y., Minami, M. & Anma, R. (2023). The generation of Eocene mafic dike swarms during the exhumation of a Core complex, Biarjmand area, NE Iran. Journal of Petrology 64 , 1–18 have attributed the E–W-oriented mafic dike swarm in the Biarjmand metamorphic core complex to an Eocene extensional event which is much younger than a previously suggested Late Jurassic–Early Cretaceous age. They proposed that the emplacement of these dikes occurred in a rapid extensional regime coeval with the exhumation of the core complex after gravitational instability in the Central Iran/Eurasia collision zone. I appreciate the opportunity this article provides to shed light on specific aspects of the Late Mesozoic–Early Cenozoic continental extension within the Eurasian sector of the Neotethys subduction system. However, I here bring to attention certain discrepancies within Azizi et al. 's publication. Specifically, the assignment of an Eocene age to the emplacement of the E–W-oriented dike swarm, even though purportedly supported by U–Pb zircon dating, appears to be at odds with field observations and previously published geochronological data. Furthermore, the article contains internal contradictions in its presentation of the core complex model for the study area. It is important to note that Malekpour-Alamdari, A., Axen, G. J., Heizler, M. T. & Hassanzadeh, J. (2017). Large-magnitude continental extension in the northeastern Iranian plateau: insight from K-feldspar 40Ar/39Ar thermochronology from the Shotor Kuh-Biarjmand metamorphic core complex. Geosphere 13 , 1207–1233 previously documented the geochronological-based metamorphic core complex model of the area. Regrettably, despite its direct relevance, these earlier works have not been acknowledged in Azizi et al. 's paper. In this comment, I outline the problems with the structural and regional geology, the zircon U–Pb age of the dike samples, the age of the dike swarm, and the geodynamic interpretations in Azizi et al. 's work. [ABSTRACT FROM AUTHOR]

Published

2024

36. Petrology and Geochemistry of Highly Differentiated Tholeiitic Magmas: Granophyres in the Messejana–Plasencia Great Dyke (Central Iberia).

Author

Orejana, David, Villaseca, Carlos, Losantos, Emma, and Andonaegui, Pilar

Subjects

*PETROLOGY, *GEOCHEMISTRY, *MAGMAS, *GABBRO, *PLAGIOCLASE, *DIKES (Geology)

Abstract

The Messejana–Plasencia great dyke (MPGD) is a Late Triassic tholeiitic gabbro intrusion related to the Central Atlantic Magmatic Province. Its large outcrop extent (~530 km), combined with its prolongation below the Duero basin (additional 100 km), makes it one of the world's largest dykes known. We have studied felsic granophyric bodies appearing in its northernmost segment at different scales, from mm-sized (interstitial micrographic pockets) to felsic dykes of up to 10 m thick and 1.5 km long, intruding within the gabbros. Significant differences exist in the mineral and whole-rock composition of gabbros and granophyres, including the Sr–Nd isotopic ratios. The chemical variation in the gabbros is coherent with fractionation of olivine, clinopyroxene and plagioclase at depth. However, the presence of a compositional gap between gabbros and granophyres (absence of intermediate compositions) and the formation of these late-stage intergranular felsic melts within the gabbro mesostasis suggest that they could be derived by liquid immiscibility. The Sr–Nd isotopic heterogeneity in the MPGD gabbros and the presence of zircons with Variscan ages (~286 Ma), inherited from granulitic rocks, indicate that the mafic magmas experienced some degree of lower crust assimilation during fractionation close to the Moho depth. On the contrary, the scarce xenocrystic Variscan zircon crystals found in a granophyric dyke within the MPGD gabbro display similar textures and ages (~299 Ma) to those of the country rock granites and point to contamination at a different crustal level. [ABSTRACT FROM AUTHOR]

Published

2024

37. Morphotectonic and petrological characteristics of Permo-Triassic traps of Siberia.

Author

Sharapov, Victor, Perepechko, Yury, Mikheeva, Anna, Ashchepkov, Igor, Lyamina, Viktoria, and Boguslavsky, Anatoly

Subjects

*FLOOD basalts, *VOLCANOLOGY, *VOLCANIC ash, tuff, etc., *SEDIMENTARY basins, *MAGNETIC anomalies, *DIKES (Geology), *LITHOSPHERE

Abstract

The article reports morphotectonic and petrological characteristics of Permo-Triassic trap basalts covering the major part of Siberian Craton and its surroundings. Lavas, sills, and dykes are distributed in Taimyr, in the crystalline basement and Mesozoic cover of the West Siberian Plate and in Kara sedimentary basin. Investigations include relief analysis, seismotomographic data, magnetic and gravitational anomalies. Four sectors of magma-permeable zones were distinguished along the perimeter of the Anabar Shield in the Siberian craton. The western sector is characterized by an intensive fracturing and stretching where the Tunguska syncline filled by the flood basalt was formed. A striking feature of volcanism is the meridional petrochemical trend corresponding to increasing the silica (decreasing pressure) of basic magmas in volcanic and intrusive rocks of the Siberian Craton from the impact center, located at the North near Norilsk, to South regions – Kuzbass and Angara-Taseev regions. It corresponds to the thinning of the mantle keel, which coincides with the reduction of the volumes of erupted melts. This trend was determined for volcanics referring to the two major time events 252–244 and 238–232 Ma. Research highlights: Permo-Triassic traps of Siberia cover West Siberian Plate and Siberian Crat. Plum impact is located part near the Norilsk region. Diffused spreading developed in Tunguska syncline. Intensive volcanism concentrating along the deep faults. In the Northern part the dike belts and extended sill intrusions prevail. Tuffitic magmatism with higher silica dominated in the southern areas with the thinner lithospheric mantle. [ABSTRACT FROM AUTHOR]

Published

2024

38. Two episodes of late Mesoproterozoic magmatism in the southwestern Yangtze Block, China, and their association with Grenville-aged orogenic cycles.

Author

Yan-Jun Wang, Wei-Guang Zhu, Zheng-Xiang Li, Hong Zhong, Zhong-Jie Bai, Cheng-Biao Leng, and Jian-Bing Xu

Subjects

*SECONDARY ion mass spectrometry, *DIKES (Geology), *ZIRCON analysis, *MAGMATISM

Abstract

We report three sets of newly identified late Mesoproterozoic mafic intrusions in the southwestern Yangtze Block, China. Secondary ion mass spectrometry (SIMS) baddeleyite and zircon U-Pb analyses yield crystallization ages of ca. 1.15 Ga for the Boka dolerites, ca. 1.07 Ga for the Lanniping gabbros, and ca. 1.06 Ga for the Tong'an mafic dikes. These are tholeiitic to alkaline rocks with enriched mid-ocean-ridge basalt (E-MORB)-like trace-element patterns and superchondritic εNd(t) values, indicating a partial melting origin from the asthenospheric mantle. These results, along with existing data, define two episodes of late Mesoproterozoic, rift-related mafic magmatism in the southwestern Yangtze Block: an early phase at 1.17-1.14 Ga and a late phase at 1.07-1.02 Ga. Initiation of the two episodes of extensional events in the southwestern Yangtze Block coincided with high-grade Grenville-aged metamorphism in Hainan Island and possible early collision of Cathaysia with the southwestern Yangtze Block, indicating an impactogen model. Therefore, we interpret the observed two episodes to have resulted from local collision between the southwestern Yangtze Block and the Cathaysia Block (including Hainan Island), which was possibly a part of western Laurentia during the assembly of Rodinia. [ABSTRACT FROM AUTHOR]

Published

2024

39. Editorial for the Special Issue "Formation and Evolution of the Continental Crust in North China Craton during Precambrian".

Author

Liu, Jin, Qian, Jiahui, and Liu, Xiaoguang

Subjects

*IGNEOUS rocks, *SEDIMENTARY rocks, *MAFIC rocks, *URANIUM-lead dating, *SHEAR zones, *FELSIC rocks, *DIKES (Geology)

Abstract

This document is an editorial for a special issue of the journal Minerals, focusing on the formation and evolution of the continental crust in the North China Craton (NCC) during the Precambrian era. The NCC is a region with ancient rocks dating back to approximately 3.8 billion years ago and has experienced multiple magmatic and metamorphic events. The special issue includes 11 contributions that explore various aspects of the geological evolution of the NCC, such as the tectonic evolution of the Khondalite Belt, the Paleoproterozoic granitic dykes, felsic metavolcanic rocks, and meta-sedimentary rocks within the Jiao-Liao-Ji Belt, and the affinity between the NCC and the Alxa Block. The findings contribute to our understanding of the Archean and Paleoproterozoic evolution of the NCC, but further research is needed in areas such as magmatism, sedimentary processes, metamorphism, and structural analyses. [Extracted from the article]

Published

2024

40. Field geology, petrology and geochronology of pluton–dyke systems: emplacement conditions of the Trapecio and Ushuaia peninsula dyke swarms (Fuegian Andes) and their relations with tectonics.

Author

González Guillot, Mauricio, Torres Carbonell, Pablo J., Cao, Sebastián, Lobo, Constanza, Bordese, Sofía, and Hollanda, María-Helena B. M.

Subjects

*DIKES (Geology), *GEOLOGICAL time scales, *PETROLOGY, *GEOLOGY, *PENINSULAS, *ANDESITE

Abstract

We report the field geology, petrography, and geochemical and geochronological data for two dyke swarms in the Fuegian Andes, with the aim of correlating them with known suites and improving our knowledge of the magmatism of the Late Cretaceous rear arc and its relations with ductile deformation. We provide keys for correlation based on the K2O content of amphiboles. The Trapecio dyke swarm is mildly alkaline and ferriferous, with a zircon U–Pb age of 75 Ma, and therefore belongs to the Fuegian potassic magmatism (78–68 Ma). The Ushuaia peninsula dyke swarm, also known as the Ushuaia Peninsula Andesites, is shown to be high-K, calc-alkaline and magnesian, with new radiometric ages of 87–86 Ma. Although the Ushuaia peninsula dyke swarm exhibits foliation associated with ductile deformation, the Trapecio dyke swarm is post-kinematic and reveals emplacement controlled by the slaty cleavage in the metapelite host. Field and geophysical evidence suggest both swarms overlie small upper crustal plutons that are mostly buried. The variable composition of the dykes suggests a protracted history of dyke injection, mostly fed from deeper reservoirs. Contact metamorphism around both pluton–dyke systems is very weak. By comparison with adjacent plutons, we argue that the main variables controlling the development of the aureole are the small magma volumes and low rates of injection. Supplementary material: Full analytical procedures (Online Resource 1); detailed petrography of the investigated Trapecio dyke swarm samples (Table S1 and Fig. S1) with geochemical data (Table S3 and Fig. S2) (Online Resource 2); extended petrography and photomicrographs (Fig. S3) of the Ushuaia Peninsula Andesite dyke swarm (Online Resource 3); mineral chemistry data (Table S2) and the results of zircon U–Pb and hornblende Ar–Ar age measurements and ratios (Tables S4–S8) (Online Resource 4), and thermobarometric results (Table S9) (Online Resource 5) are available at https://doi.org/10.6084/m9.figshare.c.7097733 [ABSTRACT FROM AUTHOR]

Published

2024

41. Far-travelled 3700 km lateral magma propagation just below the surface of Venus.

Author

El Bilali, H. and Ernst, R. E.

Subjects

VENUS (Planet), DIKES (Geology), MAGMAS, SOLAR system, GEOLOGICAL strains & stresses, VOLCANOES

Abstract

The Great Dyke of Atla Regio (GDAR) is traced for ~3700 km on Venus, as a surface graben (narrow trough) interpreted to overlie a continuous laterally-emplaced underlying mafic dyke (vertical magma-filled crack). The GDAR belongs to a giant radiating dyke swarm associated with Ozza Mons (volcano), Atla Regio plume, and was fed from a magma reservoir ~600 km south of the Ozza Mons centre. A 50-degree counter-clockwise swing of the GDAR at 1200 km from the centre is consistent with a 1200 km radius for the underlying Ozza Mons plume head, and a stress link to the 10,000 km long Parga Chasmata rift system. Our discovery of the GDAR, should spur the search for additional long continuous single dykes on Venus (and Earth), with implications for estimating plume head size, locating buffered magma reservoirs, mapping regional stress variation at a geological instant, and revealing relative ages (through cross-cutting relationships) over regional-scale distances. In this study, the authors trace lateral magma movement in a ~ 3700 km long fracture on Venus. This Great Dyke of Atla Regio is the longest so-far traced on Venus (and in the solar system) and belongs to a giant radiating dyke swarm of the Ozza Mons volcano of the Atla Regio plume. [ABSTRACT FROM AUTHOR]

Published

2024

42. U–Pb geochronology and geochemistry of dikes in the Changbaishan Tianchi volcanic field (NE China) and their relations with the coeval Jingbohu and Longgang monogenetic volcanic fields.

Author

Xu, Zhitao, Sun, Liying, Ye, Xiqing, Ma, Fei, Yu, Chang, Chen, Zhaoxin, Li, Xuemei, and Pan, Xiaodong

Subjects

*VOLCANIC fields, *GEOCHEMISTRY, *GEOLOGICAL time scales, *DIKES (Geology), *BASALT, *VOLCANISM, *VOLCANOES, *RARE earth metals, *TRACE elements

Abstract

The plain around the intraplate Changbaishan Tianchi volcano in NE China includes monogenetic cones whose shallowest plumbing system consists of dikes, and three main phases of activity are recognized since 2.8 Ma. The monogenetic volcanism mainly developed in the shield-forming phase (2.8–0.3 Ma), but the age and geochemical features of many of these vents remain poorly known. Here, we present geochemical, Sr‒Nd‒Pb isotopic and zircon trace element data from two dikes feeding monogenetic vents located north and northwest of the Changbaishan Tianchi volcano. Our aim is to constrain the emplacement age, the magma evolution processes, and the mantle source. We compare our results with those from the Jingbohu and Longgang monogenetic vents located north and west of the Changbaishan Tianchi volcano to investigate possible mantle heterogeneities in the recent NE China volcanism. The two Changbaishan dikes have 230Th disequilibrium-corrected ages of 1.27 and 1.00 Ma and show a basaltic composition with a potassic affinity. The Mg# values are 35.48–34.27 and 66.09–65.79. The whole-rock compositions, trace element compositions, and Sr‒Nd variations are consistent with fractional crystallization and minor contamination with lower crustal material, indicating an OIB-like mantle source with an EMI component possibly related to fluids released from the underlying Pacific flat slab. The melting depth determined from Na/Ti and Sm/Yb is between 140 and 180 km, i.e. the asthenospheric mantle. The dikes are characterized by (K2O+Na2O)/δEu, La/Ba, Ba/Nb, La/Sm, and La/Nb values similar to those of the Jingbohu and Longgang basaltic rocks. We conclude that the NE China volcanism at approximately 1 Ma was related to a single, relatively homogeneous OIB-like mantle source modified by ascending slab-derived fluids. According to the available geophysical data, the ascending magmas stopped at the mantle/lower crust interface and experienced limited crustal contamination. [ABSTRACT FROM AUTHOR]

Published

2024

43. Molybdenite-bearing vugs in microgranite in the Preissac pluton, Québec, Canada: Relicts of aqueous fluid pockets?

Author

Mulja, Thomas and Williams-Jones, Anthony E.

Subjects

*FLUIDS, *STABLE isotopes, *DIKES (Geology), *IGNEOUS intrusions, *MUSCOVITE, *MOLYBDENUM, *BATHOLITHS

Abstract

Field, petrochemical, and stable isotope data from peraluminous microgranite dikes and their molybdenite-bearing vugs in the Archean Preissac-Lacorne batholith, Québec, provide evidence for the transport and deposition of molybdenum by an aqueous fluid that exsolved from a felsic magma. A model is proposed in which the microgranite-forming liquid fractionated from a magma that was parental to and intruded less-evolved muscovite monzogranite. Fluid saturation is interpreted to have occurred immediately prior to emplacement, allowing sufficient time for small spherical pockets of fluid to form and rise through the liquid but insufficient time for them to leave the system. These fluid pockets scavenged molybdenum and other components during their migration but were frozen in situ to form molybdenite-bearing vugs as a result of the quenching of the magma. We therefore conclude that the vugs are relicts of the exsolved fluid pockets and that the molybdenite in them reflects the concentration of molybdenum in the fluid, estimated from volumetric relationships to have reached ~7800 ppm. [ABSTRACT FROM AUTHOR]

Published

2024

44. Experimental Research on the Piping Development Process of a Typical Dike Foundation in Poyang Lake Area.

Author

LI Huo-kun, WANG Wen-tao, WANG Jiao, TANG Yi-yuan, WANG Xuan-zi, HU Qiang, XIONG Wei, HUANG Wei, and ZHU Hui-qi

Subjects

PORE water pressure, SOIL particles, SOIL erosion, OSMOTIC pressure, LAKES, DIKES (Geology)

Abstract

Dike foundation piping is one of the most important reasons for the dangerous situation and even the breach of dikes in Poyang Lake Area. It is of great significance to study and explain the disaster-causing mechanism of dike foundation piping in Poyang Lake Area from the mechanism so as to deal with the dangerous situation of piping and carry out emergency rescue scientifically.In this paper, an organic glass model tank is designed and manufactured, which integrates the functions of pore water pressure signal acquisition, seepage flow observation, erosion soil particle collection, graded constant head control, internal water circulation and so on. Based on the typical dike foundation structure of a dike in Poyang Lake Area, the physical model test of piping is carried out by using the prototype soil of dike foundation, and the whole process of piping occurrence, development and collapse of prototype multi-layer complex dike foundation is completely simulated. Combined with the experimental phenomena, the hydraulic conditions and soil particle erosion rate of the six stages (surface crack development stage, latent layer failure stage, overlying layer failure stage, piping channel upstream stage, embankment foundation failure stage, embankment foundation collapse stage ) in the process of piping occurrence and development are analyzed, and the special embankment foundation failure mechanism of the dike is explained by analyzing the effect of vertical seepage force.The results show that the piping failure in the dike foundation structure in Poyang Lake Area is concentrated in the underlying sand layer. Under the action of osmotic pressure, the overlying weak permeable layer is penetrated by seepage, and the piping channel is formed on the contact surface between the sand layer and the overlying layer, which accelerates the erosion of soil particles and eventually leads to the dike foundation collapse. The loam layer sandwiched in the clay layer in the embankment foundation of a typical dike in the Poyang Lake Area cannot play the role of the transition layer between the strong and weak permeable layers. The law of soil particle erosion is similar to that of the embankment foundation without the transition layer. The growth rate of the cumulative erosion of the soil particles forming the surface piping outlet and the embankment foundation cracking is less than 0.1 g/s; the average overall critical horizontal gradient of the dike foundation where piping occurs is about 0.1. [ABSTRACT FROM AUTHOR]

Published

2024

45. Ambient noise tomography of El Hierro island (Canary Islands).

Author

Cabrera-Perez, Ivan, Soubestre, Jean, D'Auria, Luca, Przeor, Monika, Garcia, Ruben, Barrancos, Jose, Padilla, German D., Perez, Nemesio M., Prudencio, Janire, Petrosino, Simona, and Di Luccio, Francesca

Subjects

SEISMIC wave velocity, ISLANDS, GEOPHYSICAL prospecting, TOMOGRAPHY, SEISMIC tomography, DIKES (Geology), VOLCANISM

Abstract

El Hierro island is one of the most active islands in the Canary Islands from a volcanological point of view. This is the reason why the imaging of the internal crustal structure is of huge importance. The geophysical exploration methods employed on El Hierro Island, such as gravimetry and seismic tomography, allowed obtaining the high-resolution characterization of the crust's deep part. However, these methods did not yield significant information about the surface and the shallower part of the crust. To gain a deeper insight into the shallow geological structure of El Hierro island, we employed Ambient Noise Tomography to construct a 3D S-wave velocity model. Our investigation revealed the presence of seven significant seismic velocity anomalies, partly identified by previous studies. We identified two high-velocity anomalies located in the eastern and western parts of the island at a depth between 0 and 3 km below sea level (b.s.l.). We interpreted these anomalies as dense intrusive complexes of dikes, possibly linked to the Tanganasoga volcano and the formation of the Tinor edifice. Additionally, we observed two high-velocity anomalies in the northern and southern parts of the island at a depth between 3 and 4 km b.s.l., which we related to the accumulation of solidified igneous rocks. On the other hand, a low-velocity anomaly was observed in the Golfo valley, between 0 and 0.5 km b.s.l., and we interpreted itas megalandslide deposits. This anomaly was evidenced for the first time in the present study. Finally, two low-velocity anomalies were observed in the southern part of the island at different depths, between 0-0.5 km b.s.l. and 0-2 km b.s.l. These were interpreted as fractures generated by Quaternary volcanism along the SSE Rift. Also, one of them was evidenced for the first time in this study, corresponding to the zone of the fractures produced during the Quaternary volcanism. This study has allowed us to gain a more detailed understanding of the shallow geological structure of the island. Even if most of the anomalies had been evidenced previously, we could observe the existence of two low-velocity zones in the shallow crust that have not been observed before. [ABSTRACT FROM AUTHOR]

Published

2024

46. Slab Subduction and Pull Link Magmatism at Active and Passive Continental Margins.

Author

Dai, Li‐Qun, Zhao, Kai, Zhao, Zi‐Fu, Sun, Guo‐Chao, Gong, Bing, and Ma, Li‐Tao

Subjects

*CONTINENTAL margins, *MAGMATISM, *SUBDUCTION, *PLATE tectonics, *DIKES (Geology), *LITHOSPHERE

Abstract

Subduction leads to voluminous arc magmatism at active continental margins; however, the potential far‐field geodynamic connections with coeval magmatism along opposing passive margins, are rarely investigated. Here we report large‐scale and parallel mafic dike swarms on the South Qinling passive margin, whose geochemical features record the thick and cold subcontinental lithospheric mantle beneath passive margin was gradually replaced by thin and hot one during the early Paleozoic. The subduction of the Proto‐Tethys oceanic lithosphere led to arc magmatism along the active margin, shortly after the rift‐related mafic dike swarms occurred along the passive margin. Subsequent to the continuous oceanic subduction including the ridge‐margin collision, mantle upwelling and slab rollback eventually triggered large‐scale rift‐related magmatism and the opening of new ocean basin at passive margin, and also back‐arc magmatism on the active margin. We highlight slab subduction and pull link the geodynamic processes at active and passive continental margins, which improves our understanding of plate tectonics. Plain Language Summary: Large‐scale alkali mafic dike swarms on the South Qinling passive continental margin are associated with a series of parallel faults. Based on the estimated pressures and temperatures of the mantle sources of these dike swarms, we found that the thick and cold subcontinental lithospheric mantle beneath the passive continental margin was gradually replaced by thin and hot one during the early Paleozoic. In addition, arc magmatism on the active margin would slightly precede the dike swarms in passive continental margin. We suggest that the subduction of the Proto‐Tethys oceanic lithosphere led to arc magmatism along the active margin, while rift‐related magmatism occurred along the passive margin of South Qinling. Subsequent to the continuous oceanic subduction including the ridge‐margin collision, mantle upwelling and slab rollback increased the tensional forces on the passive margin, eventually triggering large‐scale rift‐related magmatism and the opening of the ocean. Thus, we suggest the slab pull associated with subduction, and mantle upwelling geodynamicaly link the active and passive continental margin magmatism and leading to the opening of new ocean basins at passive margin. Key Points: Large‐scale parallel mafic dike swarms on South Qinling passive continental margin record thinning of the SCLM during PaleozoicArc magmatism on the active margin of North Qinling and Erlangping Arc slightly precede the dike swarms in South QinlingSlab subduction, pull and mantle upwelling geodynamicaly link the active and passive continental margins [ABSTRACT FROM AUTHOR]

Published

2024

47. Palaeomagnetic field intensity measurements from the 2.6 Ga Yandinilling dyke swarm (Western Australia).

Author

Hawkins, Louise M, Biggin, Andrew J, Liu, Yebo, Grappone, J Michael, and Li, Zheng-Xiang

Subjects

*DIPOLE moments, *DIKES (Geology), *PHANEROZOIC Eon, *SCANNING electron microscopy, *MAGNETIC fields, *ARCHAEAN

Abstract

Precambrian palaeointensity measurements provide fundamental constraints on the evolution of the deep Earth. Core evolution models predict trends in dipole moment on billion-year timescales that can be tested by palaeomagnetic records. Here, we report new palaeointensity results from the recently identified ∼2.62 Ga Yandinilling dyke swarm of the Yilgarn Craton, Western Australia, and consider them alongside published measurements spanning 500 Myr across the late Archaean to earliest Proterozoic. Rock magnetic and scanning electron microscopy analysis confirm that the magnetic mineralogy is fine-grained magnetite, appearing mostly as exsolved lamellae with ilmenite. Six sites produced acceptable palaeointensity estimates from thermal and microwave IZZI protocol Thellier experiments and from double-heating technique Shaw experiments. These site mean values of 9–26 µT translate to virtual dipole moments of 11–44 ZAm2 that are considerably lower than today's dipole moment of ∼80 ZAm2 and the value predicted for this time period by some thermal evolution models. Their average (median = 41 ZAm2) is, however, similar to the long-term average during both of the intervals 2300–2800 Ma (median = 44 ZAm2; N  = 103) and 10–500 Ma (median 41 ZAm2; N  = 997). While there is little evidence for a substantial net change in average dipole moment between the late Archaean and Phanerozoic, there is preliminary evidence that its variance has increased between the two intervals. This lower variance more than two billion years ago supports the idea that the geodynamo, even while not producing a stronger magnetic field, was more stable on average at the Archaean–Proterozoic transition than it is today. [ABSTRACT FROM AUTHOR]

Published

2024

48. Early Triassic Episode of the Kresty Volcano–Plutonic Complex Formation in the Maymecha-Kotuy Alkaline Province, Polar Siberia: Geochemistry, Petrology and Uranium–Lead Geochronology.

Author

Sazonov, Anatoly M., Gertner, Igor F., Mustafaev, Agababa A., Krasnova, Tatyana S., Kolmakov, Yurii V., Kingsbury, Cole G., and Gogoleva, Vera A.

Subjects

*GEOCHEMISTRY, *PETROLOGY, *GEOLOGICAL time scales, *RARE earth metals, *GEOLOGICAL research, *DIKES (Geology)

Abstract

The Kresty volcano–plutonic complex (KVPC) is one of the representatives of the alkaline–ultrabasic magmatism in the Maymecha-Kotuy Alkaline Province in Polar Siberia. The geological structure of the KVPC consists of intrusive formations of olivinite–pyroxenite and melilitolite–monticellitolite bodies, a series of rocks that break through dikes of trachydolerites, syenites, granosyenites, alkaline picrites and lamprophyres. This paper summarizes the results of the authors' long-term research on the geological structure and features of the material composition of the intrusive magmatic rocks, including geochemistry, mineralogy, distribution of rare earth elements (REE), as well as the results of isotope studies. The multielement composition of the KVPC intrusions demonstrates a complex geodynamic paleoenvironment of the formation as plume nature with signs of subduction and collision. For the ultrabasic series with normal alkalinity from the first phase of the KVPC, a Sm-Nd isochron age yielded an Early Triassic (T1) result of 251 ± 25 Ma. Here, we present U-Pb dating of zircons and perovskite of high-calcium intrusive formations and a dyke complex of alkaline syenites. Thus, for the intrusion of kugdite (according to perovskite), the age determination was 249 ± 4 Ma, and for the crosscutting KVPC dykes of syenites (according to zircon) 249 ± 1 Ma and 252 ± 1 Ma. The age of the most recent dike is almost identical to the age of the main intrusive phases of the KVPC (T1), which corresponds to a larger regional event of the Siberian LIP—251 Ma. According to isotopic Sr-Nd parameters, the main source of KVPC magmas is a PREMA-type material. For dyke varieties, we assume there was an interaction of plume melts with the continental crust. The new age results obtained allow us to further constrain the episodes of alkaline–ultrabasic intrusions in Polar Siberia, taking into account the interaction of mantle plume matter and crustal material. [ABSTRACT FROM AUTHOR]

Published

2024

49. Mafic Alkaline Magmatism and Rare Earth Element Mineralization in the Mojave Desert, California: The Bobcat Hills Connection to Mountain Pass.

Author

Watts, K. E., Miller, D. M., and Ponce, D. A.

Subjects

RARE earth metals, PASSING (Football), BOBCAT, MAGMATISM, DIKES (Geology), OXYGEN isotopes, DESERTS

Abstract

Occurrences of alkaline and carbonatite rocks with high concentrations of rare earth elements (REE) are a defining feature of Precambrian geology in the Mojave Desert of southeastern California. The most economically important occurrence is the carbonatite stock at Mountain Pass, which constitutes the largest REE deposit in the United States. A central scientific goal is to understand the genesis of the carbonatite ore body in the context of widespread REE‐rich igneous activity. A swarm of mafic alkaline (shonkinite) dikes has been mapped and sampled at Bobcat Hills, 65 km southeast of the Mountain Pass mine. Whole‐rock geochemistry and zircon geochronology demonstrate a clear affinity to the ca. 1.4 Ga Mountain Pass intrusive system. Bobcat Hills dikes have comparably high REE concentrations (La ∼1,000× chondritic) and an error‐weighted mean 207Pb/206Pb zircon crystallization age of 1,426 ± 2 Ma (2σ). Unlike the alkaline intrusions at Mountain Pass, which have abundant inherited zircon from Paleoproterozoic basement rocks and crustally influenced oxygen isotope compositions (δ18Ozircon = 6.5–7.5‰), the Bobcat Hills dikes lack any evidence of crustal assimilation and have oxygen isotope values that overlap a mantle range (Bobcat Hills average δ18Ozircon = 5.6 ± 0.3‰). The dikes were a high‐temperature, early center of mafic alkaline magmatism in the Mojave Desert that serve as a snapshot of melt generation from a spatially extensive, metasomatized mantle source. We propose that modification of the crust over many tens of Myr at Mountain Pass created an environment that favored crustal assimilation and enabled ascent of late‐stage, REE‐rich carbonatite magmas. Key Points: The Bobcat Hills site expands the distribution of REE‐rich mafic alkaline magmatism 65 km southeast of the Mountain Pass mineShonkinite dikes at Bobcat Hills are physically and chemically similar to mafic intrusions at Mountain Pass and have comparably high REEBobcat Hills was an early center of REE‐rich magmatism in the Mojave Desert, with a zircon U‐Pb crystallization age of 1,426 ± 2 Ma [ABSTRACT FROM AUTHOR]

Published

2024

50. Polyphase W-Sn mineralization and rare metal magmatism in relation to the late-Variscan tectono-metamorphic evolution of the southeastern French Massif Central.

Author

Harlaux, Matthieu, Marignac, Christian, Carr, Patrick A., Mercadier, Julien, Ballouard, Christophe, Jegal, Yujin, Kouzmanov, Kalin, Foucaud, Yann, Camacho, Alfredo, Cauzid, Jean, and Cuney, Michel

Subjects

NONFERROUS metals, RECRYSTALLIZATION (Geology), HYDROTHERMAL deposits, VEINS (Geology), CASSITERITE, DIKES (Geology)

Abstract

The southeastern French Massif Central represents an ideal area to study the linkage between regional metamorphism, crustal partial melting, emplacement of granitic magmas, and hydrothermal Sn-W mineralization in a polyphase tectono-metamorphic setting related to the late-Variscan orogeny. Here, we describe the mineralogical, structural, geochemical, and geochronological characteristics of cassiterite–wolframite-bearing quartz veins at St-Mélany, a small uneconomic Sn-W occurrence located in the North Cévennes area. The veins show evidence of ductile deformation (boudinage, asymmetric folding, dynamic recrystallization) consistent with a synkinematic emplacement during the regional low-pressure–medium-temperature metamorphism at ca. 320–315 Ma. This dominantly water-fluxed melting event reaching muscovite breakdown conditions (T < 750 °C, P ≈ 0.6 GPa) was synchronous to the emplacement of the syntectonic Rocles peraluminous granite, which is interpreted as a proximal source for the mineralizing fluids at St-Mélany. The U–Pb LA-ICP-MS dating of coexisting wolframite and cassiterite from a mineralized quartz vein yielded lower-intercept ages of 318.4 ± 2.2 Ma and 311.4 ± 1.0 Ma (2σ), respectively. These results suggest a temporal decoupling of W and Sn mineralization with a time gap of 4–10 Myr, but additional work is needed to confirm this interpretation. A weighted mean 40Ar/39Ar date of 304.5 ± 4.8 Ma (2σ) was obtained for muscovite from the selvage of a mineralized vein, interpreted as a recrystallization age related to metamorphic re-equilibration or hydrothermal overprinting. Dikes of aplites and pegmatites cut the Sn-W-mineralized veins and were emplaced at 305.9 ± 3.9 Ma (2σ) based on U–Pb LA-ICP-MS dating of magmatic cassiterite. The dikes have highly evolved compositions typical of peraluminous high-phosphorus rare metal granites with Li-F-Ta > Nb-Sn-Be enrichments. Emplacement of the granitic dikes was coeval with the regional low-pressure–high-temperature metamorphism at ca. 305–300 Ma, reaching biotite dehydration melting conditions (T > 800 °C, P ≈ 0.4 GPa), which led to the formation of the Velay anatectic dome possibly linked to lower crust granulitization. We conclude that polyphase emplacement of W-Sn-mineralized veins at ca. 320–310 Ma and rare metal granitic dikes at ca. 305 Ma results from contrasting crustal melting conditions, in relation to the late-Carboniferous orogenic evolution of the southeastern French Massif Central, and possibly related to delamination of the subcontinental lithospheric mantle. [ABSTRACT FROM AUTHOR]

Published

2024