Your search keyword '"Mid-ocean Ridge"' showing total 3 results

1. Discovery of Active Hydrothermal Vent Fields Along the Central Indian Ridge, 8–12°S.

Author

Kim, Jonguk, Son, Seung‐Kyu, Kim, Dongsung, Pak, Sang‐Joon, Yu, Ok Hwan, Walker, Sharon L., Oh, Jihye, Choi, Sun Ki, Ra, Kongtae, Ko, Youngtak, Kim, Kyeong‐Hong, Lee, Jun‐Ho, and Son, Juwon

Subjects

HYDROTHERMAL vents, BIOGEOGRAPHY, ABYSSAL hills, MINERALIZATION

Abstract

Four new hydrothermal vent fields were discovered on the slow spreading Central Indian Ridge (8–12°S; Segments 1–3), all located off‐axis on abyssal hill structures or Ocean Core Complexes (OCCs). Each site was characterized using seafloor observation (towed camera system), plume chemistry (Fe, Mn, and CH4; Conductivity, Temperature, and Depth sensor [CTD]/Miniature Autonomous Plume Recorder [MAPR]), and rock sampling (TVgrab/dredges). Different styles of venting on each segment reflect different geological settings, rock types, likely heat sources, and fluid pathways. The segment 1 field was located on the western flank of the axial valley at the base of OCC‐1‐1. High‐temperature venting was inferred from plume characteristics and extensive seafloor sulfide mineralization, but only diffuse venting was observed. This site appears to be a magmatic‐influenced basaltic‐hosted system despite its off‐axis location. Two low‐temperature diffusely venting sites were located on abyssal hills 6 and 9 km off‐axis on Segment 2. Plume particle, metal, and CH4 concentrations were all very low, suggesting dilution of hydrothermal fluids by intrusion of seawater into the highly permeable flank area fault zone. The "Onnuri Vent Field" (OVF), located at the summit of OCC‐3‐2, vented clear, low‐temperature fluids supporting abundant vent organisms (21 macrofaunal taxa). The plume particle signal was low to absent, but strong ORP anomalies correlated with high CH4 and low metal concentrations. Sulfide mineralization was present, which suggests both serpentinization and magmatic/lithospheric influence on fluid composition. The detachment fault is the likely pathway for hydrothermal fluid circulation at this off‐axis location. These new vent field discoveries, especially the OVF, contribute valuable information toward understanding Indian Ocean hydrothermal systems and their ecology/biogeography. Plain Language Summary: We discovered four new hydrothermal vent fields along the slow spreading Central Indian Ridge. The different styles of hydrothermal venting discovered at each site reflect the different geological settings, types of surrounding rocks, and likely heat sources driving the hydrothermal circulation. Among the new vent fields, the "Onnuri Vent Field" is particularly interesting because the isolated location, unique style of venting, and abundant vent biology provide valuable new information for understanding vent ecology and biogeography of the Indian Ocean. Key Points: Four new hydrothermal vent fields were discovered along the Central Indian Ridge, 8–12°S, all off‐axisA particle‐poor, diffuse vent field with abundant vent fauna was located on an OCC at a nontransform discontinuityChemical compositions of the plumes reveal both basaltic‐ and ultramafic‐hosted hydrothermal systems [ABSTRACT FROM AUTHOR]

Published

2020

2. Gravity anomalies over the Central Indian Ridge between 3S and 11S, Indian Ocean: Segmentation and crustal structure.

Author

Samudrala, Kiranmai, Kamesh Raju, K, and Rao, P

Subjects

*GRAVITY anomalies, *GEOPHYSICS, *BATHYMETRY, *PLATE tectonics, *MARINE ecology

Abstract

High-resolution shipboard geophysical investigations along the Indian Ocean ridge system are sparse especially over the Carlsberg and Central Indian ridges. In the present study, the shipboard gravity and multibeam bathymetry data acquired over a 750 km long section of the Central Indian Ridge between 3 S and 11 S have been analysed to understand the crustal structure and the ridge segmentation pattern. The mantle Bouguer anomalies (MBA) and the residual mantle Bouguer anomalies (RMBA) computed in the study area have shown significant variations along the ridge segments that are separated by transform and non-transform discontinuities. The MBA lows observed over the linear ridge segments bounded by well-defined transform faults are attributed to the thickening of the crust at the middle portions of the ridge segments. The estimates of crustal thickness from the RMBA shows an average of 5.2 km thick crust in the axial part of the ridge segments. The MBA and relative RMBA highs along the two non-transform discontinuities suggests a thinner crust of up to 4.0 km. The most significant MBA and RMBA highs were observed over the Vema transform fault suggesting thin crust of 4 km in the deepest part of the transform fault where bathymetry is more than 6000 m. The identified megamullion structures have relative MBA highs suggesting thinner crust. Besides MBA lows along the ridge axis, significant off-axis MBA lows have been noticed, suggesting off-axis mantle upwelling zones indicative of thickening of the crust. The rift valley morphology varies from the typical V-shaped valley to the shallow valley floor with undulations on the inner valley floor. Segments with shallow rift valley floor have depicted well-defined circular MBA lows with persistent RMBA low, suggesting modulation of the valley floor morphology due to the variations in crustal thickness and the mantle temperature. These are supported by thicker crust and weaker lithospheric mantle. [ABSTRACT FROM AUTHOR]

Published

2016

3. Mercury proxy for hydrothermal and submarine volcanic activities in the sediment cores of Central Indian Ridge.

Author

Lim D, Kim H, Kim J, Jeong D, and Kim D

Subjects

Environmental Monitoring, Geologic Sediments, Indian Ocean, Hydrothermal Vents, Mercury analysis

Abstract

Hydrothermal vent is the one of the main natural Hg sources to the deep ocean. Thus, we investigated which Hg speciation in the sediment core can be the past records for geothermal activities in mid-ocean ridges of the Central Indian Ocean. The result showed that the hydrothermal Hg in the core sediments was mainly associated with Fe-Mn oxides with the elevated concentrations of other hydrothermal-derived trace metals [Co + Zn + Cu]. In addition, the [Sm]/[Nd] and [Rb]/[Sr] ratios and ɛNd CHUR and 87 Sr/ 86 Sr isotopic values supported that the extremely high Hg concentrations were possibly originated from the hydrothermal vent. However, the Hg emitted from submarine volcano was mainly associated with sulfides-organic matters because the volcanos did not release Fe and Mn. Thus, our results showed that the sedimentary Hg is an independent toll for reconstruction of paleodynamics of hydrothermal and/or volcanic activities in deep sea basin of the Central Indian Ocean., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020