Magnetic minerals in three Asian rivers draining into the South China Sea: Pearl, Red, and Mekong Rivers

Magnetic minerals in marine sediments are sensitive indicators of processes such as provenance changes, climatic controls, pollution, and postdepositional geochemical changes. Magnetic susceptibility is the bulk property of the sediments most commonly used to understand the magnetic characteristics of sediments. Before conclusions can be drawn from changes in this parameter, it is important to understand what factors and to what extent control changes in magnetic susceptibility. The magnetic susceptibility of surficial sediments in the Galician Rias Baixas, in NW Spain, has been shown to covary with sediment texture and organic matter content. Downcore, the magnetic properties of these sediments experience drastic changes as a result of strong dissolution caused by early diagenesis. In this paper, we further explore the relationship between these factors and formalize the observed covariations as the result of a simple second‐order kinetic model dependent on the content of organic matter in surficial sediments in the Ria de Muros. The reanalysis of previously reported data from the Rias de Vigo and Pontevedra confirmed the validity of this model and suggested further controls such as wave climate and water depth in the rates at which magnetic susceptibility changes are controlled by organic matter content.

Section: Introductionmentioning

confidence: 99%

A kinetic model to explain the grain size and organic matter content dependence of magnetic susceptibility in transitional marine environments: A case study in Ria de Muros (NWIberia)

Mohamed

Andrade

Rey

et al. 2017

“…These cores lie to the northeast of PC338 and are mostly supplied by the Pearl and Taiwan Rivers, with stable and relatively high magnetite contents compared to hematite (Kissel et al, ; Ouyang et al, ). For most surficial sediments, Red River S −300 values (0.7–0.9) are lower than those of the Pearl (0.85–1) and Taiwan Rivers (>0.9), which indicates relatively high hematite contents for the Red River (Kissel et al, ; Nguyen et al, ). Therefore, it seems that Red River‐sourced sediment lowered S –300 during the ∼32–15 kyr B.P.…”

Section: Discussionmentioning

confidence: 99%

“…The magnetic properties of SCS sediments are analyzed in combination with geochemical and grain size data that are sensitive to paleoclimate variations (e.g., Bloemendal et al, 1988;Boulay et al, 2003;Kars et al, 2017;Kissel et al, 2003;Wei et al, 2004). Our results are also compared with magnetic property data for sediments from adjacent rivers and estuaries (Kissel et al, 2016Nguyen et al, 2016;Ouyang et al, 2013Ouyang et al, , 2017.…”

Section: Key Pointsmentioning

confidence: 99%

Influence of Sea Level Change and Centennial East Asian Monsoon Variations on Northern South China Sea Sediments Over the Past 36 kyr

Ouyang

Roberts

et al. 2018

South China Sea (SCS) sediments can provide important paleoclimate records because of their generally high deposition rates and strong regional influence of East Asian summer monsoon (EASM) variations. However, interpretation of sedimentary records from the northwestern SCS slope is complicated because sedimentation is sensitive to sea level and provenance variations. We seek to develop a paleoclimatic record of SCS sediments by analyzing sediment magnetic properties over the past ∼36 kyr from core PC338. The dominant magnetic minerals are magnetite and hematite in most parts of the core. The hematite concentration increased profoundly over the ∼15–32 kyr B.P. period when sea level was lower than −90 m below the present level. This suggests that Red River inputs were enhanced significantly in this period. Moreover, increased coarse magnetite contents were recorded in association with an enhanced East Asian winter monsoon (EAWM) during the Last Glacial Maximum and Heinrich event 1. Low‐field and frequency‐dependent magnetic susceptibility variations were coeval with EASM‐controlled climate change recorded in South China and the SCS over the past 15 kyr, probably because regional terrestrial weathering and erosion of iron‐bearing minerals, and their transportation are dominated by climate. Rhythmic coarsening of Holocene magnetic mineral concentrations coincided with global cooling events, which indicates that core PC338 also contains signals of enhanced EAWM variations. The study demonstrates that magnetic proxies are indicative of sediment supply and deposition variations on the SCS continental slope that are useful for understanding the effects of sea level and climate change on SCS sediments.

“…The main magnetic minerals observed in the river samples from all around the SCS are magnetite and hematite with some pyrrhotite contribution around Taiwan (Kissel et al, , ). At sea, pyrrhotite is mainly identified in core tops from the Taiwan Strait (Horng & Huh, ; Horng et al, ) and it probably deposits on the shelves together with illite and chlorite characterizing the Taiwanese clay source (Z. Liu et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…So far, besides the mapping of the low field magnetic susceptibility in particular on the shelves by J. Liu et al () and in the southern basin by Z. Chen et al () for the specific study of hydrocarbon‐bearing zones, only the clay minerals have been analyzed in widely distributed core tops and compared to river clay composition (Z. Liu et al, , and references therein). As shown by the coupled analyses of the clay and magnetic fractions in river sediments, the two proxies carry complementary information about the provenance area (Kissel et al, , ; Z. Liu et al, ).…”

Section: Discussionmentioning

confidence: 99%

Magnetic Fingerprints of Modern Sediments in the South China Sea Resulting From Source‐to‐Sink Processes

Kissel

Sarnthein²,

Làj

et al. 2018

More than 650 Mt/year of fluvial sediment are delivered from continental regions into the South China Sea (SCS). Previous studies have shown that the composition of the magnetic fraction of riverine sediments drained into the SCS is significantly variable from north to south. On the basis of this evidence, we now examine a full set of magnetic properties for a number of core tops taken at water depth of mostly between 800 and 3,500 m. Room temperature magnetic parameters and thermal spectra are used to obtain information about the concentration and mineralogical magnetic composition. Spatial changes are observed in the relative proportion of magnetite and hematite with an increase of the latter toward the south, similarly to the observation on land. However, the N‐S contrast is much weaker in marine core tops than in river sediments, because of the role played by the shelf in partly trapping river‐borne sediments, in particular in the southern SCS. In part, sediments also reach the continental slope and the deep basins, being transported and mixed by surface and deepwater currents, which yield the magnetite‐hematite mixing in the south. For the first time, we characterize a wide spectrum of magnetic properties of modern marine sediment in the SCS. Our results give important insights into the modern pathways of sediment particles, depicting the source‐to‐sink processes that affect the terrigenous sediment load.