The Low‐Temperature Besnus Magnetic Transition: Signals Due to Monoclinic and Hexagonal Pyrrhotite

Horng, Chorng‐Shern; Roberts, Andrew P.

doi:10.1029/2017gc007394

Cited by 33 publications

(60 citation statements)

References 67 publications

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“…The relative increases of the two parameters associated with the Besnus transition are less pronounced than what has been reported previously for MD and mechanically treated 4C pyrrhotite (Dekkers et al, ; Kind et al, ; Koulialias, Schäublin, et al, ; Rochette et al, ; Volk et al, ). Finally, the B c and M r / M S values of our SD 4C pyrrhotite at 300 K are similar to those of the multiphase nodules from recent and fossil methanic sedimentary deposits reported by Horng and Roberts (). The coercivities of these nodules, however, reveal a different temperature behavior with a pronounced increase down to T ≈ 50 K followed by nearly stable values, which contrast with the low‐temperature behavior of monoclinic 4C pyrrhotite.…”

Section: Resultssupporting

confidence: 88%

“…The coercivities of these nodules, however, reveal a different temperature behavior with a pronounced increase down to T ≈ 50 K followed by nearly stable values, which contrast with the low-temperature behavior of monoclinic 4C pyrrhotite. Horng and Roberts (2018) assigned this magnetic behavior to hexagonal 3C pyrrhotite. It is worth noting that in contrast to 4C pyrrhotite, the low-temperature, magnetic, and structural behavior of the 3C polymorph is not resolved so far, and therefore, the effect of changes in the stacking modulation on the Besnus transition remains unknown.…”

Section: Low-temperature Hysteresis Propertiesmentioning

confidence: 98%

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The Besnus Transition in Single‐Domain 4C Pyrrhotite

Koulialias

Lesniak

Schwotzer

et al. 2019

Geochem Geophys Geosyst

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The discontinuous change in magnetic properties at a temperature of about 32 K, denoted as the Besnus transition, is a diagnostic feature for detecting 4C pyrrhotite in geological systems. The transition is grain size dependent, and it has been assumed that the single‐domain (SD) to multidomain (MD) threshold is in the micron size range. Here we present a combined crystallographic and magnetic study of a pure phase, SD 4C pyrrhotite that was produced by ball milling of a MD precursor. The mechanical treatment generated varying grain sizes of less than 20 μm, which are solely in a SD magnetic state. It also decreases the coherent scattering domains of the grains from 216 nm in the MD sample to 30 nm, which is taken to set limits for the MD/SD threshold in 4C pyrrhotite grains. The alternating current susceptibility response associated with the Besnus transition is diagnostic for distinguishing SD and MD 4C pyrrhotite. The unambiguous identification of SD 4C pyrrhotite provides a better insight into its occurrence in geological systems.

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Section: Resultssupporting

confidence: 88%

Section: Low-temperature Hysteresis Propertiesmentioning

confidence: 98%

The Besnus Transition in Single‐Domain 4C Pyrrhotite

Koulialias

Lesniak

Schwotzer

et al. 2019

Geochem Geophys Geosyst

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“…The remanence does not recover totally during warming of RT‐SIRM. In the same zone (Z‐III) of NGHP‐01‐05C, the Besnus transition at ~35 K is typical of detrital pyrrhotite as evident in the RT‐SIRM cooling and the first derivative of magnetization curves (Dekkers, ; Horng & Roberts, ; Rochette et al, ; Figures i and j), but lack of such a transition is not diagnostic of authigenic pyrrhotite, which lacks a low‐temperature transition (Horng & Roberts, ). The remanence recovers totally during warming of the RT‐SIRM, which suggests the occurrence of a single domain pyrrhotite.…”

Section: Resultsmentioning

confidence: 98%

Magnetic Mineralogical Approach for the Exploration of Gas Hydrates in the Bay of Bengal

et al. 2019

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We evaluate the environmental magnetic, geochemical, and sedimentological records from three sediment cores from potential methane-hydrate bearing sites to unravel linkages between sedimentation, shale tectonics, magnetite enrichment, diagenesis, and gas hydrate formation in the Krishna-Godavari basin. Based on downcore rock magnetic variations, four sedimentary magnetic property zones (I-IV) are demarcated. A uniform band of enhanced magnetic susceptibility (zone III) appears to reflect a period of high-sedimentation events in the Krishna-Godavari basin. Highly pressurized sedimentary strata developed as a result of increased sedimentation that triggered the development of a fault system that provided conduits for upward methane migration to enter the gas hydrate stability zone, leading to the formation of gas hydrate deposits that potentially seal the fault system. Magnetic susceptibility fluctuations and the presence of iron sulfides in a magnetically enhanced zone suggest that fault system growth facilitated episodic methane venting from deeper sources that led to multiple methane seepage events. Pyrite formation along sediment fractures resulted in diagenetic depletion of magnetic signals and potentially indicates paleo sulfate-methane transition zone positions. We demonstrate that a close correlation between magnetic susceptibility and chromium reducible sulfur concentration can be used as a proxy to constrain paleomethane seepage events. Our findings suggest that the interplay between higher sedimentation events and shale tectonism facilitated fluid/gas migration and trapping and the development of the gas hydrate system in the Krishna-Godavari basin. The proposed magnetic mineralogical approach has wider scope to constrain the understanding of gas hydrate systems in marine sediments.

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“…No unambiguous rock‐magnetic evidence for pyrrhotite is provided in any samples from this study, but Kars et al () in their study of Site U1437 recognized a candidate for the Besnus transition of pyrrhotite (Dekkers et al, ; Rochette et al, ) at ~32 K in ZFC LTSIRM warming curves for samples in intervals with lower methane contents within the overall methane‐rich zone between fluid anomalies 6 and 8. Diagenetic pyrrhotite which forms in methanic sediments has been reported to lack a Besnus signature (Horng & Roberts, ), so the presence of diagenetic pyrrhotite in the methane‐rich zones cannot be ruled out.…”

Section: Discussionmentioning

confidence: 99%

Progressive and Punctuated Magnetic Mineral Diagenesis: The Rock Magnetic Record of Multiple Fluid Inputs and Progressive Pyritization in a Volcano‐Bounded Basin, IODP Site U1437, Izu Rear Arc

2019

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International Ocean Discovery Program (IODP) Site U1437 recovered an 1,800‐m‐long sediment sequence in a volcano‐bounded basin on the Izu rear arc. Pore fluid studies revealed a pattern of repeated fluid inputs, fluid diffusion, and methane and ethane accumulations, which represent “fluid anomalies” that disturb the fluid profiles. First‐order reversal curve analysis, magnetic hysteresis, saturation isothermal remanent magnetization, and low‐temperature remanence cycling reveal a detrital input dominated by vortex‐state and multidomain magnetite, which passes through an initial stage of partial magnetite dissolution and greigite authigenesis in the upper few tens of meters. Progressive magnetic mineral diagenesis comprises the continued loss of fine‐grained magnetite and gradual pyritization of greigite and produces a background logarithmic decrease in saturation isothermal remanent magnetization normalized by magnetic susceptibility. This process implies a continuing slow supply of S2− to depths >1,500 m. Thermally driven diagenesis, which would cause extensive loss of greigite at these depths, does not appear to be significant here. Multidomain magnetite grains dominate the magnetic mineralogy in the deepest part of the sequence, but some single‐domain magnetite survives as inclusions in silicates. Fluid anomalies representing sulfate influx drive locally renewed greigite authigenesis, as do methane and ethane accumulations. In some cases, where methane is accompanied by H2S (“sour gas”), fine‐grained greigite is converted to pyrite. We term these multiple episodes of enhanced magnetic mineral alteration “punctuated magnetic mineral diagenesis.” Despite both progressive and punctuated magnetic mineral diagenesis, enough depositional remanence survives to allow recognition of the magnetostratigraphy to 1,320 m below seafloor.

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The Low‐Temperature Besnus Magnetic Transition: Signals Due to Monoclinic and Hexagonal Pyrrhotite

Cited by 33 publications

References 67 publications

The Besnus Transition in Single‐Domain 4C Pyrrhotite

The Besnus Transition in Single‐Domain 4C Pyrrhotite

Magnetic Mineralogical Approach for the Exploration of Gas Hydrates in the Bay of Bengal

Progressive and Punctuated Magnetic Mineral Diagenesis: The Rock Magnetic Record of Multiple Fluid Inputs and Progressive Pyritization in a Volcano‐Bounded Basin, IODP Site U1437, Izu Rear Arc

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