Magnetic mineralogy of the Mercurian lithosphere

Strauss, B. E.; Feinberg, Joshua M.; Johnson, C. L.

doi:10.1002/2016je005054

Cited by 11 publications

(10 citation statements)

References 107 publications

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“…As mineral magnetism aims to broaden its reach, contributing for example to the study of the formation of the solar system (e.g., Strauss et al, 2016;Wang et al, 2017), of deep-time terrestrial environments (e.g., Carlut et al, 2015;Slotznick and Fischer, 2016) or of extreme environments of hydrothermal vents (e.g., Toner et al, 2016), it is necessary to accompany these new frontiers with experimental tools adapted to the greater diversity of mineral compositions and greater complexity of mineral assemblages resulting from the superposition of geological and biogeochemical processes through time. Magnetic characterization presents the advantages of a low detection limit (order of 1 ppm) and in situ bulk sample analyses avoiding time consuming physical and chemical separation techniques shown to be biased (e.g., Lagroix et al, 2004;Wang et al, 2013).…”

Section: New Frontiers For Earth and Planetary Sciences Through Minermentioning

confidence: 99%

A New Tool for Separating the Magnetic Mineralogy of Complex Mineral Assemblages from Low Temperature Magnetic Behavior

Guyodo

2017

Front. Earth Sci.

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One timeless challenge in rock magnetic studies, inclusive of paleomagnetism and environmental magnetism, is decomposing a sample's bulk magnetic behavior into its individual magnetic mineral components. We present a method permitting to decompose the magnetic behavior of a bulk sample experimentally and at low temperature avoiding any ambiguities in data interpretation due to heating-induced alteration. A single instrument is used to measure the temperature dependence of remanent magnetizations and to apply an isothermal demagnetization step at any temperature between 2 and 400 K. The experimental method is validated on synthetic mixtures of magnetite, hematite, goethite as well as on natural loess samples where the contributions of magnetite, goethite, hematite and maghemite are successfully isolated. The experimental protocol can be adapted to target other iron bearing minerals relevant to the rock or sediment under study. One limitation rests on the fact that the method is based on remanent magnetizations. Consequently, a quantitative decomposition of absolute concentration of individual components remains unachievable without assumptions. Nonetheless, semi-quantitative magnetic mineral concentrations were determined on synthetic and natural loess/paleosol samples in order to validate and test the method as a semi-quantitative tool in environmental magnetism studies.

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Section: New Frontiers For Earth and Planetary Sciences Through Minermentioning

confidence: 99%

A New Tool for Separating the Magnetic Mineralogy of Complex Mineral Assemblages from Low Temperature Magnetic Behavior

Guyodo

2017

Front. Earth Sci.

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“…Although the hermean surface is generally much poorer in iron than the lunar surface, it has been argued that even for the extreme endmember case where the surface of Mercury has no native FeO, the iron brought in by meteorites should be sufficient to produce significant amounts of npFe 0 through vapor fractionation (Noble and Pieters 2003). The formation of npFe 0 might also be responsible for the observed remnant crustal magnetization (e.g., Johnson et al 2015;Strauss et al 2016). Thus, understanding the effects of space weathering on MERTIS spectra is critical for their accurate interpretation and justifies a comprehensive laboratory program that simulates SW by short-pulsed lasers, ion bombardment, and shock recovery experiments on various minerals and their mixtures (Weber et al 2019.…”

Section: Effects Of Space Weatheringmentioning

confidence: 99%

Studying the Composition and Mineralogy of the Hermean Surface with the Mercury Radiometer and Thermal Infrared Spectrometer (MERTIS) for the BepiColombo Mission: An Update

et al. 2020

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Launched onboard the BepiColombo Mercury Planetary Orbiter (MPO) in October 2018, the Mercury Radiometer and Thermal Infrared Spectrometer (MERTIS) is on its way to planet Mercury. MERTIS consists of a push-broom IR-spectrometer (TIS) and a radiometer (TIR), which operate in the wavelength regions of 7-14 μm and 7-40 μm, respectively. This wavelength region is characterized by several diagnostic spectral signatures: the Christiansen feature (CF), Reststrahlen bands (RB), and the Transparency feature (TF), which will allow us to identify and map rock-forming silicates, sulfides as well as other minerals. Thus, the instrument is particularly well-suited to study the mineralogy and composition of the hermean surface at a spatial resolution of about 500 m globally and better than 500 m for approximately 5-10% of the surface. The instrument is fully functional onboard the BepiColombo spacecraft and exceeds all requirements (e.g., mass, power, performance). To prepare for the science phase at Mercury, the team developed an innovative operations plan to maximize the scientific output while at the same time saving spacecraft resources (e.g., data downlink). The upcoming fly-bys will be excellent opportunities to further test and adapt our software and operational procedures. In summary, the team is undertaking action at multiple levels, including performing a comprehensive suite of spectroscopic measurements in our laboratories on relevant analog materials, performing extensive spectral modeling, examining space weathering effects, and modeling the thermal behavior of the hermean surface.

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“…Such a distinction on the basis of paleopole estimates could only be possible if the paleopoles, accounting for their location uncertainties, are estimated to lie northward of 70°S. On the other hand, metal iron is the probable magnetic carrier present in Mercury's surface (Strauss et al, ). In addition, the abundance of metal iron present in the crater melt sheet is constrained by the crater's size.…”

Section: Discussion: Constraining the Early History Of Mercurymentioning

confidence: 99%

Constraining the Early History of Mercury and Its Core Dynamo by Studying the Crustal Magnetic Field

2019

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Low‐altitude magnetic field data acquired by MESSENGER (MErcury Surface, Space ENvironment, GEochemistry, and Ranging) over a small portion of Mercury's surface revealed weak crustal magnetic field signatures. Here we study the crustal magnetic anomalies associated with impact craters on Mercury. We assume that the sources of these anomalies consist of impact melt, enriched in impactor iron. We assume that the subsurfaces of Mercury's impact craters have cooled in the presence of a constant global magnetic field, thus becoming thermoremanently magnetized. We invert for the crustal magnetization direction within five craters using a unidirectional magnetization model which assumes that the melt impact rocks recorded the constant core magnetic field present when the crater was formed and that the crater's magnetization has not been altered since its formation. From the best fitting magnetization direction we then obtain the corresponding north magnetic paleopole position assuming a centered core dipolar field. Results show that all five magnetic paleopoles lie in the southern hemisphere but are not required to be located near the present‐day magnetic pole, which lies near the south geographic pole. Accounting for the uncertainties, we show that our results all agree in a common small region that excludes the current magnetic pole. This strongly suggests that the dynamo has evolved with time. Our results represent valuable information for understanding the evolution of Mercury and emphasize the importance of including more anomaly analyses to complete and refine our conclusions.

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Magnetic mineralogy of the Mercurian lithosphere

Cited by 11 publications

References 107 publications

A New Tool for Separating the Magnetic Mineralogy of Complex Mineral Assemblages from Low Temperature Magnetic Behavior

A New Tool for Separating the Magnetic Mineralogy of Complex Mineral Assemblages from Low Temperature Magnetic Behavior

Studying the Composition and Mineralogy of the Hermean Surface with the Mercury Radiometer and Thermal Infrared Spectrometer (MERTIS) for the BepiColombo Mission: An Update

Constraining the Early History of Mercury and Its Core Dynamo by Studying the Crustal Magnetic Field

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