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2. 17 Endogenous Lunar Volatiles

Author

McCubbin, Francis M., primary, Barnes, Jessica J., additional, Ni, Peng, additional, Hui, Hejiu, additional, Klima, Rachel L., additional, Burney, David, additional, Day, James M. D., additional, Magna, Tomáš, additional, Boyce, Jeremy W., additional, Tartèse, Romain, additional, Vander Kaaden, Kathleen E., additional, Steenstra, Edgar, additional, Elardo, Stephen M., additional, Zeigler, Ryan A., additional, Anand, Mahesh, additional, and Liu, Yang, additional

Published
2024
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3. The case for landed Mercury science

Author

Byrne, Paul K., Blewett, David T., Chabot, Nancy L., Hauck, II, Steven A., Mazarico, Erwan, Vander Kaaden, Kathleen E., Vervack, Ronald J., Oberst, Jürgen, Hussmann, Hauke, and Stark, Alexander

Published
2022
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7. Using Simulated Micrometeoroid Impacts to Understand the Progressive Space Weathering of the Surface of Mercury

Author

Thompson, Michelle S, McGlaun, M. L, Vander Kaaden, Kathleen E, Loeffler, M. J, and McCubbin, Francis M

Subjects
Lunar And Planetary Science And Exploration
Abstract

The surfaces of airless bodies such as Mercury are continually modified by space weathering, which is driven by micrometeoroid impacts and solar wind irradiation. Space weathering alters the chemical composition, microstructure, and spectral properties of surface regolith. In lunar and ordinarychondritic style space weathering, these processes affect the reflectance properties by darkening (lowering of reflectance), reddening (increasing reflectance with increasing wavelength), and attenuation of characteristic absorption features. These optical changes are driven by the production of nanophase Febearing particles (npFe). While our understanding of these alteration processes has largely been based on data from the Moon and near-Earth S-type asteroids, the space weathering environment at Mercury is much more extreme. The surface of Mercury experiences a more intense solar wind flux and higher velocity micrometeoroid impacts than its planetary counterparts at 1 AU. Additionally, the composition of Mercury’s surface varies significantly from that of the Moon. Most notably, a very low albedo unit has been identified on Mercury’s surface, known as the low reflectance material (LRM). This unit is enriched with up to 4 wt.% carbon, likely in the form of graphite, over the local mean. In addition, the surface concentration of Fe across Mercury’s surface is low (<2 wt.%) compared to the Moon. Our understanding of how these low-Fe and carbon phases are altered as a result of space weathering processes is limited. Since Fe plays a critical role in the development of space weathering features on other airless surfaces (e.g., npFe), its limited availability on Mercury may strongly affect the space weathering features in surface materials. In order to understand how space weathering affects the chemical, microstructural, and optical properties of the surface of Mercury, we can simulate these processes in the laboratory [7]. Here we used pulsed laser irradiation to simulate the short duration, high temperature events associated with micrometeoroid impacts. We used forsteritic olivine, likely present on the Mercurian surface, with varying FeO contents, each mixed with graphite, in our experiments. We then performed reflectance spectroscopy and electron microscopy to investigate the spectral, chemical, and microstructural changes in these samples.

Published
2020

11. Experimental Insights into the Geochemistry of Mercury

Author

Vander Kaaden, Kathleen E

Subjects
Lunar And Planetary Science And Exploration
Abstract

With the recent estimate of Mercury's surface composition from the X-Ray Spectrometer and Gamma-Ray Spectrometer that were onboard NASA's MErcury Surface, Space ENvironment, Geochemistry and Ranging (MESSENGER) spacecraft, we now have our first opportunity to directly investigate the compositions of lavas from the planet Mercury and indirectly investigate the chemical make-up of its interior. Results from MESSENGER showed exotic surface compositions with more than 3 wt% sulfur in some lavas and relatively low amounts of iron (less than 3 wt%) across the surface. These striking features are consistent with magmatism occurring under highly reducing conditions which has an impact on the thermal and chemical evolution of a planetary body. Here we'll explore the geochemical evolution of Mercury through a series of experimental studies and discuss the implications of low oxygen fugacity on elemental behavior and magmatic processes.

Published
2019

12. The Geochemistry of Aubrites: Investigating Reduced Parent Bodies

Author

Wilbur, Z. E, Udry, A, Zeigler, Ryan A, McCubbin, Francis M, Vander Kaaden, Kathleen E, Ziegler, K, DeFelice, C, and McCoy, T. J

Subjects
Lunar And Planetary Science And Exploration
Abstract

The aubrites (~30 known meteorites) are a unique group of differentiated meteorites that formed on asteroids with oxygen fugacities (ƒO2) from ~2 to ~6 log units below the iron-wüstite buffer [1–2]. At these highly reduced conditions, elements deviate from the geochemical behavior exhibited at terrestrial ƒO2, forming FeO-poor silicates, Si-bearing metals, and exotic sulfides [3]. Here we examine the 3D mineralogy and the geochemistry of fourteen aubrites, including mineral major element compositions, bulk-rock compositions, and oxygen isotopic compositions to understand their formation and evolution at extreme ƒO2 conditions. While previous studies have described the petrology and 2D modal abundances of aubrites, this work investigates the 3D modal mineralogies of silicate, metal, and sulfide phases in aubrite samples, which are then com-pared to the available 2D data. We utilize X-ray computed tomography (XCT) to non-destructively analyze the distribution and abundances of mineral phases in aubrites and locate composite clasts of sulfide grains for future analysis.

Published
2019

13. Discreditation of Bobdownsite and the Establishment of Criteria for the Identification of Minerals with Essential Monofluorophosphate (PO3F2-)

Author

McCubbin, Francis M, Phillips, Brian L, Adcock, Christopher T, Tait, Kimberly T, Steele, Andrew, Vaughn, John S, Fries, Marc D, Atudorei, Viorel, Vander Kaaden, Kathleen E, and Hausrath, Elisabeth M

Subjects
Geosciences (General)
Abstract

Bobdownsite, IMA number 2008-037, was approved as a new mineral by the Commission on New Minerals, Nomenclature and Classification (CNMNC) as the fluorine endmember of the mineral whitlockite. The type locality of bobdownsite is in Big Fish River, Yukon Canada, and bobdownsite was reported to be the first naturally occurring mineral with essential monofluorophosphate (PO3F2-). The type specimen of bobdownsite has been reinvestigated by electron probe microanalysis (EPMA), and our data indicate that fluorine abundances are below detection in the mineral. In addition, we conducted detailed analysis of bobdownsite from the type locality by gas chromatography isotope ratio mass spectrometry, Raman spectroscopy, EPMA, and NMR spectroscopy. These data were compared with previously published data on synthetic monofluorophosphate salts. Collectively, these data indicate that bobdownsite is indistinguishable from whitlockite with a composition along the whitlockite-merrillite solid solution. Bobdownsite is therefore discredited as a valid mineral species. An additional mineral, krásnoite, has been purported to have monofluorophosphate components in its structure, but reexamination of those data indicate that F- in krásnoite forms bonds with Al, similar to OH- bonded to Al in perhamite. Consequently, krásnoite also lacks monofluorophosphate groups, and there are currently no valid mineral species with monofluorophosphate in their structure. We recommend that any future reports of new minerals that contain essential monofluorophosphate anions be vetted by abundance measurements of fluorine, vibrational spectroscopy (both Raman and FTIR), and where paramagnetic components are permissibly low, NMR spectroscopy. Furthermore, we emphasize the importance of using synthetic compounds containing monofluorophosphate anions as a point of comparison in the identification of minerals with essential monofluorophosphate. Structural data that yield satisfactory P-F bond lengths determined by X-ray crystallography, coupled with direct chemical analyses of fluorine in a material do not constitute sufficient evidence alone to identify a new mineral with essential monofluorophosphate anions.

Published
2018
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14. The Role of Carbon in Exotic Crust Formation on Mercury

Author

Vander Kaaden, Kathleen E and McCubbin, Francis M

Subjects
Space Sciences (General), Lunar And Planetary Science And Exploration
Abstract

The terrestrial planets that comprise our inner Solar System, including the Moon, are all rocky bodies that have differentiated into a crust, mantle, and core. Furthermore, all of these bodies have undergone various igneous processes since their time of primary crust formation. These processes have resurfaced each of these bodies, at least in part, resulting in the production of a secondary crust, to which Mercury is no exception. From its first flyby encounter with Mercury on January 14, 2008, the MErcury Surface, Space ENvironment, GEochemistry and Ranging (MESSENGER) spacecraft collected data on the structure, chemical makeup, and density of the planet among other important characteristics. The X-Ray Spectrometer on board MESSENGER measured elevated abundances of sulfur and low abundances of iron, suggesting the planets oxygen fugacity (fO2) is several log10 units below the Iron-Wustite buffer. Similar to the role of other volatiles (e.g. sulfur) on highly reducing planetary bodies, carbon is expected to behave differently in an oxygen starved environment than it does in an oxygen enriched environment (e.g., Earth).

Published
2018

15. Endogenous Lunar Volatiles

Author

McCubbin, Francis M, Liu, Yang, Barnes, Jessica J, Anand, Mahesh, Boyce, Jeremy W, Burney, David, Day, James M. D, Elardo, Stephen M, Hui, Hejiu, Klima, Rachel L, Magna, Tomas, Ni, Peng, Steenstra, Edgar, Tartèse, Romain, and Vander Kaaden, Kathleen E

Subjects
Lunar And Planetary Science And Exploration
Abstract

Despite all of the new data generated on endogenous lunar volatiles since the publication of New Views of the Moon, many important questions remain unanswered or only partially resolved. This abstract looks to the future and discusses several of those important remaining questions on the topic of endogenous lunar volatiles.

Published
2018

17. Assessing the Behavior of Typically Lithophile Elements Under Highly Reducing Conditions Relevant to the Planet Mercury

Author

Rowland, Rick, II, Vander Kaaden, Kathleen E, McCubbin, Francis M, and Danielson, Lisa R

Subjects
Lunar And Planetary Science And Exploration, Geophysics
Abstract

With the data returned from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) mission, there are now numerous constraints on the physical and chemical properties of Mercury, including its surface composition. The high Sand low FeO contents observed from MESSENGER suggest a low oxygen fugacity of the present materials on the planet's surface. Most of our understanding of elemental partitioning behavior comes from observations made on terrestrial rocks, but Mercury's oxygen fugacity is far outside the conditions of those samples, estimated at approximately 3-7 log units below the Iron-Wtistite (lW) oxygen buffer, several orders of magnitude more reducing than other terrestrial bodies we have data from. With limited oxygen available, lithophile elements may instead exhibit chalcophile, halophile, or siderophile behaviors. Furthermore, very few natural samples of rocks that formed under reducing conditions (e.g., enstatite chondrites, achondrites, aubrites) are available in our collections for examination of this change in geochemical affinity. Our goal is to determine the elemental partitioning behavior of typically lithophile elements at lower oxygen fugacity as a function of temperature and pressure. Experiments were conducted at I GPa in a 13 mm QUICKpress piston cylinder and at 4 GPa in an 880-ton multianvil press, at temperatures up to 1850degC. The composition of starting materials for the experiments were designed so the final run products contained metal, silicate melt, and sulfide melt phases. Oxygen fugacity was controlled in the experiments by adding silicon metal to the samples, in order to utilize the Si-Si02 buffer, which is approximately 5 log units more reducing than the IW buffer at our temperatures of interest. The target silicate melt composition was diopside (CaMgSi206) because measured surface compositions indicate partial melting of a pyroxene-rich mantle. The results of our experiments will aid in our understanding of the fate of elements during the differentiation and thermal evolution of Mercury and other highly reducing planetary bodies.

Published
2017

18. Experimental Constraints on the Partitioning Behavior of F, Cl, and OH Between Apatite and Basaltic Melt

Author

McCubbin, Francis M, Barnes, Jessica J, Vander Kaaden, Kathleen E, Boyce, Jeremy W, Ustunisik, Gokce, and Whitson, Eric S

Subjects
Geophysics
Abstract

The mineral apatite is present in a wide range of planetary materials. The presence of volatiles (F, Cl, and OH) within its crystal structure (X-site) have motivated numerous studies to investigate the partitioning behavior of F, Cl, and OH between apatite and silicate melt with the end goal of using apatite to constrain the volatile contents of planetary magmas and mantle sources. A number of recent experimental studies have investigated the apatite-melt partitioning behavior of F, Cl, and OH in magmatic systems. Apatite-melt partitioning of volatiles are best described as exchange equilibria similar to Fe-Mg partitioning between olivine and silicate melt. However, the partitioning behavior is likely to change as a function of temperature, pressure, oxygen fugacity, apatite composition, and melt composition. In the present study, we have conducted experiments to assess the partitioning behavior of F, Cl, and OH between apatite and silicate melt over a pressure range of 0-6 gigapascals, a temperature range of 950-1500 degrees Centigrade, and a wide range of apatite ternary compositions. All of the experiments were conducted between iron-wustite oxidation potentials IW minus 1 and IW plus 2 in a basaltic melt composition. The experimental run products were analyzed by a combination of electron probe microanalysis and secondary ion mass spectrometry (NanoSIMS). Temperature, apatite crystal chemistry, and pressure all play important roles in the partitioning behavior of F, Cl, and OH between apatite and silicate melt. In portions of apatite ternary space that undergo ideal mixing of F, Cl, and OH, exchange coefficients remain constant at constant temperature and pressure. However, exchange coefficients vary at constant temperature (T) and pressure (P) in portions of apatite compositional space where F, Cl, and OH do not mix ideally in apatite. The variation in exchange coefficients exhibited by apatite that does not undergo ideal mixing far exceeds the variations induced by changes in temperature (T) or pressure (P) . In regions where apatite undergoes ideal mixing of F, Cl, and OH, temperature has a stronger effect than pressure on the partitioning behavior, but both are important. Furthermore, fluorine becomes less compatible in apatite with increasing pressure and temperature. We are still in the process of analyzing our experimental run products, but we plan to quantify the effects of P and T on apatite-melt partitioning of F, Cl, and OH.

Published
2017

20. Highly Reducing Partitioning Experiments Relevant to the Planet Mercury

Author

Rowland, Rick, II, Vander Kaaden, Kathleen E, McCubbin, Francis M, and Danielson, Lisa R

Subjects
Lunar And Planetary Science And Exploration
Abstract

With the data returned from the MErcury Surface Space ENvironment GEochemistry and Ranging (MESSENGER) mission, there are now numerous constraints on the physical and chemical properties of Mercury, including its surface composition. The high S and low FeO contents observed from MESSENGER on the planet's surface suggests a low oxygen fugacity of the present planetary materials. Estimates of the oxygen fugacity for Mercurian magmas are approximately 3-7 log units below the Iron-Wüstite (Fe-FeO) oxygen buffer, several orders of magnitude more reducing than other terrestrial bodies we have data from such as the Earth, Moon, or Mars. Most of our understanding of elemental partitioning behavior comes from observations made on terrestrial rocks, but Mercury's oxygen fugacity is far outside the conditions of those samples. With limited oxygen available, lithophile elements may instead exhibit chalcophile, halophile, or siderophile behaviors. Furthermore, very few natural samples of rocks that formed under reducing conditions are available in our collections (e.g., enstatite chondrites, achondrites, aubrites). With this limited amount of material, we must perform experiments to determine the elemental partitioning behavior of typically lithophile elements as a function of decreasing oxygen fugacity. Experiments are being conducted at 4 GPa in an 880-ton multi-anvil press, at temperatures up to 1850degC. The composition of starting materials for the experiments were selected for the final run products to contain metal, silicate melt, and sulfide melt phases. Oxygen fugacity is controlled in the experiments by adding silicon metal to the samples, using the Si-SiO2 oxygen buffer, which is approximately 5 log units more reducing than the Fe-FeO oxygen buffer at our temperatures of interest. The target silicate melt compositional is diopside (CaMgSi2O6) because measured surface compositions indicate partial melting of a pyroxene-rich mantle. Elements detected on Mercury's surface by MESSENGER (K, Na, Fe, Ti, Cl, Al, Cr, Mn, U, Th) and other geochemically relevant elements (P, F, H, N, C, Co, Ni, Mo, Ce, Nd, Sm, Eu, Gd, Dy, Yb) are added to the starting composition at trace abundances (approximately 500 ppm) so that they are close enough to infinite dilution to follow Henry's law of trace elements, and their partitioning behavior can be measured between the metal, silicate, and sulfide phases. The results of these experiments will allow us to assess the thermal and magmatic evolution of the planet Mercury from a geochemical standpoint.

Published
2017

21. The effects of highly reduced magmatism revealed through aubrites

Author

Wilbur, Zoë E., primary, Udry, Arya, additional, McCubbin, Francis M., additional, vander Kaaden, Kathleen E., additional, DeFelice, Christopher, additional, Ziegler, Karen, additional, Ross, Daniel Kent, additional, McCoy, Timothy J., additional, Gross, Juliane, additional, Barnes, Jessica J., additional, Dygert, Nick, additional, Zeigler, Ryan A., additional, Turrin, Brent D., additional, and McCoy, Christopher, additional

Published
2022
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22. A Synthesis of Experimental Data Describing the Partitioning of Moderately Volatile Elements in Major Rock Forming Minerals: Implications for the Moon

Author

Vander Kaaden, Kathleen E, Draper, David S, McCubbin, Francis M, Neal, Clive R, and Taylor, G. Jeffrey

Subjects
Lunar And Planetary Science And Exploration
Abstract

Highly volatile elements [condensation temperatures below about 700 K] and water are highly informative about lunar bulk composition (hence origin), differentiation and magmatic evolution, and the role of impacts in delivering volatiles to the Moon. Fractionation of volatile elements compared to moderately volatile and refractory elements are informative about high-temperature conditions that operated in the proto-lunar disk. Existing data show clearly that the Moon is depleted in volatile elements compared to the bulk silicate Earth. For example, K/Th is ~400-700 in the Moon compared to 2800-3000 in Earth. A complicating factor is that the abundances of the highly volatile elements in major lunar lithologies vary by approximately two orders of magnitude. Perhaps most interesting, H2O is not correlated with the concentration of volatile elements, indicating a decoupling of highly volatile elements from the even more volatile H2O. We contend that this decoupling could be a significant tracer of processes operating during lunar formation, differentiation, and bombardment, and the combination of analyzing both volatile elements and water is likely to provide significant insight into lunar geochemical history. This variation and lack of correlation raises the question: what were the relative contributions of crystallization in the magma ocean, subsequent mantle overturn, production of secondary magmas, and addition of volatiles by large impacts in producing this apparently large range in volatile abundances? This current study will produce new partitioning data relevant to the role and distribution of the volatile and non-volatile, yet geochemically significant elements (Co, Ni, Zn, Se, Rb, Sr, Mo, Ag, Cd, In, Sb, Ce, Yb, Tl, Pb, Bi) during the thermal and magmatic evolution of the Moon.

Published
2017

23. The Role of Carbon in Core Formation Under Highly Reducing Conditions With Implications for the Planet Mercury

Author

Vander Kaaden, Kathleen E, McCubbin, Francis M, Ross, D. Kent, and Draper, David S

Subjects
Lunar And Planetary Science And Exploration
Abstract

Results from the MErcury Surface, Space ENvironment, GEochemistry and Ranging (MESSENGER) spacecraft have shown elevated abundances of carbon on the surface of Mercury. Furthermore, the X-Ray Spectrometer on board MESSENGER measured elevated abundances of sulfur and low abundances of iron, suggesting the planet's oxygen fugacity (fO2) is several log10 units below the Iron-Wüstite (IW) buffer. Similar to the role of other volatiles (e.g. sulfur) on highly reducing planetary bodies, carbon is expected to behave differently than it would under higher fO2. As discussed by Nittler et al. and Hauck et al., under such highly reducing conditions, the majority of the iron partitions into the core. On Mercury, this resulted in a relatively large core and a thin mantle. Using a composition similar to the largest volcanic field on the planet (the northern volcanic plains), Vander Kaaden and McCubbin conducted sink-float experiments to determine the density of melts and minerals on Mercury. They showed that graphite would be the only buoyant mineral in a mercurian magma ocean. Therefore, Vander Kaaden and McCubbin proposed a possible primary flotation crust on the planet composed of graphite. Concurrently, Peplowski et al. used GRS data from MESSENGER to show an average northern hemisphere abundance of C on the planet of 1.4 +/- 0.9 wt%. However, as this result was only at the one-sigma detection limit, possible carbon abundances at the three-sigma detection limit for Mercury range from 0 to 4.1 wt% carbon. Additionally, Murchie et al. investigated the possible darkening agent on Mercury and concluded that coarse-grained graphite could darken high reflectance plains to the low reflectance material. To further test the possibility of elevated abundances of carbon in Mercury's crust, Peplowski et al. used the low-altitude MESSENGER data to show that carbon is the only material consistent with both the visible to near-infrared spectra and the neutron measurements of low reflectance material on Mercury, confirming that C is the primary darkening agent on Mercury. Confirmation of carbon on the planet prompts many questions regarding the role of carbon during the differentiation and evolution of Mercury. Given the elevated abundances of both S and C on Mercury's surface, it begs the question, what is the core composition of the planet? This study seeks to understand the impact of C as a light element on potential core compositions on Mercury.

Published
2017

24. Making Mercury's Core with Light Elements

Author

Vander Kaaden, Kathleen E, McCubbin, Francis M, and Ross, D. Kent

Subjects
Astrophysics
Abstract

Recent results obtained from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging spacecraft showed the surface of Mercury has low FeO abundances (less than 2 wt%) and high S abundances (approximately 4 wt%), suggesting the oxygen fugacity of Mercury's surface materials is somewhere between 3 to 7 log10 units below the IW buffer. The highly reducing nature of Mercury has resulted in a relatively thin mantle and a large core that has the potential to exhibit an exotic composition in comparison to the other terrestrial planets. This exotic composition may extend to include light elements (e.g., Si, C, S). Furthermore, has argued for a possible primary floatation crust on Mercury composed of graphite, which may require a core that is C-saturated. In order to investigate mercurian core compositions, we conducted piston cylinder experiments at 1 GPa, from 1300 C to 1700 C, using a range of starting compositions consisting of various Si-Fe metal mixtures (Si5Fe95, Si10Fe90, Si22Fe78, and Si35Fe65). All metals were loaded into graphite capsules used to ensure C-saturation during the duration of each experimental run. Our experiments show that Fe-Si metallic alloys exclude carbon relative to more Fe-rich metal. This exclusion of carbon commences within the range of 5 to 10 wt% Si. These results indicate that if Mercury has a Si-rich core (having more than approximately 5 wt% silicon), it would have saturated in carbon at low C abundances allowing for the possible formation of a graphite floatation crust as suggested by. These results have important implications for the thermal and magmatic evolution of Mercury.

Published
2016

25. Science Goals and Mission Concept for a Landed Investigation of Mercury

Author

Ernst, Carolyn M., primary, Chabot, Nancy L., additional, Klima, Rachel L., additional, Kubota, Sanae, additional, Rogers, Gabe, additional, Byrne, Paul K., additional, Hauck, Steven A., additional, Vander Kaaden, Kathleen E., additional, Vervack, Ronald J., additional, Besse, Sébastien, additional, Blewett, David T., additional, Denevi, Brett W., additional, Goossens, Sander, additional, Indyk, Stephen J., additional, Izenberg, Noam R., additional, Johnson, Catherine L., additional, Jozwiak, Lauren M., additional, Korth, Haje, additional, McNutt, Ralph L., additional, Murchie, Scott L., additional, Peplowski, Patrick N., additional, Raines, Jim M., additional, Rampe, Elizabeth B., additional, Thompson, Michelle S., additional, and Weider, Shoshana Z., additional

Published
2022
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26. Carbon Solubility in Silicon-Iron-Bearing Metals during Core Formation on Mercury

Author

Vander Kaaden, Kathleen E, McCubbin, Francis M, Ross, D. Kent, Rapp, Jennifer F, Danielson, Lisa R, Keller, Lindsay P, and Righter, Kevin

Subjects
Lunar And Planetary Science And Exploration
Abstract

Recent results obtained from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft showed the surface of Mercury has high S abundances (approximately 4 wt%) and low Iron(II) Oxide abundances (less than 2 wt%). Based on these extreme values, the oxygen fugacity of Mercury's surface materials was estimated to be approximately 3 to 7 log(sub 10) units below the IW buffer (Delta IW-3 to Delta IW-7). This highly reducing nature of the planet has resulted in a large core and relatively thin mantle, extending to only approximately 420 km depth (corresponding to a core-mantle boundary pressure of approximately 4-7 GPa) within the planet. Furthermore, MESSENGER results have suggested the presence of carbon on the surface of the planet. Previous experimental results from have also suggested the possibility of a primary floatation crust on Mercury composed of graphite, produced after a global magma ocean event. With these exotic conditions of this compositional end-member planet, it begs the question, what is the core composition of Mercury? Although no definitive conclusion has been reached, previous studies have made advances towards answering this question. Riner et al. and Chen et al. looked at iron sulfide systems and implemented various crystallization and layered core scenarios to try and determine the composition and structure of Mercury's core. Malavergne et al. examined core crystallization scenarios in the presence of sulfur and silicon. Hauck et al. used the most recent geophysical constraints from the MESSENGER spacecraft to model the internal structure of Mercury, including the core, in a iron-sulfur-silicon system. More recently, Chabot et al. conducted a series of metal-silicate partitioning experiments in a iron-sulfur-silicon system. These results showed the core of Mercury has the potential to contain more than 15 wt% silicon. However, with the newest results from MESSENGER's low altitude campaign, carbon is another potential light element that could be incorporated into Mercury's core. The goal of this study is to determine the carbon concentration at graphite saturation in various silicon-iron bearing metals relevant to possible mercurian core compositions. Future experiments will include the addition of sulfur into these metals.

Published
2016

27. Mineralogy of the Mercurian Surface

Author

Vander Kaaden, Kathleen E, McCubbin, Francis M, Nittler, Larry R, Peplowski, Patrick N, Weider, Shoshana Z, Evans, Larry R, Frank, Elizabeth A, and McCoy, Timothy

Subjects
Lunar And Planetary Science And Exploration
Abstract

The MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft orbited Mercury for four years until April 2015, revealing its structure, chemical makeup, and compositional diversity. Data from the mission have confirmed that Mercury is a compositional end-member among the terrestrial planets. The X-Ray Spectrometer (XRS) and Gamma-Ray Spectrometer (GRS) on board MESSENGER provided the first detailed geochemical analyses of Mercury's surface. These instruments have been used in conjunction with the Neutron Spectrometer and the Mercury Dual Imaging System to classify numerous geological and geochemical features on the surface of Mercury that were previously unknown. Furthermore, the data have revealed several surprising characteristics about Mercury's surface, including elevated S abundances (up to 4 wt%) and low Fe abundances (less than 2.5 wt%). The S and Fe abundances were used to quantify Mercury's highly reduced state, i.e., between 2.6 and 7.3 log10 units below the Iron-Wustite (IW) buffer. This fO2 is lower than any of the other terrestrial planets in the inner Solar System and has important consequences for the thermal and magmatic evolution of Mercury, its surface mineralogy and geochemistry, and the petrogenesis of the planet's magmas. Although MESSENGER has revealed substantial geochemical diversity across the surface of Mercury, until now, there have been only limited efforts to understand the mineralogical and petrological diversity of the planet. Here we present a systematic and comprehensive study of the potential mineralogical and petrological diversity of Mercury.

Published
2016

28. The case for landed Mercury science

Author

Byrne, Paul K., primary, Blewett, David T., additional, Chabot, Nancy L., additional, Hauck, Steven A., additional, Mazarico, Erwan, additional, Vander Kaaden, Kathleen E., additional, Vervack, Ronald J., additional, Oberst, Jürgen, additional, Hussmann, Hauke, additional, and Stark, Alexander, additional

Published
2021
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32. Reclassification of four aubrites as enstatite chondrite impact melts: Potential geochemical analogs for Mercury

Author

Udry, Arya, primary, Wilbur, Zoë E., additional, Rahib, Rachel R., additional, McCubbin, Francis M., additional, Vander Kaaden, Kathleen E., additional, McCoy, Timothy J., additional, Ziegler, Karen, additional, Gross, Juliane, additional, DeFelice, Christopher, additional, Combs, Logan, additional, and Turrin, Brent D., additional

Published
2019
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33. Discreditation of bobdownsite and the establishment of criteria for the identification of minerals with essential monofluorophosphate (PO3F2–)

Author

McCubbin, Francis M., primary, Phillips, Brian L., additional, Adcock, Christopher T., additional, Tait, Kimberly T., additional, Steele, Andrew, additional, Vaughn, John S., additional, Fries, Marc D., additional, Atudorei, Viorel, additional, Vander Kaaden, Kathleen E., additional, and Hausrath, Elisabeth M., additional

Published
2018
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36. Discreditation of bobdownsite and the establishment of criteria for the identification of minerals with essential monofluorophosphate (PO3F2–).

Author

McCubbin, Francis M., Phillips, Brian L., Adcock, Christopher T., Tait, Kimberly T., Steele, Andrew, Vaughn, John S., Fries, Marc D., Atudorei, Viorel, Vander Kaaden, Kathleen E., and Hausrath, Elisabeth M.

Subjects
GAS chromatography, RAMAN spectroscopy
Abstract

Bobdownsite, IMA number 2008-037, was approved as a new mineral by the Commission on New Minerals, Nomenclature and Classification (CNMNC) as the fluorine end-member of the mineral whitlockite. The type locality of bobdownsite is in Big Fish River, Yukon, Canada, and bobdownsite was reported to be the first mineral with essential monofluorophosphate (PO3F2–). The type specimen of bobdownsite has been reinvestigated by electron probe microanalysis (EPMA), and our data indicate that fluorine abundances are below detection in the mineral. In addition, we conducted detailed analysis of bobdownsite from the type locality by gas chromatography isotope ratio mass spectrometry, Raman spectroscopy, EPMA, and NMR spectroscopy. These data were compared with previously published data on synthetic monofluorophosphate salts. Collectively, these data indicate that bobdownsite is indistinguishable from whitlockite with a composition along the whitlockite-merrillite solid solution. Bobdownsite is therefore discredited as a valid mineral species. An additional mineral, krásnoite, has been purported to have monofluorophosphate components in its structure, but reexamination of those data indicate that F in krásnoite forms bonds with Al, similar to OH bonded to Al in perhamite. Consequently, krásnoite also lacks monofluorophosphate groups, and there are currently no valid mineral species with monofluorophosphate in their structure. We recommend that any future reports of new minerals that contain essential monofluorophosphate anions be vetted by abundance measurements of fluorine, vibrational spectroscopy (both Raman and FTIR), and where paramagnetic components are permissibly low, NMR spectroscopy. Furthermore, we emphasize the importance of using synthetic compounds containing monofluorophosphate anions as a point of comparison in the identification of minerals with essential monofluorophosphate. Structural data that yield satisfactory P-F bond lengths determined by X-ray crystallography, coupled with direct chemical analyses of fluorine in a material do not constitute sufficient evidence alone to identify a new mineral with essential monofluorophosphate. [ABSTRACT FROM AUTHOR]

Published
2018
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37. Magmatic volatiles (H, C, N, F, S, Cl) in the lunar mantle, crust, and regolith: Abundances, distributions, processes, and reservoirs

Author

McCubbin, Francis M., primary, Vander Kaaden, Kathleen E., additional, Tartèse, Romain, additional, Klima, Rachel L., additional, Liu, Yang, additional, Mortimer, James, additional, Barnes, Jessica J., additional, Shearer, Charles K., additional, Treiman, Allan H., additional, Lawrence, David J., additional, Elardo, Stephen M., additional, Hurley, Dana M., additional, Boyce, Jeremy W., additional, and Anand, Mahesh, additional

Published
2015
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38. Experimental investigation of F, Cl, and OH partitioning between apatite and Fe-rich basaltic melt at 1.0–1.2 GPa and 950–1000 °C

Author

McCubbin, Francis M., primary, Vander Kaaden, Kathleen E., additional, Tartèse, Romain, additional, Boyce, Jeremy W., additional, Mikhail, Sami, additional, Whitson, Eric S., additional, Bell, Aaron S., additional, Anand, Mahesh, additional, Franchi, Ian A., additional, Wang, Jianhua, additional, and Hauri, Erik H., additional

Published
2015
Full Text
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44. Magmatic volatiles (H, C, N, F, S, Cl) in the lunar mantle, crust, and regolith: abundances, distributions, processes, and reservoirs

Author

McCubbin, Francis M., Vander Kaaden, Kathleen E., Tartèse, Romain, Klima, Rachel L., Liu, Yang, Mortimer, James, Barnes, Jessica J., Shearer, Charles K., Treiman, Allan H., Lawrence, David J., Elardo, Stephen M., Hurley, Dana M., Boyce, Jeremy W., Anand, Mahesh, McCubbin, Francis M., Vander Kaaden, Kathleen E., Tartèse, Romain, Klima, Rachel L., Liu, Yang, Mortimer, James, Barnes, Jessica J., Shearer, Charles K., Treiman, Allan H., Lawrence, David J., Elardo, Stephen M., Hurley, Dana M., Boyce, Jeremy W., and Anand, Mahesh

Abstract

There have been many studies on magmatic volatiles (H, C, N, F, S, Cl) in and on the Moon within the last several years that have cast into question the post-Apollo view of lunar formation, the distribution and sources of volatiles in the Earth-Moon system, and the thermal and magmatic evolution of the Moon. However, these recent observations are not the first data on lunar volatiles. When Apollo samples were first returned, substantial efforts were made to undersand volatile elements and a wealth of data regarding volatile elements exists in this older literature. In this review paper we approach volatiles in and on the Moon using new and old data derived from lunar samples and remote sensing. From combining these data sets, we identified many points of convergence, although numerous questions remain unanswered.

45. Magmatic volatiles (H, C, N, F, S, Cl) in the lunar mantle, crust, and regolith: abundances, distributions, processes, and reservoirs

Author

McCubbin, Francis M., Vander Kaaden, Kathleen E., Tartèse, Romain, Klima, Rachel L., Liu, Yang, Mortimer, James, Barnes, Jessica J., Shearer, Charles K., Treiman, Allan H., Lawrence, David J., Elardo, Stephen M., Hurley, Dana M., Boyce, Jeremy W., Anand, Mahesh, McCubbin, Francis M., Vander Kaaden, Kathleen E., Tartèse, Romain, Klima, Rachel L., Liu, Yang, Mortimer, James, Barnes, Jessica J., Shearer, Charles K., Treiman, Allan H., Lawrence, David J., Elardo, Stephen M., Hurley, Dana M., Boyce, Jeremy W., and Anand, Mahesh

Abstract

There have been many studies on magmatic volatiles (H, C, N, F, S, Cl) in and on the Moon within the last several years that have cast into question the post-Apollo view of lunar formation, the distribution and sources of volatiles in the Earth-Moon system, and the thermal and magmatic evolution of the Moon. However, these recent observations are not the first data on lunar volatiles. When Apollo samples were first returned, substantial efforts were made to undersand volatile elements and a wealth of data regarding volatile elements exists in this older literature. In this review paper we approach volatiles in and on the Moon using new and old data derived from lunar samples and remote sensing. From combining these data sets, we identified many points of convergence, although numerous questions remain unanswered.

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