The mass flux of volatiles from volcanic eruptions on Mercury

Mercury has been extensively resurfaced by large, effusive lava plains [1&#8211;2]. Similar lava plains on the Moon, the maria, are known to contain volatiles [3&#8211;4] and are estimated to have outgassed ~1016 kg of CO and S and ~1014 kg of H2O, with the bulk of volatiles being released during peak mare emplacement ~3.5 Ga ago [5]. If volcanic activity released substantial volatiles on the Moon [6&#8211;7], then it is possible that substantial volatiles were also volcanically released on Mercury, albeit with different chemical species [6&#8211;9]. Here we seek to understand the potential contribution of outgassing to volatile deposits, specifically for Mercury&#8217;s volatile species (S, CH4, Cl, and N-H).We analyze the production function of volcanic plains deposits on Mercury and find that the volume of outgassed basalts on Mercury is 2 to 3 orders of magnitude larger than that predicted for the Moon [8]. We use a variety of experimental petrology studies [10&#8211;12] to predict the dominant species and their abundances associated with these eruptions on Mercury, providing estimates for both low-gas and high-gas scenarios for different oxygen fugacities (IW-3 and IW-7). The most prevalent volatile species predicted for Mercury (S, CH4, and Cl) are 1 to 4 orders of magnitude more abundant than what is predicted for the most abundant volatiles outgassed on the Moon (CO, S, and H2O) [5].On the Moon, it has been predicted that volatiles outgassed from the formation of the maria may have been present in sufficient volumes to produce a transient atmosphere capable of aiding in the transport of H2O to cold-trapping regions [5]. At mantle pressures and Mercury&#8217;s extremely reducing conditions, H2O is not predicted to be present in the magma [e.g., 6&#8211;12]. Therefore, Mercury&#8217;s outgassed volatiles are of a different composition from the H2O ice observed at Mercury&#8217;s poles today [e.g., 13], and the polar H2O-ice deposits are better explained by some external delivery mechanism (likely cometary impacts). But the fate of large volumes of volatiles other than H2O is an important unanswered question for Mercury.The large volumes of outgassed volatiles calculated here suggest that volcanism on Mercury may have resulted in the transient production of anomalously high atmospheric pressures of short lifetime due to solar proximity. If Mercury&#8217;s atmospheric loss rate was insufficient to lose all of the erupted gases, then it is possible that ancient, outgassed volatiles remain trapped in the planet&#8217;s subsurface today. The fate of Mercury&#8217;s outgassed volatiles is an important open question that we discuss in this work.References: [1] Head et al. (2011). [2] Denevi et al. (2013). [3] Boyce et al. (2010). [4] McCubbin et al. (2010). [5] Needham and Kring (2017). [6] Nittler et al. (2011). [7] Zolotov et al. (2013). [8] Peplowski et al. (2016). [9] Greenwood et al. (2018). [10] Anzures et al. (2017). [11] Armstrong et al. (2015). [12] Libourel et al. (2003). [13] Lawrence et al. (2013).

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Reconstruction of recent climate change in Alaska from the Aurora Peak ice core, central Alaska

Climate of the Past ◽

10.5194/cp-11-217-2015 ◽

2015 ◽

Vol 11 (2) ◽

pp. 217-226 ◽

Cited By ~ 8

Author(s):

A. Tsushima ◽

S. Matoba ◽

T. Shiraiwa ◽

S. Okamoto ◽

H. Sasaki ◽

...

Keyword(s):

Climate Change ◽

Accumulation Rate ◽

Ice Core ◽

Chemical Species ◽

Volcanic Eruptions ◽

Gulf Of Alaska ◽

Temporal Variations ◽

Storm Activity ◽

Alaska Range ◽

Recent Climate

Abstract. A 180.17 m ice core was drilled at Aurora Peak in the central part of the Alaska Range, Alaska, in 2008 to allow reconstruction of centennial-scale climate change in the northern North Pacific. The 10 m depth temperature in the borehole was −2.2 °C, which corresponded to the annual mean air temperature at the drilling site. In this ice core, there were many melt–refreeze layers due to high temperature and/or strong insolation during summer seasons. We analyzed stable hydrogen isotopes (δD) and chemical species in the ice core. The ice core age was determined by annual counts of δD and seasonal cycles of Na+, and we used reference horizons of tritium peaks in 1963 and 1964, major volcanic eruptions of Mount Spurr in 1992 and Mount Katmai in 1912, and a large forest fire in 2004 as age controls. Here, we show that the chronology of the Aurora Peak ice core from 95.61 m to the top corresponds to the period from 1900 to the summer season of 2008, with a dating error of ± 3 years. We estimated that the mean accumulation rate from 1997 to 2007 (except for 2004) was 2.04 m w.eq. yr-1. Our results suggest that temporal variations in δD and annual accumulation rates are strongly related to shifts in the Pacific Decadal Oscillation index (PDOI). The remarkable increase in annual precipitation since the 1970s has likely been the result of enhanced storm activity associated with shifts in the PDOI during winter in the Gulf of Alaska.

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Characteristics and Sources of Black Carbon Aerosol in a Mega-City in the Western Yangtze River Delta, China

Atmosphere ◽

10.3390/atmos11040315 ◽

2020 ◽

Vol 11 (4) ◽

pp. 315

Author(s):

Jun Li ◽

Lei Jiang ◽

Cheng Chen ◽

Dantong Liu ◽

Songshan Du ◽

...

Keyword(s):

Black Carbon ◽

Coating Thickness ◽

Yangtze River ◽

Anthropogenic Activities ◽

Chemical Species ◽

Yangtze River Delta ◽

River Delta ◽

Traffic Emissions ◽

Potential Contribution ◽

Coated Particle

A single particle soot photometer (SP2) was deployed in urban Nanjing, located in the Yangtze River Delta (China), to investigate the mixing state and sources of ambient refractory black carbon (rBC) from 26 January to 25 February 2014, along with an in-situ measurement of submicron aerosol chemical species by an aerodyne aerosol chemical speciation monitor (ACSM). The results showed that anthropogenic activities associated with firework emissions can be a significant source for rBC-containing particles during the period of the Chinese New Year, resulting from the evident peaks of rBC at midnight. During the residual periods, namely regular day (RD), the diurnal cycles of rBC presented two typical peaks that can be attributed to a synergistic influence of local traffic emissions and boundary layer changes throughout a day. Three coating factors, including organics, sulfate, and nitrate (-rich), were resolved using a positive matrix factorization (PMF) approach to explain the potential contribution of non-rBC coatings (i.e., organics, sulfate, and nitrate) to the coating thickness of rBC-containing particles. As the results show, organic aerosols (OAs) might be a major contributor to the coating thickness of rBC-coating particles during the whole period. The relative coating thickness (a ratio between coated particle size to BC core) exhibited a positive relationship with sulfate, indicative of the favorable coating factor during the episode caused by firework emissions. Source apportionment of rBC was performed via a multiple linear regression between the total rBC mass and each ACSM-PMF factor (rBC-ACSM-PMF). On average, biomass burning emissions accounted for 43%, being the largest contributor during the RD period, whereas local traffic emissions played a major role during the new year time.

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Quantification of the total ion transport in the near-Earth plasma sheet

Annales Geophysicae ◽

10.5194/angeo-35-869-2017 ◽

2017 ◽

Vol 35 (4) ◽

pp. 869-877 ◽

Cited By ~ 6

Author(s):

Rikard Slapak ◽

Maria Hamrin ◽

Timo Pitkänen ◽

Masatoshi Yamauchi ◽

Hans Nilsson ◽

...

Keyword(s):

Plasma Sheet ◽

Low Energy ◽

Auroral Region ◽

Ion Dynamics ◽

Lower Velocity ◽

Order Of Magnitude ◽

Using Data ◽

Open Question ◽

Atmospheric Loss ◽

Net Fluxes

Abstract. Recent studies strongly suggest that a majority of the observed O+ cusp outflows will eventually escape into the solar wind, rather than be transported to the plasma sheet. Therefore, an investigation of plasma sheet flows will add to these studies and give a more complete picture of magnetospheric ion dynamics. Specifically, it will provide a greater understanding of atmospheric loss. We have used Cluster spacecraft 4 to quantify the H+ and O+ total transports in the near-Earth plasma sheet, using data covering 2001–2005. The results show that both H+ and O+ have earthward net fluxes of the orders of 1026 and 1024 s−1, respectively. The O+ plasma sheet return flux is 1 order of magnitude smaller than the O+ outflows observed in the cusps, strengthening the view that most ionospheric O+ outflows do escape. The H+ return flux is approximately the same as the ionospheric outflow, suggesting a stable budget of H+ in the magnetosphere. However, low-energy H+, not detectable by the ion spectrometer, is not considered in our study, leaving the complete magnetospheric H+ circulation an open question. Studying tailward flows separately reveals a total tailward O+ flux of about 0. 5 × 1025 s−1, which can be considered as a lower limit of the nightside auroral region O+ outflow. Lower velocity flows ( < 100 km s−1) contribute most to the total transports, whereas the high-velocity flows contribute very little, suggesting that bursty bulk flows are not dominant in plasma sheet mass transport.

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Impact of volcanic halogens on the ozone layer and climate, a look to the past to highlight the present

10.5194/egusphere-egu2020-19275 ◽

2020 ◽

Author(s):

Hélène Balcone-Boissard ◽

Thiébaut D'Augustin ◽

Georges Boudon ◽

Slimane Bekki ◽

Magali Bonifacie ◽

...

Keyword(s):

Volcanic Eruptions ◽

Field Work ◽

Field Studies ◽

Global Scale ◽

Ozone Layer ◽

Volatile Species ◽

Magma Supply ◽

Global Impacts ◽

Almost All ◽

The Impact

Explosive eruptions of the Plinian type inject large amounts of particles (pumice, ash, aerosols) and volatile species into the atmosphere. They result from the rapid discharge of a magma chamber and involve large volumes of magma (from a km3 to hundreds of km3). Such eruptions correspond to a rapid ascent of magma in the conduit driven by the exsolution of volatile species. If the magma supply is continuous, this jet produces a convective eruptive column that can reach tens of km in height and transports gas and particles (pumice, ash, aerosols) directly into the stratosphere. Depending on the latitude of the volcano, the volume of implied magma, the height of the eruptive plume and the composition of the released gaseous and particulate mixture, these events can strongly affect the environment at the local or even at a global scale. Almost all studies on global impacts of volcanic eruptions have largely focused on the sulfur component. Volcanoes are also responsible for the emission of halogens which have a crucial impact on the ozone layer and therefore the climate.The objective of our project is to revisit the issue of the impact of volcanism on the atmosphere and climate by considering not only the sulfur component but also the halogen component. We will provide field work-based constraints on the strength of halogen (Cl and Br) emissions and on degassing processes for key eruptions, we will characterise the dynamics of volcanic plumes, notably the vertical distribution of emissions and we will explore and quantify the respective impacts of sulfur and halogen emissions on the ozone layer and climate.&#160;Here we will shed light on the methodology that will combine field campaign, laboratory analysis of collected samples and a hierarchy of modelling tools to study. We use an approach combining field studies, petrological characterization, geochemical measurements including isotopic data, estimation of the volume of involved magma and the height of injection of gases and particles by modelling the eruptive plume dynamic and numerical simulation of the impacts at the plume scale and at the global scale. &#160;The first halogen budget will also be presented.

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Depleted Uranium Oxides and Silicates as Spent Nuclear Fuel Waste Package Fill Materials

MRS Proceedings ◽

10.1557/proc-465-615 ◽

1996 ◽

Vol 465 ◽

Cited By ~ 2

Author(s):

C. W. Forsberg

Keyword(s):

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Chemical Species ◽

Fission Products ◽

Depleted Uranium ◽

Improve Performance ◽

Waste Package ◽

Reducing Conditions ◽

Nuclear Fuel Waste

ABSTRACTA new repository waste package (WP) concept for spent nuclear fuel (SNF) is being investigated. The WP uses depleted uranium (DU) to improve performance and reduce the uncertainties of geological disposal of SNF. The WP would be loaded with SNF. Void spaces would then be filled with DU (∼0.2 wt % 235U) dioxide (UO2) or DU silicate-glass beads.Fission products and actinides can not escape the SNF UO2 crystals until the UO2 dissolves or is transformed into other chemical species. After WP failure, the DU fill material slows dissolution by three mechanisms: (1) saturation of WP groundwater with DU and suppression of SNF dissolution, (2) maintenance of chemically reducing conditions in the WP that minimize SNF solubility by sacrificial oxidation of DU from the +4 valence state, and (3) evolution of DU to lower-density hydrated uranium silicates. The fill expansion minimizes water flow in the degraded WP. The DU also isotopically exchanges with SNF uranium as the SNF degrades to reduce long-term nuclear-criticality concerns.

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Newton novel magnetic instrument. Potential application to unveil key questions as the origin of the Moon

10.5194/egusphere-egu2020-20527 ◽

2020 ◽

Author(s):

José Luis Mesa Uña ◽

Marina Díaz Michelena ◽

Francisco Javier de Frutos Hernánsanz ◽

Claudio Aroca Hernández-Ros ◽

Marina Pérez Jiménez ◽

...

Keyword(s):

Magnetic Field ◽

Magnetic Susceptibility ◽

Temporal Variations ◽

Magnetic Characteristics ◽

Potential Contribution ◽

The European Union ◽

The Moon ◽

Lunar Crust ◽

Sensors And Actuators ◽

Earth Planet

The main objective of this contribution is to present the evolution of NEWTON novel magnetic susceptometer for planetary exploration, a state of the art sensor for the measurement of the complex magnetic susceptibility developed in the frame of an EU H2020 funded project [1].The magnetic susceptibility is a complex parameter dependent on the external magnetic field amplitude, direction and frequency. NEWTON susceptometer has been developed to determine the magnetic susceptibility of rocks and soils, with the capability to determine not only the real part but also the imaginary part of the susceptibility.The calibration and validation process for the susceptometer prototype casted very good results in comparison with other commercial and high resolution laboratory devices, reaching a resolution in the order of &#967; = 10&#8722;4 (I.S. Vol. Susceptibility), representative of Earth, Moon and Mars rocks. The critical parts of the prototype have been subjected to different tests, i.e. vibration and TVT, to verify the capability to withstand the hard environmental conditions of interplanetary missions.In this work we discuss the potential contribution of NEWTON instrument on the technical and scientific objectives achievement in future investigations on the Moon, either as payload during in-situ exploration with rovers or in sample return missions, providing a useful tool for fast in place sample analysis.There are still open questions regarding Moon&#8217;s magnetic field and geological characteristics of the satellite. Most hypotheses to explain the magnetic characteristics and anomalies on the lunar surface invoke a thermally driven core dynamo during its Pre-Nectarian and Nectarian history [2]. However, this theory is problematical given the small size of the core and the required strong magnetic field strength of an ancient dynamo. Further investigations on the lunar samples from missions [3] indicate ancient magnetic fields with intensities of <1 to 120 &#956;T for the period between 4.2 to 4.0 Ga. This huge range of intensities may indicate that the Moon&#8217;s magnetic field experienced extreme high temporal variations [2]. Even if considering large uncertainties, dynamo models should consider paleointensities of at least ~35 &#956;T for this high-field period.The use of scientific instruments like NEWTON susceptometer in rover exploration missions could shed some light on the ancient dynamo magnetic field, the magnetic and mineral composition of the lunar crust and other unanswered questions from the Moon.Acknowledgements:This project has received funding from the European Union&#8217;s Horizon 2020 research and innovation program under grant agreement No 730041 and the Spanish Programme of Research, Development and Innovation oriented to the challenges of the society under grant ESP2017-88930-R.&#160;References:[1]&#160;M.Diaz Michelena, J.L Mesa U&#241;a, M. Perez Jimenez, M. Maicas Ramos, P. Cobos Arribas, C. Aroca Hernandez-Ros, Sensors and Actuators, A: Physical, volume 263, pages 471-479 (2017)[2] Tikoo, S.M., Weiss, B.P., Cassata, W.S., Shuser, D.L., Gattacceca, J., Lima, E.A., Suavet, C., Nimmo, F. & Fuller, M.D. Earth Planet. Sci. Lett., 404: 89-97 (2014)[3] Tsunakawa, H., Takahashi, F., Shimizu, H., Shibuya, H., & Matsushima, M. Icarus 228: 35-53 (2014).[3] Fuller, M. (1974). Reviews of Geophysics, 12 &#8211; 1, 101-103 (1974)

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The contribution of the Geological Survey of Italy to the GeoERA Programme challenges towards a geological service for Europe

10.5194/egusphere-egu2020-21381 ◽

2020 ◽

Author(s):

Luca Guerrieri ◽

Carlo Cipolloni ◽

Chiara D'Ambrogi ◽

Barbara Dessi ◽

Pio Di Manna ◽

...

Keyword(s):

Natural Hazards ◽

Raw Materials ◽

Sustainable Use ◽

Volcanic Eruptions ◽

Carbonate Reservoir ◽

Geological Survey ◽

Potential Contribution ◽

Ornamental Stones ◽

Available Information

The better knowledge of the subsurface is one of the challenges faced by the Geological Survey Organizations all around the world. The assessment, and sustainable use, also concurrent, of subsurface resources, requires a holistic approach that takes into account also natural hazards and environmental impacts. Such approach is particularly significant in Italy where a large part of the territory is affected by several hazards (earthquakes, landslides, floods, volcanic eruptions, ground subsidence), and the exploitation of subsurface resources has been recently a theme for a scientific and political debate to address, investigate, and manage the potential contribution &#160;of human activities to increase natural hazards.Exploration and knowledge, sustainable use and management, impacts, and publicly available information are key topics addressed in the GeoERA Programme by the Geological Survey of Italy (SGI) a department of ISPRA, , through the participation to eight GeoERA projects.In the Geo-Energy Theme, the SGI contribution focuses on subsurface knowledge and database production: geological 3D model of the Po Basin subsurface as base input data for geothermal assessment of Mesozoic multilayer carbonate reservoir (HotLime); the implementation of the European Fault Database &#8211; EFD with information about faults characteristics, including 3D geometry and activity (HIKE).As regards the Raw Materials Theme, inthe last decade, various projects aimed at implementing data and metadata on available raw materials have been fostered by the EU Commission. The projects involving SGI range from cataloguing mineral resources (MINTELL4EU) into a Database INSPIRE compliant, to the inventory of ornamental stones containing information about the physical and mechanical characteristics of the rocks (EUROLITHOS), as well as to deepen the knowledge aimed at a possible recycling/reuse of minerals from extractive wastes (FRAME) in a circular economy perspective.In the Groundwater Theme, the main efforts of the SGI are involved on the implementation of an Italian inventory of available information on thermal-mineral water, an investigation on their geological background and the preparation of maps and web-map service (HOVER); the calculation of groundwater recharge at selected observation boreholes applying a statistical lumped model and as well using satellite data to produce spatially distributed recharge maps (TACTIC).Finally, SGI contributes to the implementation and development of the GeoERA Information Platform that is established to support the other GeoERA projects in managing and disseminating geospatial data, reports and unstructured data, and the results of their research.In a long term perspective, through the participation to eight GeoERA projects, the SGI has contributed to the development of a geological service for Europe built on the joint cooperation among national and regional geological surveys, that&#160; will be the long term objective of the whole GeoERA Programme.This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 731166.

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Electrostatic charging of permanently shadowed craters on the Moon

Monthly Notices of the Royal Astronomical Society Letters ◽

10.1093/mnrasl/slaa082 ◽

2020 ◽

Vol 496 (1) ◽

pp. L80-L84

Author(s):

S K Mishra ◽

Anil Bhardwaj

Keyword(s):

Steady State ◽

Quantum Field ◽

Fine Dust ◽

The Moon ◽

Surface Plasma ◽

Rich Region ◽

Plasma System ◽

Steady State Condition ◽

Electrostatic Charging ◽

Open Question

ABSTRACT An open question of the electrostatic charge development on the lunar surface in the electron-rich region within the permanently shadowed craters (PSCs) is addressed. We propose that the fine dust grains on the crater surface may act as efficient field emission centres generating electrons via quantum field tunnelling. This return current may be sufficient to establish a steady-state dynamical equilibrium for the surface-plasma system. This leads to the crater surface attaining a finite electric potential. Our analysis illustrates that the PSC having ∼100 nm dust, covering 1 per cent of the surface area within the electron-rich region, may acquire a negative potential of few hundred volts in the steady-state condition.

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The relationship between the moon cycle and the orientation of glass eels ( Anguilla anguilla ) at sea

Royal Society Open Science ◽

10.1098/rsos.190812 ◽

2019 ◽

Vol 6 (10) ◽

pp. 190812 ◽

Cited By ~ 5

Author(s):

Alessandro Cresci ◽

Caroline M. Durif ◽

Claire B. Paris ◽

Cameron R. S. Thompson ◽

Steven Shema ◽

...

Keyword(s):

Anguilla Anguilla ◽

Lunar Cycle ◽

Global Scale ◽

European Eel ◽

Sargasso Sea ◽

The Moon ◽

Detection Mechanism ◽

Freshwater Habitats ◽

Glass Eels ◽

Open Question

Links between the lunar cycle and the life cycle (migration patterns, locomotor activity, pulses in recruitment) of the European eel ( Anguilla anguilla ) are well documented. In this study, we hypothesized that the orientation of glass eels at sea is related to the lunar cycle. The European eel hatches in the Sargasso Sea and migrates across the Atlantic Ocean towards Europe. Upon reaching the continental shelf, the larvae metamorphose into glass eels and migrate up the estuaries, where some individuals colonize freshwater habitats. How glass eels navigate pelagic waters is still an open question. We tested the orientation of 203 glass eels in a transparent circular arena that was drifting in situ during the daytime, in the coastal Norwegian North Sea, during different lunar phases. The glass eels swimming at sea oriented towards the azimuth of the moon at new moon, when the moon rose above the horizon and was invisible but not during the other moon phases. These results suggest that glass eels could use the moon position for orientation at sea and that the detection mechanism involved is not visual. We hypothesize a possible detection mechanism based on global-scale lunar disturbances in electrical fields and discuss the implications of lunar-related orientation for the recruitment of glass eels to estuaries. This behaviour could help glass eels to reach the European coasts during their marine migration.

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