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738 results on '"Brain, David"'

1. Exoplanet Magnetic Fields

Author

Brain, David A., Kao, Melodie M., and O'Rourke, Joseph G.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Geophysics, Physics - Space Physics
Abstract

Planetary magnetic fields are important indicators of planetary processes and evolution, from a planet's outer core to its surface (if it possesses one) to its atmosphere and near-space environment. Magnetic fields are most directly measured in situ, and determining whether distant planetary objects possess magnetic fields can be challenging. At present we have no unambiguous measurements of magnetic fields on exoplanets. Nevertheless, it would be surprising if at least some exoplanets did not generate a magnetic field, like many planetary bodies in the solar system. This chapter provides an overview of the current understanding of exoplanetary magnetic fields and their consequences. In the next section we review the current understanding of planetary dynamo generation as it applies to solar system objects and discuss the implications for exoplanetary magnetic field generation. Following this, we describe seven methods for determining the existence and strength of an exoplanetary magnetic field and discuss the near-term prospects for each method. We close by highlighting four main consequences of exoplanetary magnetic fields for a planet and its evolution., Comment: Chapter 11 accepted for publication in the Reviews in Mineralogy and Geochemistry (RiMG) Volume 90 on "Exoplanets: Compositions, Mineralogy, and Evolution" edited by Natalie Hinkel, Keith Putirka, and Siyi Xu; 29 pages, 20 figures, 2 tables, and 12 equations

Published
2024

5. Exogeoscience and Its Role in Characterizing Exoplanet Habitability and the Detectability of Life

Author

Unterborn, Cayman, Byrne, Paul K, Anbar, Ariel D, Arney, Giada, Brain, David, Desch, Steve J, Foley, Bradford J, Gilmore, Martha S, Hartnett, Hilairy E, Henning, Wade G, Hirschmann, Marc M, Izenberg, Noam R, Kane, Stephen R, Kite, Edwin S, Kreidberg, Laura, Lee, Kanani KM, Lyons, Timothy W, Panero, Wendy R, Planavsky, Noah J, Reinhard, Christopher T, Renaud, Joseph P, Schaefer, Laura K, Schwieterman, Edward W, Sohl, Linda E, Tasker, Elizabeth J, and Way, Michael J

Published
2022

7. A Statistical Investigation of Factors Influencing the Magnetotail Twist at Mars.

Author

DiBraccio, Gina, Romanelli, Norberto, Bowers, Charles, Gruesbeck, Jacob, Halekas, Jasper, Ruhunusiri, Suranga, Weber, Tristan, Espley, Jared, Xu, Shaosui, Luhmann, Janet, Harada, Yuki, Dubinin, Eduard, Poh, Gang, Brain, David, and Curry, Shannon

Subjects
Mars, magnetic reconnection, magnetosphere, magnetotail
Abstract

The Martian magnetotail exhibits a highly twisted configuration, shifting in response to changes in polarity of the interplanetary magnetic fields (IMF) dawn-dusk (B Y) component. Here, we analyze ∼6000 MAVEN orbits to quantify the degree of magnetotail twisting (θ Twist) and assess variations as a function of (a) strong planetary crustal field location, (b) Mars season, and (c) downtail distance. The results demonstrate that θ Twist is larger for a duskward (+B Y) IMF orientation a majority of the time. This preference is likely due to the local orientation of crustal magnetic fields across the surface of Mars, where a +B Y IMF orientation presents ideal conditions for magnetic reconnection to occur. Additionally, we observe an increase in θ Twist with downtail distance, similar to Earths magnetotail. These findings suggest that coupling between the IMF and moderate-to-weak crustal field regions may play a major role in determining the magnetospheric structure at Mars.

Published
2022

10. Exogeoscience and Its Role in Characterizing Exoplanet Habitability and the Detectability of Life

Author

Unterborn, Cayman T., Byrne, Paul K., Anbar, Ariel D., Arney, Giada, Brain, David, Desch, Steve J., Foley, Bradford J., Gilmore, Martha S., Hartnett, Hilairy E., Henning, Wade G., Hirschmann, Marc M., Izenberg, Noam R., Kane, Stephen R., Kite, Edwin S., Kreidberg, Laura, Lee, Kanani K. M., Lyons, Timothy W., Olson, Stephanie L., Panero, Wendy R., Planavsky, Noah J., Reinhard, Christopher T., Renaud, Joseph P., Schaefer, Laura K., Schwieterman, Edward W., Sohl, Linda E., Tasker, Elizabeth J., and Way, Michael J.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics
Abstract

The search for exoplanetary life must encompass the complex geological processes reflected in an exoplanet's atmosphere, or we risk reporting false positive and false negative detections. To do this, we must nurture the nascent discipline of "exogeoscience" to fully integrate astronomers, astrophysicists, geoscientists, oceanographers, atmospheric chemists and biologists. Increased funding for interdisciplinary research programs, supporting existing and future multidisciplinary research nodes, and developing research incubators is key to transforming true exogeoscience from an aspiration to a reality., Comment: Submitted as white paper to 2023-2033 Planetary Science and Astrobiology Decadal Survey; Updated to include all co-authors

Published
2020

16. Planetary Magnetic Field Control of Ion Escape from Weakly Magnetized Planets

Author

Egan, Hilary, Jarvinen, Riku, Ma, Yingjuan, and Brain, David

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Intrinsic magnetic fields have long been thought to shield planets from atmospheric erosion via stellar winds; however, the influence of the plasma environment on atmospheric escape is complex. Here we study the influence of a weak intrinsic dipolar planetary magnetic field on the plasma environment and subsequent ion escape from a Mars sized planet in a global three-dimensional hybrid simulation. We find that increasing the strength of a planet's magnetic field enhances ion escape until the magnetic dipole's standoff distance reaches the induced magnetosphere boundary. After this point increasing the planetary magnetic field begins to inhibit ion escape. This reflects a balance between shielding of the southern hemisphere from ``misaligned" ion pickup forces and trapping of escaping ions by an equatorial plasmasphere. Thus, the planetary magnetic field associated with the peak ion escape rate is critically dependent on the stellar wind pressure. Where possible we have fit power laws for the variation of fundamental parameters (escape rate, escape power, polar cap opening angle and effective interaction area) with magnetic field, and assessed upper and lower limits for the relationships., Comment: Accepted to MNRAS. 17 pages, 10 figures

Published
2019
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17. Stellar Influence on Heavy Ion Escape from Unmagnetized Exoplanets

Author

Egan, Hilary, Jarvinen, Riku, and Brain, David

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Planetary habitability is in part determined by the atmospheric evolution of a planet; one key component of such evolution is escape of heavy ions to space. Ion loss processes are sensitive to the plasma environment of the planet, dictated by the stellar wind and stellar radiation. These conditions are likely to vary from what we observe in our own solar system when considering a planet in the habitable zone around an M-dwarf. Here we use a hybrid global plasma model to perform a systematic study of the changing plasma environment and ion escape as a function of stellar input conditions, which are designed to mimic those of potentially habitable planets orbiting M-dwarfs. We begin with a nominal case of a solar wind experienced at Mars today, and incrementally modify the interplanetary magnetic field orientation and strength, dynamic pressure, and Extreme Ultraviolet input. We find that both ion loss morphology and overall rates vary significantly, and in cases where the stellar wind pressure was increased, the ion loss began to be diffusion or production limited with roughly half of all produced ions being lost. This limit implies that extreme care must be taken when extrapolating loss processes observed in the solar system to extreme environments., Comment: Accepted to MNRAS. 10 pages, 3 figures, 2 tables

Published
2019
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18. The Super-Earth Opportunity - Search for Habitable Exoplanets in the 2020s

Author

Hu, Renyu, Beichman, Charles A., Brain, David, Chen, Pin, Damiano, Mario, Dawson, Rebekah, Friedson, A. James, Hasagawa, Yasuhiro, Howard, Andrew, Johnson, Robert, Kataria, Tiffany, Kidd, Richard, Kite, Edwin, Knutson, Heather, Lyra, Wladimir, Mischna, Michael, Planavsky, Noah, Reinhard, Chris, Schlichting, Hilke, Seager, Sara, Sotin, Christophe, Swain, Mark, Turner, Neal, West, Robert, Yung, Yuk, and Zellem, Robert

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The recent discovery of a staggering diversity of planets beyond the Solar System has brought with it a greatly expanded search space for habitable worlds. The Kepler exoplanet survey has revealed that most planets in our interstellar neighborhood are larger than Earth and smaller than Neptune. Collectively termed super-Earths and mini-Neptunes, some of these planets may have the conditions to support liquid water oceans, and thus Earth-like biology, despite differing in many ways from our own planet. In addition to their quantitative abundance, super-Earths are relatively large and are thus more easily detected than true Earth twins. As a result, super-Earths represent a uniquely powerful opportunity to discover and explore a panoply of fascinating and potentially habitable planets in 2020 - 2030 and beyond., Comment: Science white paper submitted to the 2020 Astronomy and Astrophysics Decadal Survey

Published
2019

22. The Inner Solar System's Habitability Through Time

Author

Del Genio, Anthony D., Brain, David, Noack, Lena, and Schaefer, Laura

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Earth, Mars, and Venus, irradiated by an evolving Sun, have had fascinating but diverging histories of habitability. Although only Earth's surface is considered to be habitable today, all three planets might have simultaneously been habitable early in their histories. We consider how physical processes that have operated similarly or differently on these planets determined the creation and evolution of their atmospheres and surfaces over time. These include the geophysical and geochemical processes that determined the style of their interior dynamics and the presence or absence of a magnetic field; the surface-atmosphere exchange processes that acted as a source or sink for atmospheric mass and composition; the Sun-planet interactions that controlled escape of gases to space; and the atmospheric processes that interacted with these to determine climate and habitability. The divergent evolutions of the three planets provide an invaluable context for thinking about the search for life outside the Solar System., Comment: Accepted; 55 pages, 5 figures, 1 table

Published
2018

23. Modeling Martian Atmospheric Losses over Time: Implications for Exoplanetary Climate Evolution and Habitability

Author

Dong, Chuanfei, Lee, Yuni, Ma, Yingjuan, Lingam, Manasvi, Bougher, Stephen, Luhmann, Janet, Curry, Shannon, Toth, Gabor, Nagy, Andrew, Tenishev, Valeriy, Fang, Xiaohua, Mitchell, David, Brain, David, and Jakosky, Bruce

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

In this Letter, we make use of sophisticated 3D numerical simulations to assess the extent of atmospheric ion and photochemical losses from Mars over time. We demonstrate that the atmospheric ion escape rates were significantly higher (by more than two orders of magnitude) in the past at $\sim 4$ Ga compared to the present-day value owing to the stronger solar wind and higher ultraviolet fluxes from the young Sun. We found that the photochemical loss of atomic hot oxygen dominates over the total ion loss at the current epoch whilst the atmospheric ion loss is likely much more important at ancient times. We briefly discuss the ensuing implications of high atmospheric ion escape rates in the context of ancient Mars, and exoplanets with similar atmospheric compositions around young solar-type stars and M-dwarfs., Comment: 6 pages, 4 figures, 1 table, accepted for publication in ApJ Letters

Published
2018
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24. Comprehensive Comparison of Two Global Multi‐Species MHD Models of Mars.

Author

Sun, Wenyi, Sakata, Ryoya, Ma, Yingjuan, Seki, Kanako, Russell, Christopher T., Terada, Naoki, Sakai, Shotaro, Shinagawa, Hiroyuki, Brain, David, and Toth, Gabor

Subjects
MARTIAN atmosphere, SPACE plasmas, MAGNETIC fields, MARS (Planet), MAGNETOHYDRODYNAMICS
Abstract

Understanding the interaction between Mars and the solar wind is crucial for comprehending the atmospheric evolution and climate change on Mars. To gain a comprehensive understanding of the Martian plasma environment, global numerical simulations are essential in addition to spacecraft observations. However, there are still discrepancies among different simulation models. This study investigates how these discrepancies stem from the considered physical processes and numerical implementations. We compare two global multispecies MHD models: the "Sun model" based on the BATS‐R‐US code and the "Sakata model" based on a newly developed multifluid model MAESTRO. By employing the same typical upstream conditions and the same neutral atmosphere for current Mars, along with similar numerical implementations such as inner boundary conditions, we obtain simulation results that exhibit unprecedented agreement between the two models. The dayside results are nearly identical, especially along the subsolar line, indicating the robustness of MHD models to predict dayside interaction under given upstream conditions and ionosphere assumptions. The escape rates of planetary ions are also in good agreement. However, discrepancies remain in the terminator and nightside regions. Detailed numerical implementations, including inner boundary conditions, magnetic field divergence control methods, and radial resolutions, are shown to influence certain aspects of the results greatly, such as magnetotail configuration and ion diffusion. Key Points: The same physical assumptions are employed for two different global multispecies MHD modelsThe results for the dayside interaction and planetary ion escape are in unprecedented good agreementDetails of the numerical implementations influence the results, especially on the nightside [ABSTRACT FROM AUTHOR]

Published
2024
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27. The Mars system revealed by the Martian Moons eXploration mission

Author

Ogohara, Kazunori, Nakagawa, Hiromu, Aoki, Shohei, Kouyama, Toru, Usui, Tomohiro, Terada, Naoki, Imamura, Takeshi, Montmessin, Franck, Brain, David, Doressoundiram, Alain, Gautier, Thomas, Hara, Takuya, Harada, Yuki, Ikeda, Hitoshi, Koike, Mizuho, Leblanc, François, Ramirez, Ramses, Sawyer, Eric, Seki, Kanako, Spiga, Aymeric, Vandaele, Ann Carine, Yokota, Shoichiro, Barucci, Antonella, and Kameda, Shingo

Published
2022
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28. Statistical Analysis of Discrete Aurora on Mars: Variability with Magnetic Topology, Local Time and Season

Author

Chirakkil, Krishnaprasad, primary, Lillis, Robert James, additional, Deighan, Justin, additional, Chaffin, Michael Scott, additional, Jain, Sonal, additional, Brain, David Andrew, additional, Fillingim, Matthew O., additional, Susarla, Raghuram, additional, Holsclaw, Gregory, additional, Fang, Xiaohua, additional, Schneider, Nicholas M., additional, Almazmi, Hoor, additional, Almatroushi, Hessa, additional, Gacesa, Marko, additional, and El-Kork, Nayla, additional

Published
2024
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33. Source of Drift-dispersed Electrons in Martian Crustal Magnetic Fields.

Author

Zhang, Chi, Zhou, Hongyang, Dong, Chuanfei, Harada, Yuki, Yamauchi, Masatoshi, Xu, Shaosui, Nilsson, Hans, Ebihara, Yusuke, Curry, Shannon M., Qin, Junfeng, Mitchell, David L., and Brain, David A.

Subjects
SOLAR magnetic fields, MARTIAN atmosphere, ELECTRON sources, SOLAR system, SOLAR wind
Abstract

Mars lacks a global intrinsic dipole field but possesses localized crustal fields, making it unique in the solar system. Recent observations revealed that electrons can be injected into the crustal fields, and exhibit drift-dispersed bursts due to the magnetic drift motion, which are characterized by increases or decreases in energy over time in the energy spectrum. However, the source of the drift-dispersed electrons and the mechanism of their injection into the crustal fields remains unclear. Here, by leveraging data from the Mars Atmosphere and Volatile EvolutioN mission, along with test-particle simulations, we reveal that the source of dispersed electrons is the precipitating electrons injected into the crustal fields via open field lines. These electrons display as dispersionless bursts near the source location, and as dispersed bursts as they drift away from the source. Thus, the dispersed electrons represent a later stage in the evolution of dispersionless electrons. This evolutionary process closely mirrors that observed within Earth's dipole field, affirming that the crustal fields function similarly to a mini-magnetosphere. [ABSTRACT FROM AUTHOR]

Published
2024
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36. Exploring Mars discrete aurora with synoptic images and movies from EMM EMUS

Author

Lillis, Robert, primary, Chirakkil, Krishnaprasad, additional, Deighan, Justin, additional, Fillingim, Matthew, additional, Jain, Sonal, additional, Chaffin, Michael, additional, Raghuram, Susarla, additional, Holsclaw, Gregory, additional, Almazmi, Hoor, additional, Brain, David, additional, Schneider, Nick, additional, Xu, Shaosui, additional, Halekas, Jasper, additional, Espley, Jared, additional, Gruesbeck, Jacob, additional, and Curry, Shannon, additional

Published
2024
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38. Solar and solar wind energy drivers for O+ and O2+ ion escape at Mars

Author

Schnepf, Neesha Regmi, primary, Dong, Yaxue, additional, Brain, David Andrew, additional, Hanley, Kathleen Gwen, additional, Peterson, William K., additional, Strangeway, Robert J, additional, Thiemann, Edward Michael Benjamin, additional, Halekas, Jasper S., additional, Espley, Jared Randolph, additional, Eparvier, Francis G., additional, and Mcfadden, James P., additional

Published
2024
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39. A parallel randomised trial testing community fibrosis assessment for suspected non-alcoholic fatty liver disease: Outcomes from LOCATE-NAFLD

Author

Tulleners, Ruth, primary, Barnett, Adrian, additional, O'Beirne, James, additional, Powell, Elizabeth, additional, Hickman, Ingrid, additional, Valery, Patricia, additional, Kularatna, Sanjeewa, additional, Stuart, Katherine, additional, McIvor, Carolyn, additional, Witness, Elen, additional, Aikebuse, Melanie, additional, and Brain, David, additional

Published
2024
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42. Temporal Variability of Waves at the Proton Cyclotron Frequency Upstream from Mars: Implications for Mars Distant Hydrogen Exosphere

Author

Bertucci, Cesar, Romanelli, Norberto, Chaufray, Jean-Yves, Gomez, Daniel, Mazelle, Christian, Delva, Magda, Modolo, Ronan, Gonzalez-Galindo, Francisco, and Brain, David Andrew

Subjects
Physics - Space Physics
Abstract

We report on the temporal variability of the occurrence of waves at the local proton cyclotron frequency upstream from the Martian bow shock from Mars Global Surveyor observations during the first aerobraking and science phasing orbit periods. Observations at high southern latitudes during minimum-to-mean solar activity show that the wave occurrence rate is significantly higher around perihelion southern summer solstice and lower around the same hemisphere's spring and autumn equinoxes. A similar trend is observed in the hydrogen (H) exospheric density profiles over the Martian South Pole obtained from a model including UV thermospheric heating effects. In spite of the complexity in the ion pick-up and plasma wave generation and evolution processes, these results support the idea that variations in the occurrence of waves could be used to study the temporal evolution of the distant Martian H corona and its coupling with the thermosphere at altitudes currently inaccessible to direct measurements., Comment: 16 pages, 2 figures, Submitted to Geophysical Research Letters

Published
2013
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43. Emirates Mars Mission Characterization of Mars Atmosphere Dynamics and Processes

Author

Almatroushi, Hessa, AlMazmi, Hoor, AlMheiri, Noora, AlShamsi, Mariam, AlTunaiji, Eman, Badri, Khalid, Lillis, Robert J., Lootah, Fatma, Yousuf, Maryam, Amiri, Sarah, Brain, David A., Chaffin, Michael, Deighan, Justin, Edwards, Christopher S., Forget, Francois, Smith, Michael D., Wolff, Michael J., Christensen, Philip R., England, Scott, Fillingim, Matthew, Holsclaw, Gregory M., Jain, Sonal, Jones, Andrew R., Osterloo, Mikki, Jakosky, Bruce M., Luhmann, Janet G., and Young, Roland M. B.

Published
2021
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44. Sinuous Aurora at Mars: A Link to the Tail Current Sheet?

Author

Lillis, Robert J., Deighan, Justin, Chirakkil, Krishnaprasad, Jain, Sonal, Fillingim, Matthew, Chaffin, Michael, Holsclaw, Greg, Susarla, Raghuram, Brain, David, Al Matroushi, Hessa, Lootah, Fatma, Al Mazmi, Hoor, Dong, Yaxue, Schneider, Nick, Azari, Abigail, Ramstad, Robin, Nauth, Murti, Ma, Yingjuan, Halekas, Jasper, and Espley, Jared

Subjects
CURRENT sheets, INTERPLANETARY magnetic fields, SOLAR wind, CONVECTION (Astrophysics), MARS (Planet), AURORAS
Abstract

We examine the newly discovered phenomena of sinuous aurora on the nightside of Mars, using images of 130.4 and 135.6 nm oxygen emission measured by the Emirates Mars Mission EMUS ultraviolet spectrograph, and upstream measurements from the MAVEN and Mars Express spacecraft. They are detected in ∼3% of observations, totaling 73 clear detections. These emissions are narrow, elongated (1,000–6,000 km), cross Mars' UV terminator, and are oriented generally toward the anti‐solar point, clustering into north, south, east, and west‐oriented groups. Diverse morphologies are observed, though some spatial features, such as broad curves, may in some cases be due to temporal aliasing of aurora motion as each image is built up over 15–20 min. Sinuous aurora form away from Mars' strongest crustal magnetic fields and can be interrupted by moderate crustal fields. Sinuous aurora occurrence increases strongly with solar wind pressure, though brightness shows only a weak positive dependence on pressure. Interplanetary magnetic field (IMF) clock angle affects their occurrence and orientation: sinuous aurora show a broad range of orientations centered on the solar wind convection electric field (Econv) direction and forming in the +Econv hemisphere, although with moderate clockwise and counterclockwise average "twists" for westward and eastward IMF, respectively. From these features we infer a link between sinuous aurora and electron energization in Mars' magnetotail current sheet, where field geometry on the +Econv side of the sheet is more organized and symmetric. Determination of specific triggering conditions for sinuous aurora requires further investigation. Plain Language Summary: Sinuous aurora are narrow, extended patterns of UV emission caused by long, thin channels of energized electrons striking Mars' nightside upper atmosphere. We study images of these aurora taken by the Emirates Mars Mission EMUS instrument. 73 cases of sinuous auroras were found (∼3% occurrence rate) with lengths ranging from 1,000 to 6,000 km. These auroras usually cross Mars' day‐night boundary and extend in the direction opposite to the Sun. They tend to cluster into groups oriented toward the north, south, east, and west directions with a diverse array of shapes. Sinuous aurora generally form away from Mars' strongest crustal magnetic fields. They occur more frequently for higher solar wind pressure. Their orientations are affected by the interplanetary magnetic field (IMF), displaying a broad range of orientations centered on the direction of the electric field in the solar wind, and forming in the hemisphere to which this electric field points, although with moderate counterclockwise and clockwise average "twists" for eastward and westward IMF, respectively. From these features we infer a link between sinuous aurora and a sheet of current in Mars magnetic tail, wherein the aurora‐causing electrons may be energized before falling into the upper atmosphere to produce aurora. Key Points: These narrow emission features form away from strong crustal fields, oriented anti‐sunward, cross the terminator, are detected in 3% observationsOccurrence increases with solar wind pressure, certain interplanetary magnetic field orientations, and in the positive motional electric field hemisphereSinuous aurora may be related to magnetotail asymmetry and electron energization processes occurring in the tail current sheet [ABSTRACT FROM AUTHOR]

Published
2024
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45. EMM EMUS Observations of FUV Aurora on Mars: Dependence on Magnetic Topology, Local Time, and Season.

Author

Chirakkil, Krishnaprasad, Lillis, Robert J., Deighan, Justin, Chaffin, Michael S., Jain, Sonal K., Brain, David A., Fillingim, Matthew O., Susarla, Raghuram, Holsclaw, Greg, Fang, Xiaohua, Schneider, Nick M., AlMazmi, Hoor, AlMatroushi, Hessa, Gacesa, Marko, El‐Kork, Nayla, Thiemann, Ed, and Halekas, Jasper S.

Subjects
THERMOSPHERE, AURORAS, SPACE environment, CORONAL mass ejections, MARS (Planet), SOLAR cycle
Abstract

We present a comprehensive study of the nightside aurora phenomenon on Mars, utilizing observations from EMUS onboard Emirates Mars Mission. The oxygen emission at 130.4 nm is by far the brightest FUV auroral emission line observed at Mars. Our statistical analysis reveals geographic, solar zenith angle, local time, and seasonal dependencies of auroral occurrence. Higher occurrence of aurora is observed in regions of open magnetic topology, where crustal magnetic fields are either very weak or both strong and vertical. Aurora occurs more frequently closer to the terminator and is more likely on the dusk side than on the dawn side of the night hemisphere. A pronounced auroral feature appears close to midnight local times in the southern hemisphere, consistent with the spot of energetic electron fluxes previously identified in the Mars Global Surveyor data. This auroral spot is more frequent after midnight than before. Additionally, some regions on Mars are "aurora voids" where essentially no aurora occurs. Aurora exhibits a seasonal dependence, with a major enhancement near perihelion. Non–crustal field aurora additionally shows a secondary enhancement near Ls 30°. This seasonal variability is a combination of the variability in ionospheric photoelectrons and thermospheric atomic oxygen abundance. Auroral occurrence also shows an increase with the rise of Solar Cycle 25. The brightest auroral pixels are observed during space weather events such as Coronal Mass Ejections and Stream Interaction Regions. These observations not only shed light on where and when Martian aurora occurs, but also add to our understanding of Mars' magnetic environment and its interaction with the heliosphere. Plain Language Summary: In this study, we explore the phenomenon of aurora on the nightside of Mars, using observations from the highly sensitive Emirates Mars Ultraviolet Spectrometer (EMUS) on the Emirates Mars Mission. Our analysis reveals distinct patterns in auroral occurrence on the planet. For instance, there is a higher rate of auroral activity in regions where Mars' magnetic field lines are open (i.e., connected to the collisional atmosphere at one end). We also found that aurora is more common near the terminator (with the occurrence decreasing as the solar zenith angle increases), and particularly during the evening hours, as opposed to early morning. Interestingly, these auroral events also show a seasonal dependence, peaking around perihelion in a Martian year, when Mars is closest to the sun. This seasonal pattern corresponds with the variation of photoelectrons in Mars' dayside ionosphere and the atomic oxygen abundance in the thermosphere. Auroral occurrence increases with increasing solar activity. Also, the auroral brightness increases during space weather events. Our study not only gives us a clearer picture of where and when the aurora occurs on Mars but also hints at the underlying processes influencing them, offering insights into the planet's magnetic and charged particle environment. Key Points: Higher auroral occurrence is observed in regions of open magnetic topology, where crustal fields are either very weak or primarily verticalAurora occurs more frequently near the terminator compared to deep night, with higher occurrence at dusk than at dawnAurora occurs more frequently near perihelion, with the brightest auroral pixels observed during space weather events [ABSTRACT FROM AUTHOR]

Published
2024
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47. A randomised control trial investigating the effect of improving the cleaning of shared medical equipment on healthcare-associated infections (The CLEEN study): Statistical Analysis Plan

Author

White, Nicole, primary, Cheng, Allen, additional, Browne, Katrina, additional, Russo, Philip, additional, Stewardson, Andrew, additional, Amin, Maham, additional, Graham, Kirsty, additional, King, Jennie, additional, Tehan, Peta, additional, Brain, David, additional, Northcote, Maria, additional, and Mitchell, Brett, additional

Published
2023
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49. EMM EMUS Observations of Hot Oxygen Corona at Mars: Radial Distribution and Temporal Variability

Author

Chirakkil, Krishnaprasad, primary, Deighan, Justin, additional, Chaffin, Michael Scott, additional, Jain, Sonal, additional, Lillis, Robert James, additional, Raghuram, Susarla, additional, Holsclaw, Gregory, additional, Brain, David Andrew, additional, Thiemann, Edward Michael Benjamin, additional, Chamberlin, Phillip C, additional, Fillingim, Matthew O., additional, Evans, Joseph Scott, additional, England, Scott L, additional, Almatroushi, Hessa, additional, Almazmi, Hoor, additional, Eparvier, Francis G., additional, Gacesa, Marko, additional, El-Kork, Nayla, additional, and Curry, Shannon M., additional

Published
2023
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50. How digital health translational research is prioritised: a qualitative stakeholder-driven approach to decision support evaluation

Author

Bamgboje-Ayodele, Adeola, primary, McPhail, Steven M, additional, Brain, David, additional, Taggart, Richard, additional, Burger, Mitchell, additional, Bruce, Lenert, additional, Holtby, Caroline, additional, Pradhan, Malcolm, additional, Simpson, Mark, additional, Shaw, Tim J, additional, and Baysari, Melissa T, additional

Published
2023
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