Your search keyword '"Oxygen ions"' showing total 21 results

1. The Energetic Oxygen Ion Beams in the Martian Magnetotail Current Sheets: Hints From the Comparisons Between Two Types of Current Sheets.

Author

Zhang, Chi, Rong, Zhaojin, Li, Xinzhou, Fränz, Markus, Nilsson, Hans, Jarvinen, Riku, Persson, Moa, Futaana, Yoshifumi, Dong, Chuanfei, Yamauchi, Masatoshi, Gao, Jiawei, Zhou, Yijia, Wang, Lei, Shi, Zhen, Wei, Yong, He, Fei, Holmström, Mats, and Barabash, Stas

Subjects

*CURRENT sheets, *ION beams, *SOLAR wind, *MARTIAN atmosphere, *MAGNETIC structure, *OXYGEN, *ELECTRIC fields

Abstract

Using data from the Mars Atmosphere and Volatile EvolutioN (MAVEN) mission, we explore the plasma properties of Martian magnetotail current sheets (CS), to further understand the solar wind interaction with Mars and ion escape. There are some CS exhibit energetic oxygen ions that show narrow beam structures in the energy spectrum, which primarily occurs in the hemisphere where the solar wind electric field (Esw) is directed away from the planet. On average, these CS have a higher escaping flux than that of the CS without energetic oxygen ion beams, suggesting different roles in ion escape. The CS with energetic oxygen ion beams exhibits different proton and electron properties to the CS without energetic oxygen ion beams, indicating their different origins. Our analysis suggests that the CS with energetic oxygen ion beams may result from the interaction between the penetrated solar wind and localized oxygen ion plumes. Plain Language Summary: Ion escape into space, driven by solar wind interactions with Mars, plays a pivotal role in the evolution of the Martian atmosphere. An important escape channel of planetary oxygen ions is the current sheet in the nightside magnetotail. Yet, our existing understanding of plasma characteristics within this magnetic structure remains quite limited. Based on the MAVEN observations, we find the current sheets can be categorized into two distinct types according to the energy distribution patterns of oxygen ions: one is with the appearance of energetic oxygen ions with narrow beam structure, the other one is not. On average, the current sheets with energetic oxygen ion beams have a higher escaping flux than those without, suggesting different roles in ion escape. Furthermore, the two types of current sheets exhibit markedly distinct plasma properties, indicating that they have different origins. Here we suggest that the current sheet with energetic oxygen ion beams arise from the interaction between the penetrated solar wind and localized oxygen ion plumes. Key Points: Martian magnetotail current sheets occasionally exhibit energetic oxygen ions that show beam structures in the energy spectrumThe current sheets with energetic oxygen ion beam usually have a higher escaping flux than those withoutPlasma properties in current sheets differ significantly differences between those with and without energetic oxygen ion beams [ABSTRACT FROM AUTHOR]

Published

2024

2. The Energetic Oxygen Ion Beams in the Martian Magnetotail Current Sheets: Hints From the Comparisons Between Two Types of Current Sheets

Author

Chi Zhang, Zhaojin Rong, Xinzhou Li, Markus Fränz, Hans Nilsson, Riku Jarvinen, Moa Persson, Yoshifumi Futaana, Chuanfei Dong, Masatoshi Yamauchi, Jiawei Gao, Yijia Zhou, Lei Wang, Zhen Shi, Yong Wei, Fei He, Mats Holmström, and Stas Barabash

Subjects

Mars, ion escape, current sheet, oxygen ions, magnetotail, solar wind, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Using data from the Mars Atmosphere and Volatile EvolutioN (MAVEN) mission, we explore the plasma properties of Martian magnetotail current sheets (CS), to further understand the solar wind interaction with Mars and ion escape. There are some CS exhibit energetic oxygen ions that show narrow beam structures in the energy spectrum, which primarily occurs in the hemisphere where the solar wind electric field (Esw) is directed away from the planet. On average, these CS have a higher escaping flux than that of the CS without energetic oxygen ion beams, suggesting different roles in ion escape. The CS with energetic oxygen ion beams exhibits different proton and electron properties to the CS without energetic oxygen ion beams, indicating their different origins. Our analysis suggests that the CS with energetic oxygen ion beams may result from the interaction between the penetrated solar wind and localized oxygen ion plumes.

Published

2024

3. Dispersive Alfvén Wave Control of O+ Ion Outflow and Energy Densities in the Inner Magnetosphere

Author

A. J. Hull, C. C. Chaston, J. W. Bonnell, J. R. Wygant, C. A. Kletzing, G. D. Reeves, and A. Gerrard

Subjects

dispersive Alfven waves, ion outflow, inner magnetosphere, geomagnetic storms, substorms, oxygen ions, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract The relationship between dispersive Alfvén waves (DAWs), magnetospheric activity, and O+ ion outflow/energy density is examined using measurements from the Van Allen Probes. We show that correlated DAW activity and O+ outflow/energization is a characteristic feature of the inner magnetosphere during active conditions and during storms persists for several hours over large L‐shell and azimuthal ranges of the plasma sheet. Though enhanced during substorm and storm active periods, these correlated features are most intense during geomagnetic storms. Comparisons show a linear relationship between DAW electric (and magnetic) field energy density and outflowing O+ energy. Statistical measurements from a large number of storms also reveal a linear relationship between DAW energy density and gross enhancements in energetic O+ energy densities. These observations support the notion that DAWs play an important role in the energization of O+ ions into and within the inner magnetosphere.

Published

2019

4. On the Species Dependence of Ion Escapes Across the Magnetopause.

Author

Zhou, Xu‐Zhi, Zhang, Xuan, Li, Jing‐Huan, and Zong, Qiu‐Gang

Subjects

*MAGNETOPAUSE, *GEOMAGNETISM, *PLASMA sheaths, *SOLAR wind, *PARTICLE tracks (Nuclear physics), *HEAVY ions, *SQUARE root, *IONS

Abstract

Recent observations and particle‐tracing models have revealed a counterintuitive difference between the behaviors of magnetospheric protons and oxygen ions when they encounter the magnetopause. The oxygen ions usually meander around the magnetopause without a full escape to the magnetosheath, whereas the protons can more easily stream across the magnetopause despite their smaller gyroradii. Here, we analytically identify the mechanisms that cause this species dependence. As magnetospheric ions drift toward the magnetopause, the grazing angle of their magnetopause encounter is constrained within a narrow range near 0°, with its maximum being proportional to the square root of the ion gyroradius. It is the grazing angle that largely determines the follow‐up ion motion. The ions with larger grazing angles would meander around the magnetopause, whereas the meandering motion for ions with smaller grazing angles could be easily disrupted to enable their escape even if the normal magnetic field is very weak. Plain Language Summary: The Earth's magnetic field is constrained by the interplanetary field within a finite region named the magnetosphere. The boundary of this region, the magnetopause, separates the magnetospheric plasma from the cooler and denser population in the shocked solar wind. Some of the magnetospheric particles, however, can still penetrate the magnetopause and escape into the interplanetary space. One may expect that heavy ions, like singly charged oxygen ions, are more likely to escape than protons due to their larger gyroradii; however, the opposite trend has been identified in spacecraft observations. This counterintuitive feature, although reproduced in a particle‐tracing model, has not yet been fully understood. Here, we analyze the particle trajectories to identify the mechanism underlying the species dependence of the ion escape. When magnetospheric ions encounter the magnetopause, their grazing angles are constrained within a narrow range near 0°, with the maximum angle depending positively on ion gyroradius. We find that the ions with larger grazing angles would meander around the magnetopause without a full escape, whereas the meandering motion for those with smaller angles could be more easily disrupted by a weak normal magnetic field to enable their field‐aligned escape. Key Points: Despite their smaller gyroradii, protons are found more likely to escape from the magnetosphere than oxygen ionsA mechanism leading to the counterintuitive species dependence is analytically identified based on a simple modelThe model also explains the bifurcated gyrophase bunching of the oxygen ions observed in the magnetosheath [ABSTRACT FROM AUTHOR]

Published

2021

5. Cluster Observations on Time‐of‐Flight Effect of Oxygen Ions in Magnetotail Reconnection Exhaust Region.

Author

Wu, T., Fu, S. Y., Xie, L., Zong, Q.‐G., Zhou, X. Z., Yue, C., Sun, W. J., Pu, Z. Y., Xiong, Y., Zhao, S. J., Zhang, H., and Yu, F. B.

Subjects

*ION mobility, *IONS, *GEOMAGNETISM, *KINETIC energy

Abstract

The D‐shaped ion velocity distribution generated by the time‐of‐flight (ToF) effect can be considered as an important characteristic of reconnection exhausts in the magnetopause and magnetotail reconnection processes. In this study, we reported the D‐shaped velocity distribution of O+ ions produced by the ToF effect in the magnetotail reconnection exhaust based on the observations from the Cluster spacecraft. The observed cutoff velocity of O+ ions is smaller than that of H+ ions at the same time, which is different from the previous theoretical prediction. We suggested that the difference between the two cutoff velocities is probably due to O+ ions having a larger reconnection diffusion region than H+ ions. We also demonstrated a remote‐sensing method to estimate the spatial scale ratio between the O+ and H+ diffusion regions and the distance from the observation site to the center of the magnetotail reconnection region. Plain Language Summary: The reconnection processes at the Earth's magnetopause and magnetotail can convert the magnetic energy into the kinetic energy of the plasma, thus producing high‐speed reconnection exhausts. The exhausting ions usually show a D‐shaped velocity distribution caused by the time‐of‐flight effect. Previous works usually focused only on exhausting protons from the reconnection site, while O+ ions could also be abundant during geomagnetic active times. In this study, we analyzed a reconnection event to investigate the behaviors of O+ and H+ ions in the magnetotail reconnection exhaust region using the observations from the Cluster spacecraft. It is suggested that different behaviors of H+ and O+ ions are probably due to O+ ions having a larger reconnection diffusion region than H+ ions. In addition, we proposed a remote‐sensing method to estimate the spatial scale ratio between the O+ and H+ diffusion regions and the distance from the observation site to the center of the magnetotail reconnection region. Key Points: The time‐of‐flight effect of O+ ions in magnetotail reconnection exhaust was observed by the Cluster spacecraftThe observed cutoff velocity of O+ is smaller than that of H+, indicating that O+ may have a larger diffusion region than H+A remote‐sensing method to estimate the spatial scale ratio between O+ and H+ diffusion regions is introduced [ABSTRACT FROM AUTHOR]

Published

2020

6. Dispersive Alfvén Wave Control of O+ Ion Outflow and Energy Densities in the Inner Magnetosphere.

Author

Hull, A. J., Chaston, C. C., Bonnell, J. W., Wygant, J. R., Kletzing, C. A., Reeves, G. D., and Gerrard, A.

Subjects

*MAGNETOSPHERE, *ION energy, *PLASMA Alfven waves, *ENERGY density, *MAGNETIC storms, *WAVE energy

Abstract

The relationship between dispersive Alfvén waves (DAWs), magnetospheric activity, and O+ ion outflow/energy density is examined using measurements from the Van Allen Probes. We show that correlated DAW activity and O+ outflow/energization is a characteristic feature of the inner magnetosphere during active conditions and during storms persists for several hours over large L‐shell and azimuthal ranges of the plasma sheet. Though enhanced during substorm and storm active periods, these correlated features are most intense during geomagnetic storms. Comparisons show a linear relationship between DAW electric (and magnetic) field energy density and outflowing O+ energy. Statistical measurements from a large number of storms also reveal a linear relationship between DAW energy density and gross enhancements in energetic O+ energy densities. These observations support the notion that DAWs play an important role in the energization of O+ ions into and within the inner magnetosphere. Plain Language Summary: Geomagnetic storms are major disturbances in the Earth's magnetosphere, during which the particle content and pressure in the magnetosphere increase considerably. Much of the pressure increase is due to singly charged oxygen ions that come from the ionosphere. How this happens is not clear. Analyzing satellite observations, we found evidence suggesting that a particular type of low‐frequency electromagnetic wave called a dispersive Alfvén wave may be playing a key role. These waves are found to be more prevalent and intense in the magnetosphere during storms. Oxygen ion energies are shown to increase with increasing intensities of these waves. The oxygen ion contribution to pressure also increases in association with intensified wave activity. These observations support the notion that the waves energize and heat oxygen ions into and within the magnetosphere over extended periods of time, which leads to significant magnetospheric pressure increases. Key Points: Dispersive Alfven wave energy density is enhanced during substorms and geomagnetic stormsOxygen ion outflow energy and energy density are correlated with dispersive Alfven wave energy densityObservations support modeling that dispersive Alfven waves enhance oxygen ion energy density in the inner magnetosphere [ABSTRACT FROM AUTHOR]

Published

2019

7. Dispersive Alfvén Wave Control of O + Ion Outflow and Energy Densities in the Inner Magnetosphere

Author

Andrew J. Gerrard, John Wygant, Craig Kletzing, Christopher C. Chaston, John W. Bonnell, Geoff Reeves, and A. J. Hull

Subjects

Geomagnetic storm, Alfvén wave, Physics, Geophysics, Oxygen ions, General Earth and Planetary Sciences, Magnetosphere, Outflow, Atomic physics, Energy (signal processing), Ion

Published

2019

8. Excitation of Oxygen Ion Cyclotron Harmonic Waves in the Inner Magnetosphere: Hybrid Simulations

Author

Bolu Feng, Kaijun Liu, Yan Wang, and Kyungguk Min

Subjects

Physics, Geophysics, law, Singular value decomposition method, Cyclotron, Oxygen ions, General Earth and Planetary Sciences, Magnetosphere, Atomic physics, Electron scattering, Excitation, law.invention

Published

2020

9. Oxygen Ion Escape From Venus Is Modulated by Ultra‐Low Frequency Waves

Author

I. Pulkkinen Tuija, Markku Alho, Esa Kallio, Riku Jarvinen, Tuija Pulkkinen Group, Esa Kallio Group, Department of Electronics and Nanoengineering, Aalto-yliopisto, and Aalto University

Subjects

Materials science, 010504 meteorology & atmospheric sciences, biology, Astrophysics::High Energy Astrophysical Phenomena, Venus, biology.organism_classification, 01 natural sciences, Foreshock, Geophysics, Physics::Plasma Physics, 13. Climate action, Physics::Space Physics, 0103 physical sciences, Oxygen ions, Astrophysics::Solar and Stellar Astrophysics, General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics, Atomic physics, 010303 astronomy & astrophysics, Ultra low frequency, 0105 earth and related environmental sciences

Abstract

We study the solar wind-driven, nonthermal escape of O+ ions from Venus in a global hybrid simulation. In the model, a well-developed ion foreshock forms ahead of the Venusian quasi-parallel bow shock under nominal upstream conditions. Large-scale magnetosonic ultra-low frequency (ULF) waves at 20- to 30-s period are excited and convect downstream along the foreshock with the solar wind. We show that the foreshock ULF waves transmit through the bow shock in the downstream region and interact with the planetary ion acceleration, causing 25% peak-to-peak fluctuations in the O+ escape rate. These results demonstrate the importance of upstream plasma waves on the energization and escape of heavy ions from the planetary atmospheres.

Published

2020

10. Cluster Observations on Time‐of‐Flight Effect of Oxygen Ions in Magnetotail Reconnection Exhaust Region

Author

Ying Xiong, Q.-G. Zong, Xu-Zhi Zhou, S. J. Zhao, Weijie Sun, Zuyin Pu, Lun Xie, H. Zhang, S. Y. Fu, Chao Yue, Tong Wu, and F. B. Yu

Subjects

Physics, Thesaurus (information retrieval), Time of flight, Geophysics, Chemical substance, Oxygen ions, Cluster (physics), General Earth and Planetary Sciences, Magnetic reconnection, Astrophysics

Published

2020

11. Direct observation of lunar pick-up ions near the Moon

Author

K. Cierpka, George Gloeckler, Antoinette B. Galvin, B. Wilken, A. Söding, Fritz M. Neubauer, Urs Mall, and E. Kirsch

Subjects

Physics, Spectrometer, Spacecraft, business.industry, Direct observation, Astronomy, Ionic composition, Ion, Astrobiology, Lunar water, Geophysics, Oxygen ions, General Earth and Planetary Sciences, Ion distribution, business

Abstract

Measurements made with the Suprathermal Ion Spectrometer (STICS) on the WIND spacecraft during 17 lunar fly-bys which took place between 1995 and 1997 allow the direct observations of lunar pick-up ions (PUI's) on the earthwards side of the Moon as close as 17 lunar radii. The composition measurements reveal an O+, an Al+, Si+ and possibly a P+ component.

Published

1998

12. Species dependent energies in upward directed ion beams over auroral arcs as observed with FAST TEAMS

Author

C. W. Carlson, Cynthia A Cattell, Robert J. Strangeway, J. P. McFadden, M. Temerin, B. Klecker, Eberhard Möbius, E. G. Shelley, R. C. Elphic, F. S. Mozer, D. Hovestadt, David Klumpar, Robert F. Pfaff, Robert E. Ergun, W. K. Peterson, Mark A. Popecki, L. M. Kistler, Eric J. Lund, and L. Tang

Subjects

Solar minimum, Physics, Geophysics, Ion beam, Energy spectrum, Oxygen ions, Physics::Accelerator Physics, General Earth and Planetary Sciences, Statistical analysis, Atomic physics, Mass spectrometry, Beam (structure), Ion

Abstract

Upward flowing field-aligned ion beams over auroral arcs have been observed with the 3-dimensional ion mass spectrograph TEAMS on FAST. We have performed a statistical study on a sample of 77 ion beams from the auroral campaign in early 1997. All observed beams contain substantial amounts of H+, He+ and O+. A clear ordering of the total energies according to mass is found, with H+ having the lowest and O+ the highest energy. The composition varies significantly from beam to beam, with O+/H+ ratios ranging from ≈ 0.1 to 10. No variation of the energy ratio between species is observed as a function of relative abundance. These results are discussed in the light of earlier observations of higher energies for O+ in statistical studies of beams during solar minimum and attempts to explain this behavior in terms of beam instabilities.

Published

1998

13. Determination of the heliospheric axis orientation-An opportunity for the Cassini Mission to Saturn

Author

H. Fichtner, Urs Mall, Daniel Rucinski, and D. C. Hamilton

Subjects

Physics, Spacecraft, business.industry, Astronomy, Astrobiology, Geophysics, Orientation (geometry), Saturn, Trajectory, Oxygen ions, General Earth and Planetary Sciences, Interplanetary spaceflight, business, Heliosphere

Abstract

Pick-up ion measurements that could be made during the interplanetary cruise of the Cassini spacecraft to Saturn offer a unique opportunity to determine the orientation of the upwind-downwind axis of the heliosphere. The method and results of a feasibility study are presented. The study shows that pick-up oxygen is the best candidate for such a measurement. Model computations are used to predict the actual pick-up oxygen fluxes which instruments on the Cassini spacecraft would see along its trajectory for several currently debated upwind-downwind axis orientations.

Published

1996

14. Kinetic temperature ratios of O6+and He2+: Observations from Wind/MASS and Ulysses/SWICS

Author

George Gloeckler, R. von Steiger, R. B. Sheldon, C. M. S. Cohen, Michael R. Collier, B. Wilken, and D. C. Hamilton

Subjects

Physics, Solar wind, Geophysics, Mean kinetic temperature, Helium ions, Physics::Space Physics, Thermal, Oxygen ions, Astrophysics::Solar and Stellar Astrophysics, General Earth and Planetary Sciences, Atomic physics, Kinetic energy, Computational physics

Abstract

We present results from a two spacecraft study of the ratio of O 6+ and He 2+ kinetic temperatures as a function of solar wind speed. Data from the Wind/MASS and Ulysses/SWICS instruments both indicate the O 6+ /He 2+ kinetic temperature ratio increases with increasing solar wind speed, peaking near 500 km/s. Above 500 km/s, the ratio appears to decrease slightly. Values near unity were obtained for slow solar wind while fast wind yielded ratios substantially higher than what is expected from the general rule T i /T j ≃M i /M j . (1) Although averaging over all data would result in the nominal ratio of 4, deviations from equation (1) appear to be common and the assumption of equal thermal velocities should not be made a priori.

Published

1996

15. Signatures of impulsive convection in the magnetospheric lobes

Author

J. A. Sauvaud, J. H. Waite, James L. Burch, L. A. Avanov, Oleg Vaisberg, and Dominique Delcourt

Subjects

Convection, Cusp (singularity), Physics, Field line, Magnetosphere, Geophysics, Computational physics, Ion, Electric field, Physics::Space Physics, Oxygen ions, General Earth and Planetary Sciences, Transient (oscillation)

Abstract

We analyze the injections of tailward flowing O+ ions measured by PROGNOZ-8 in the magnetospheric lobes using three-dimensional single-particle codes. These injections are shaped as “inverted Vs” and unexpectedly well correlated with AE variations during a time interval of about 7 hours. Such a correlation leads us to consider the effect of transient intensification of the large-scale magnetospheric convection. Using a simple model of time-varying electric field, we show that the source of the O+ lies near the dayside cusp. This source extends over a narrow (a few degrees) latitudinal interval in the vicinity of the last closed field line, likely involving ions expelled into the magnetosphere after being transversely accelerated. We demonstrate that, downstream of the ejection site, impulsive convection leads to prominent structuring of the tailward streaming particles with abrupt energy variations on small length scales. A good agreement is obtained between the numerical results and the observations which supports our impulsive convection based interpretation framework.

Published

1996

16. Indications for ionospheric participation in the substorm process from AMPTE/CCE observations

Author

Ioannis A. Daglis, G. Kremser, and E. T. Sarris

Subjects

Physics, Growth phase, Night sky, Plasma sheet, Magnetosphere, Geophysics, Physics::Geophysics, Atmosphere of Earth, Physics::Space Physics, Substorm, Oxygen ions, General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics, Ionosphere

Abstract

Observations with the AMPTE/CCE spacecraft in the near-earth nightside magnetosphere show a significant enhancement of ionospheric particle presence, mainly O(+), at the beginning of the substorm growth phase. Such an enhancement indicates not only an ionospheric participation in the substorm initiation, but also an active role in the substorm growth phase.

Published

1990

17. Critical comparison of OII(732-733 nm), OI(630 nm), and N2(1PG) emissions in auroral rays

Author

Joshua Semeter

Subjects

Geophysics, Altitude, Materials science, Excited state, Analytical chemistry, Atomic oxygen, Oxygen ions, General Earth and Planetary Sciences, Emission spectrum, Ionosphere, Atmospheric sciences, Electron ionization

Abstract

[1] All-sky spectral imagery has been used to study the altitude distribution of OII(732–733 nm), OI(630 nm), and N2(1PG) emissions in tall auroral rays appearing at the poleward edge of the auroral oval. The OII(732–733 nm) emission layer was consistently higher than the OI(630 nm) emission layer in these structures; the peak emission altitudes were estimated to be ∼380 km and ∼240 km, respectively. Neither the high absolute altitude of the OII(732–733 nm) peak nor its >100 km offset from the OI(630 nm) peak are consistent with published model results, which consider electron impact on atomic oxygen as the sole source of auroral O+(2P). The present results suggest that O+(2P) may also be excited directly from ambient ionospheric O+(4S) atoms. Other contributing factors may include a significant underestimation of the rate coefficients for O+(2P) quenching, or field-aligned up-flows of ionospheric O+.

Published

2003

18. Ionospheric evidence of hot oxygen in the upper atmosphere of Venus

Author

R. Kohli, N.K. Sethi, K. K. Mahajan, and S. Ghosh

Subjects

biology, chemistry.chemical_element, Venus, biology.organism_classification, Atmospheric sciences, Oxygen, Physics::History of Physics, Ion, Atmosphere of Venus, Solar wind, Geophysics, chemistry, Physics::Space Physics, Oxygen ions, General Earth and Planetary Sciences, Dynamic pressure, Astrophysics::Earth and Planetary Astrophysics, Ionosphere, Physics::Atmospheric and Oceanic Physics, Geology

Abstract

Model calculations, as well as optical observations, have shown that hot oxygen is the dominant neutral constituent up to about 3000 km in the upper atmosphere of Venus. Consequently O+ is expected to be the dominant ion up to about 3000 km in the upper ionosphere of Venus. Under normal circumstances, it is difficult to verify this result, since the solar wind interaction terminates the Venus ionosphere at altitudes below about 500 km for subsolar conditions. However, the upper boundary of the Venus ionosphere can move up to very high altitudes during some rare events when the solar wind dynamic pressure is extremely low. An analysis of Pioneer Venus measurements during such events indeed shows O+ to be the dominant ion at altitudes even as high as 2800 km. This result provides ionospheric evidence of hot oxygen in the upper atmosphere of Venus.

Published

1992

19. Correction to 'Energetic oxygen ions of ionospheric origin observed in the cusp'

Author

Jiasheng Chen and Theodore A. Fritz

Subjects

Physics, Geophysics, Oxygen ions, General Earth and Planetary Sciences, Cusp (anatomy), Ionosphere, Atomic physics

Published

2001

20. Discovery of He2+and O2+ions of terrestrial origin in the outer magnetosphere

Author

Hans Balsiger, A. G. Ghielmetti, H. Rosenbauer, J. Geiss, P. Eberhardt, and D. T. Young

Subjects

Physics, Range (particle radiation), Plasma composition, Analytical chemistry, Magnetosphere, Geophysics, Earth radius, Ion, On board, Local time, Physics::Space Physics, Oxygen ions, General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics

Abstract

Using the Ion Composition Experiment (ICE) on board ESA'S GEOS satellite we have observed He2+ and O2+ ions of terrestrial origin in the outer magnetosphere predominantly in the energy range ∼ 1 - 100 eV. Data were obtained near the equatorial plane at geocentric distances of 3 to 7 earth radii in the local time sector 1500 - 2100 hours. During periods when doubly charged ions are observed typical abundances are O2+/O+ ∼ 30% and He2+/He+ ∼ 0.5% - 10%. The proportions of the major constituents H+, He+, and O+ are highly variable with He+ occasionally the dominant species at higher altitudes.

Published

1977

21. The OI 989-Å tropical nightglow

Author

Supriya Chakrabarti, Vincent J. Abreu, Stanley C. Solomon, J. H. Yee, and A. Dalgarno

Subjects

Physics, Atomic line, Geophysics, Spectrometer, Equator, Airglow, Oxygen ions, General Earth and Planetary Sciences, Satellite, Emission spectrum, Astrophysics, Atomic physics, Ultraviolet radiation

Abstract

Attention is given to the morphology and origin of the OI 989 A emission in the tropical nightglow. Dielectronic recombination of O(+) is suggested as the mechanism responsible for populating the 3s' 3D0 state of this 2p4 3P 3s' 3D0 emission. The spectrometer used is that aboard the STP 78-1 satellite, which is in sun-synchronous orbit. The emission morphology is characterized by tropical arcs on each side of the dip equator.

Published

1984