Stochastic Models of Hot Planetary and
Satellite Coronas
The uppermost layers of a planetary
(satellite) atmosphere where the density of neutral particles is infinitely low
are commonly called the exosphere or the planetary (satellite) corona. Since
the atmosphere is not completely bound to the planet (or satellite) by the
planetary gravitational field, such light atoms as hydrogen and helium in the
uppermost atmospheric layers can have velocities that exceed the escape
velocity from this planet and can escape into interplanetary space. This
process is commonly called thermal escape; the thermal escape flux depends on
the temperature of the ambient atmospheric gas, while the flux itself is formed
at heights where the flow of atmospheric gas is virtually collisionless
(Chamberlain and Hunten, 1987). These heights correspond to the transition
region between the underlying collision-dominated atmospheric layers and the
free-molecule exospheric gas. The concept of exobase, the lower boundary of the
exosphere, is introduced as a height at which the atmospheric particle mean
free path is equal to the density scale height (Chamberlain and Hunten, 1987).
For example, in the Earth’s upper atmosphere, the exobase is at a height of
about 500 km, and the exosphere here is populated mainly by atomic oxygen with
small admixtures of hydrogen and helium. The heavier carbon, nitrogen, and
oxygen atoms can escape from the atmospheres of the terrestrial planets only
through the collisional processes that determine such nonthermal escape
mechanisms as photodissociation, charge exchange and sputtering by
magnetospheric plasma, and ion capture by the solar wind (Chamberlain and
Hunten, 1987; Johnson, 1990; Hunten, 2002; Johnson, 2002).
The current theories of planetary
coronas are based mainly on ground-based and space observations of such
exospheric emission features as the 1026 A and 1216 A hydrogen lines, the 584 A
helium line, and the 1304 and 1356 A oxygen lines. These observations, together
with in-situ mass-spectrometer measurements, have allowed the density and
temperature height profiles of the exospheric components to be constructed.
These measurements have revealed that the planetary coronas contain both a
thermal fraction of neutral particles with the mean particle kinetic energy
corresponding to the exospheric temperature and a hot fraction of neutral
particles with the mean kinetic energy corresponding to a manifold higher
exospheric temperature ( Hunten, 2002; Johnson, 2002). The hot fraction is
produced by the nonthermal processes that form both the nonthermal escape
fluxes proper and the hot corona itself. These nonthermal collisional processes
are triggered under the external effects of solar extreme ultraviolet radiation
and magnetospheric plasma and are accompanied by intense energy exchange
between the various degrees of freedom of the atmospheric particles as well as
by a significant thermal effect of the photochemical reactions. A manifestation
of the non-equilibrium behavior of planetary and satellite atmospheres is the
formation of translationally excited (hot) particles with kinetic energies much
higher than thermal energy of the ambient atmospheric gas. These hot particles
are products of the photolytic and collisional dissociation and ionization of
the molecular atmospheric components as well as several exothermic chemical
reactions.
In recent years, interest in
investigating the role of suprathermal (energetically active) particles in the
physics and chemistry of the upper planetary and satellite atmospheres has
increased (Johnson, 1990; Wayne, 1991;
Shizgal and Arkos, 1996; Marov et al., 1997). In particular, the
energetically active particles produced in the upper atmospheric layers have
been shown to play an important role in the chemistry and energetics of the
upper atmosphere or, more specifically,
The following numerical approaches
are mainly used to simulate the nonthermal losses of planetary atmospheres in
practice (see, e.g., Shizgal and Arkos, 1996; Hunten, 2002):
—The stochastic simulation method
(Shematovich et al., 1994), which is a modification of the direct
statistical simulation Monte-Carlo method (Bird, 1976).
In general, the stochastic
simulation method consists in constructing a physical–probabilistic analogue of
discrete media with collisional physical–chemical processes and is used to simulate
chemically reacting multi-component gases (dsmc.html).
This approach has been further developed to investigate the formation,
kinetics, and transport of suprathermal particles for the linear and
nonlinear formation of hot planetary and satellite coronas (Shematovich
et al., 1994; Shematovich 2004).
The numerical stochastic models to
study both the local formation and kinetics of suprathermal particles and their
transport in the transition region between the collision-dominated and free
molecular layers of planetary and satellite atmospheres were developed for
different planets and satellites in our Solar System. Moreover, these numerical
models are suitable for investigating the flows of atmospheric gas being weakly
and strongly perturbed by suprathermal particles, i.e., for studying the
formation of hot planetary and satellite coronas in a proper way.
Bird, G.A. Molecular Gas Dynamics,
Chamberlain, J.W. and Hunten, D. Theory
of Planetary Atmospheres. An Introduction to Their Physics and Chemistry,
Ferziger, J. and Kaper, H. Mathematical
Theory of Transport Processes in Gases,
Hunten, D.M. Exospheres and
Planetary Escape, Atmospheres in the Solar System, Mendillo, M., Nagy,
A., and Waite, J.H., Eds.,
Ip, W.-H. On a Hot Oxygen
Johnson, R.E., Energetic Charged
Particle Interactions with Atmospheres and Surfaces,
Johnson, R.E. Surface Boundary Layer
Atmospheres, Atmospheres in the Solar System, Mendillo, M., Nagy, A.,
and Waite, J.H., Eds.,
Marov, M.Ya., Shematovich, V.I.,
Bisikalo, D.V., and Gerard, J.-C. Nonequilibrium Processes in the Planetary
and Cometary Atmospheres: Theory and Applications,
Nagy, A.F. and Cravens, T.E. Hot
Oxygen Atoms in the Upper Atmospheres of Venus and Mars, Geophys. Res. Lett.,
1988, vol. 15, pp. 433–435.
Shematovich, V.I., Bisikalo, D.V.,
and Gerard, J.-C. A Kinetic Model of the Formation of the Hot Oxygen Geocorona.
I. Quiet Geomagnetic Conditions, J. Geophys. Res., 1994b, vol. 99, pp.
217–226.
Shizgal, B.D. and Arkos, G.G.
Nonthermal Escape of the Atmospheres of Venus, Earth, and Mars, Rev.
Geophys., 1996, vol. 34, pp. 483–505.
Whipple, E.C., Van Zandt, T.E., and
Love, C.H. Kinetic Theory of Warm Atoms – Non-Maxwellian Velocity Distributions
and Resulting Doppler-Broadened Emission-Line Profiles, J. Chem. Phys.,
1975, vol. 62, pp. 3024–3030.
Hot hydrogen coronas:
EARTH:
- hydrogen emissions in the proton and electron auroras in the Earth's
upper atmosphere:
Ly-alpha emission in the proton aurora (abstract).
J.
Geophys. Res., 2000, 105, No. A7, 15795-15806.
The
role of proton precipitation in the excitation of auroral FUV emissions (abstract).
J.
Geophys. Res., 2001, 106, No. A10, 21475-21494.
Observation
of the proton aurora with IMAGE FUV imager and simultaneous ion flux in situ
measurements (abstract).
J.
Geophys. Res., 2001, 106, No. A12, 28939 -28948.
JUPITER:
- hot hydrogen sources, their distribution and auroral hydrogen emission
in Jupiter's thermosphere:
· Bisikalo, D.V., Shematovich, V.I.,
Gerard, J.-C.,
The distribution of hot
hydrogen atoms produced by electron and proton precipitation in the Jovian
aurora (
abstract),
J. Geophys. Res., 1996, 101, 21157.
Hot nitrogen coronas:
TITAN:
- kinetics and dynamics of hot nitrogen in the upper atmosphere:
Kinetic modeling of superthermal nitrogen
atoms in the Titan's atmosphere.I. Sources ( abstract).
Solar System Research (English
translation of "Astronomicheskij Vestnik"), 1998, 32, No.5 ,
384.
Kinetic modeling of superthermal
nitrogen atoms in the Titan's atmosphere. II. Escape flux due to dissociation
processes (abstract).
Solar System Research (English
translation of "Astonomicheskij Vestnik"), 1999, 33, No.1, 36.
Kinetic modeling of translationally
excited (hot) nitrogen atoms in the Titan's upper atmosphere.
In: Book of abstracts of International
Symposium NANTES98
"The Jovian system after Galileo.
The Saturnian system before Cassini-Huygens", 1998,
Suprathermal nitrogen atoms and molecules
in Titan's corona
(preprint).
Adv. Space Res., 2001, 27,
No.11, 1875-1880
Nitrogen
loss from Titan.
J. Geophys. Res., 2003, 108, No. E8, 5085.
Hot oxygen coronas:
EARTH:
- formation, kinetics and transport of "hot" oxygen atoms in
the exosphere and thermosphere:
A
kinetic model of the formation of the hot oxygen geocorona. I. Quiet
geomagnetic conditions(abstract).
J.
Geophys. Res., 1994, 99, 217.
The
importance of new chemical sources for the hot oxygen geocorona (abstract).
Geophys. Res. Lett., 1995, 22, 279.
A
kinetic model of the formation of the hot oxygen geocorona.II. Influence of O+
ion precipitation (abstract).
J.
Geophys. Res., 1995, 100, 3715.
Thermalization of O(1D) atoms in the thermosphere (abstract).
J.
Geophys. Res., 1999, 104, No. A3, 4287-4295.
The
role of hot oxygen on thermospheric OI UV airglow and density profiles (abstract).
J.
Geophys. Res., 1999, 104, No. A8, 17139-17143
Observation of anomalous temperatures in the daytime O(1D) 6300 A
thermospheric emission:
a
possible signiture of nonthermal atoms (abstract).
J.
Geophys. Res., 2001, 106, No. A7, 12753-12764.
EUROPA:
- near-surface oxygen atmosphere:
Possible mechanism of the oxygen-bearing
atmosphere formation on the Jovian icy satellites ( abstract).
Solar System Research (English
translation of "Astronomicheskij Vestnik"), 2000,34, No.1, 12.
Near-surface oxygen atmosphere at Europa ( preprint).
Adv. Space Res., 2001, 27,
No.11, 1881-1888