User:Ennasus.k/Ionospheric dynamo region

This is not a Wikipedia article: It is an individual user's work-in-progress page, and may be incomplete and/or unreliable. For guidance on developing this draft, see Wikipedia:So you made a userspace draft.  Find sources: Google (books · news · scholar · free images · WP refs) · FENS · JSTOR · TWL Easy tools: Citation bot (help) | Advanced: Fix bare URLs This page was last edited by Citation bot (talk | contribs) 3 years ago. (Update timer) Finished writing a draft article? Are you ready to request an experienced editor review it for possible inclusion in Wikipedia?     Submit your draft for review!

ionospheric dynamo region ...

Ionospheric dynamo region

Introduction

In the height region between about 85 and 200 km altitude, the ionospheric plasma is electrically conducting. Atmospheric tidal winds due to differential solar heating or due to gravitational lunar forcing move the ionospheric plasma against the geomagnetic field lines thus generating electric fields and currents just like a dynamo coil moving against magnetic field lines. The magnetic manifestation of these electric currents on the ground can be observed during magnetospheric quiet conditions. They are called Sq-variations (S=solar; q=quiet) and L-variations (L=lunar) of the geomagnetic field ^[1].

Additional electric currents are generated by the varying magnetospheric electric convection field. These are the DP1-currents (the auroral electrojets) and the polar DP2-currents. Finally, a polar cap field has been observed which depends on the polarity of the interplanetary magnetic field ^[2]. These varying geomagnetic variations belong to the so-called external part of the geomagnetic field. Their amplidudes reach at most about 1 % of the main internal geomagnetic field B_o.

Atmospheric electric conductivity

Radioactive material from the ground and galactic cosmic rays ionize a small fraction of the atmospheric gas within the lower and middle atmosphere and make the gas electrically conducting. Electrons quickly attach to neutral particles forming negative ions. The positive ions are mostly singly charged. The electric conductivity depends on the mobility of the ions . That mobility is proportional to the reciprocal air density. Thus, the electric conductivity increases almost exponentially with altidude. The ions move with the neutral gas thus making the conductivity isotropic ^[3].

At heights between about 85 and 200 km however -the dynamo region-, solar X- and extreme ultraviolet radiation (XUV) is almost completely absorbed generating the ionospheric D-, E-, and F-layers. Here, the electrons are already bounded to the geomagnetic field gyrating several times around these lines before they collide with the neutrals, while the positive ions still essentially move with the neutral gas. Thus, the electric conductivity becomes anisotropic. The conductivity parallel to an electric field E is called Pedersen conducticity. The conductivity orthogonal to E and the geomagnetic field B_o is the Hall conductivity. Ohmic losses and thus Joule heating occur when these currents flow. The component parallel to B_o still increases with altitude. Near the dip equator, a west-east directed electric field generates vertical Hall currents which cannot close. Therefore, a vertical polarization field builts up generating a horizontal Hall current which adds to the Petersen current. Such enhancement is described by the Cowling conductivity. Pedersen and Hall conductivities reach maximum values near 120 to 140 km with numbers of about 1 mS/m during sunlit conditions. During the night, these numbers may decrease by a facor of ten or more. The values of these conductivities depend on local time, latitude, season and solar 11- year cycle. The height integrated conductivities become of the order of 50 S, or a total resistance of the dynamo region of about 1/50 = 0.02 Ohm.

In the auroral regions which lie between about 15° and 20° geomagnetic co-latitude and the corresponding latitudes in the southern hemisphere , precipitating high energy particles from the magnetosphere ionize the neutral gas, in particular at heights around 110 and 120 km, and increase the electric conductivity substancially. During magnetospheric disturbed conditions, this conductivity enhancement becomes even larger, and the auroral regions move equatorward.

At heights above about 200 km, collisions between neutrals and plasma become rare so that both ions and electrons can only gyrate around the geomagnetic lines of force, or drift orthogonal to E and B. The parallel conductivity is so large that the geomagnetic lines of force become electric potential lines, and only electric fields orthogonal to B_o can exist (see magnetosphere).

Atmospheric Tides

Atmospheric tides are global-scale waves excited by regular solar differential heating (thermal tides)or by the gravitational tidal force of the moon (gravitational tides). The atmosphere behaves like a huge waveguide closed at the bottom (the Earth's surface) and open to space at the top. In such a waveguide an infinite number of atmospheric wave modes can be excited. Because the waveguide is imperfect, however, only modes of lowest degree with large horizontal and vertical scales can develope sufficiently well so that they can be filtered out from the meteorological noise. They are solutions of the Laplace equation ^[4] and are called Hough functions. These can be approximated by a sum of spherical harmonics.

Two kinds of wave modes exit: class 1 waves (sometimes called gravity waves), and class 2 waves (rotational waves). Class 2 waves owe their existence to the Coriolis force and can only exist for periods larger than 12 hours. Class 2 waves can be either internal (travelling waves ) with positive eigenvalues (or equivalent depth) which have finite vertical wavelengths and can transport wave energy upward, or external (evanescent waves) with negative eigenvalues and infinitely large vertical wavelengths meaning that their phases remain constant with altitude. These external wave modes cannot transport wave energy, and their amplitudes decrease exponentially with height outside their source regions. Each mode is characterized by four numbers: the zonal wave number m, a meridional wave number n positive for class 1 waves and negative for class 2 waves (their meridional structures becoming increasingly complex with increasing number n), the eigenvalue, and the period, in our case one solar or lunar day, respectively. The modes are labeled as (m, n). Even numbers of n correspond to wave symmetric with respect to the equator, and odd numbers corresponding to antisymmetric waves.

At thermospheric heights, dissipation of atmospheric waves becomes significant so that at above about 150 km altitude, all wave modes gradually become external waves, and the Hough functions degenerate to spherical functions (e.g., mode (1, -2) develops to the spherical function P₁¹(θ), mode (2, 2) becomes P₂²(θ), with θ the co-latitude, etc.). ^[5].

Migrating Solar Tides

The fundamental solar diurnal tidal mode which optimally matches the solar heat input configuration and thus is most strongly excited is the (1, -2) - mode. It depends on local time and travels westward with the Sun. It is an external mode of class 2. Its maximum pressure amplidude on the ground is about 60 hPa ^[6]. Within the thermosphere, however, it becomes the predominant mode reaching temperature amplitudes at the exosphere of at least 140 K and horizontal winds of the order of 100 m/s and more increasing with geomagnetic activity ^[7]. The largest solar semidiurnal wave is mode (2, 2) with maximum pressure amplitudes near the ground of 120 hPa. It is an internal class 1 wave. Its amplitude increases with altitude. Although its solar excitation is half of that of mode (1, -2), its amplitude is larger by a factor of two. This indicates the effect of suppression of external waves, in this case by a factor of four.

Semidiurnal lunar tides

The dominant migrating lunar tide is the (2, 2) mode depending on lunar local time. Its maximum pressure amplitude near the ground is 6 Pa, which is far below the meteorological noise. Therefore, it is not simple to detect such small signal^[6] . Because it is an internal waves, its amplitude increases with altitude reaching values at 100 km height two orders of magnitude larger than on the ground.

ElectricCurrents

Sq-current

Morphology

More than 100 geomagnetic observatories around the world measure regularly the variations of the earth's magnetic field. The daily variations during selected days of quiet geomagnetic activity are used to determine a monthly mean. The average of such variations depending on local time at various latitudes is presented in Figure 1. From the horizontal component ΔH of such data , one can derive a corresponding overhead equivalent electric current system at dynamo layer heights of strength J = 2 ΔH/μ = 1.6 ΔH with J (in milliAmpere/meter) the electric overhead sheet current, ΔH (in nanoTesla) the observed horizontal component of the geomagnetic variation, and μ the permeability of free space.^[1]. One has to take into account, however, that this relationship is not unique In general, electric currrents within ionosphere and magnetosphere are three dimensional, and an infinite number of current configurations fits to the geomagnetic variations observed on the ground ^[8]. Magnetic measurement in space are necessary to obtain a realistic picture.

east (ΔY), and vertical (ΔZ; positive downward) versus local time at various latitudes]]

Figure 2a shows current streamlines of an equivalent Sq current as seen from the sun at noon. This current configuration is fixed to the sun, while the earth rotates beneath it. A total current of about 140 kA flows within one daytime vortex. The rotating Sq current and the electrically conducting earth interior behave like a huge transformer with the dynamo region as the primary winding and the earth as the secondary winding. Since the Sq current varies with the basic period of one day, electric currents are induced within the earth's interior. The magnetic field of this secondary current is superimposed on the magnetic field of the primary Sq current. Methodes to separate both components go back to Gauss. The amplitude of the secondary current is about 1/3 of that of the primary current and slightly shifted in phase. Figure 1b shows that secondary component. The ratio between sheet current and magnetic component has now simply the value one.

.

The Sq current depends on season. The summer vortex is intensified compared with the winter vortex and reaches into the winter hemisphere. A longitudinal dependence of the Sq current exists which is related to the inclined dipole component of the internal magnetic field, but probably also to nonmigrating tidal waves from below ^[10]. In the course of the 11-year solar cycle, the amplitude of Sq increases by a factor of more than two from sunspot minimum to sunspot maximum. Two thirds of this increase may result from the enhancement of the electric conductivity with solar activity. The rest is probably due to the increase of the wind speed caused by the temperature increase with increasing solar activity. During the night, the electron density of the ionospheric E-layer diminishes much more strongly than that of the F-layer. Therefore, the height center of the dynamo region shifts upward ^[11].

Near the dip equator (where the geomagnetic field lines are horizontal), a strong band of eastward flowing currents can be observed in a range of about 150 km from the equator . Such enhancement of the Sq current by a factor of about four is due to the Cowling conductivity. The centers of the daytime vortices show a day to day variability. This can be attributed to the internal tidal modes which are sensitive to the varying meteorological conditions in the lower and in the middle atmosphere, in part also to solar activity. The main driver of the Sq current is the external (1, -2) tidal wave mode. Due to its constant phase with altitude, is is most efficient to drive coherent winds at dynamo layer height ^[12], while the currents generated by the internal modes interfere destructively at various heights ^[13].

A Fourier analysis shows a semidiurnal component with an amplitude of 1 /2 of that of the diurnal component, phase shifted by 180^o. This appears to be the result of nonlinear coupling between the product of the diurnally varying wind and the diurnally varying conductivity ^[5].

During a solar flare, bursts of solar radiation from the environment of an active sunspot reach the higher atmosphere, mainly at E- and D- layer heights, lasting at most for one hour. The electric conductivity increases, and the Sq current enhances on the day time hemisphere. A small increase (crochet) occurs, called geomagnetic solar flare effect ^[14]. During a solar eclipse, the electric conductivity decreases in the shadow region, and the Sq current and thus the Sq variation diminishes by a few nT ^[15]. It is called a geomagnetic solar eclipse effect. Both effects can be observed only during quiet geomagnetic activity.

In the aftermate of strong magnetospheric disturbances, a current system develops into a quasi anti-Sq-current. It is generated by Joule heating in the polar thermosphere ^{[16] [17]}. This current system is called Ddyn.

Theory

In order to determine quantitatively the dynamo action of the neutral wind U, one starts with the horizontal momentum equation of the wind together with an equation for the divergence of the wind. The momentum equation balances the inertial force, the Coriolis force, and the horizontal pressure p. In addition, the Ampere force force Jx B_o couples the electric current density j to the wind and pressure system. The equivalent depth h (the eigenvalue of the tidal mode) determines the divergence of the wind. The electric current must obey Ohm's law. An electric polarization field E is generated by charge separation to enforce the condition of no sources and sinks of the current. Feedback between wind and electric current occurs via the Lorentz force Ux B. Usually, tThe electric conductivity tensor σ is considered as a given data set, and a height integrated conductivity tensor Σ and a height integrated sheet current J are applied Electrodynamics (^[18].

In convential models, the Ampere force is neglected. This means that gate B in Figure 3 is open. This is called a kinematic dynamo. Such models overestimate the effect of the winds. Models with closed gate B are called hydromagnetic dynamos. The influence of the mutual coupling between wind and current can immediately be seen if one considers an infinitely large electric conductivity σ. In the kinematic model, the electric currents would become infinitely large. In the hydromagnetic model, the current would reaches an upper limit, similar to a technical dynamo. During a short circuit, the wind amplitude breaks down to a fraction of its original value, while the electric current is still finite. Charge separation acts like a self-impedance preventing the current to become infinitely large ^[5].

L-current

Lunar (L) currents are weaker by a factor of about 20 than the Sq currents. The dominant wind component to drive these currents is the (2, 2) tidal mode. The L current is similar in shape as the Sq current, with the difference that four vortices instead of two exit. In each vortex a total current of about 4 kA flows. The seasonal variation of L is similar to that of Sq. During sunlit hours, L is strongly enhanced, while it approaches zero during the night. The L current exhibits, in addition, a solar modulation depending on the lunar phase ^[1].

DP1-current

Interaction between solar wind plama and the polar geomagnetic field produces a global-scale magnetospheric electric convection field directed from dawn to dusk with a potential difference of about 15 kV during quiet magnetospheric conditions, increading substantially during disturbed conditions (see magnetosphere). Charge separation takes place at the magnetopause. This area is connected with the ionospheric dynamo layer via the first open geomagnetic field lines with footpoints within the auroral regions. Thus, electric discharging currents can flow via field-aligned currents as two small bands within the auroral zone dynamo layer, on the day time as well as on the night time hemisphere. These currents are called DP1 current or auroral electrojets. Their magnitudes are of the order of Mega Amperes. Ohmic losses and thus Joule heating of these currents is comparable with that due tothe solar XUV heat input within middle and lower latitudes during quiet conditions and much larger during disturbed conditions. Therefore, it dominates ionospheric and thermospheric dynamics and causes ionospheric and thermospheric storms ^[19].

DP2-current

The magnetospheric electric convection field drives a two cell current with their vortices situated on the morning and on the evening side. It is called DP2 current. That current exists already during quiet conditions (S_q^p) and becomes enhances during disturbed conditions. It is mainly composed of electric Hall currents ^{[1] [20]}.

Polar Cap Current

If the azimuthal component of the interplanetary magnetic field (IMF) is directed toward dusk, the magnetospheric plasma is slowed down in the northern polar cup and accelerated in the southern polar cap. If the azimuthal component of the IMF is directed toward dawn, the situation is reversed. This devitation from co-rotation disappears at lower latitudes. The magnetic effect on the ground within the polar regions corresponds to a ionospheric Hall current at about 10^{o polar distance encircling the magnetic poles in a clockwise direction as seen by an observer standing on the ground during interplanetatry sectors with fields pointing away from the sun, and in a counterclockwise direction during toward-sector polarity [21].}

References

1. Chapman , S.J. and J. Bartels, „Geomagnetism“ , Clarendon Press, 1951
2. Heppner, J.P., in Dyer, E.R. (ed), "Critical Problems of Magnetospheric Physics", Nat. Acad. Sci.,Washington, D.C., p. 107. 1972
3. Viggiano, A.A., and F. Arnold, in Volland, H. (ed), "Handbook of Atmospheric Electrodynamics", Vol. 1, p. 1, CRC Press, Boca Raton, FL, 1995
4. Longuet-Higgins, M.S., "The eigenfunctions of Laplace's tidal equations over a sphere", Phil. Trans. Roy. Soc.", London, A262, p. 511, 1968
5. Volland, H., "Atmospheric Tidal and Planetary Waves", Kluwer Publ., Dordrecht, 1988 Cite error: The named reference "VollandAE" was defined multiple times with different content (see the help page).
6. Chapman, S., and R.S. Lindzen, "Atmospheric Tides", Kluwer Dordrecht, 1970
7. Kohl, H. and J.W. King, J. Atm. Terr. Phys., 29,1045, 1967
8. Fukushima, N., Radio Sci., 6, 269, 1971
9. Malin, S.R.C., Phil Trans. R. Soc., London, Ser. A 274, 551,1973
10. Forbes, J.M., at all., J. Geophys. Res., Space Physics, 113, 17, 2008
11. Matsushita, S., and W.H. Campell, W.H. (eds.), "Physics of Geomagnetic Phenomena", Vol. I and II, Academic Press, New York,1967
12. Kato, S., J. Geophys. Res., 71, 3211, 1966
13. Forbes, J.M., J. Geophys.Res. 87, 5222, 1988
14. Richmond, A.DF., and S.V. Venkatesmaran, J. Geophys. Res., 81, 139,1971
15. Wagner, C.U., J. Atm. Terr. Phys., 25,529,1963
16. Blanc, M., and A.D. Richmond, J. Geophys. Res., 85, 1669, 1980
17. Zaka, K,.Z., et all., Ann. Geophys., 27, 3523, 2009
18. Richmond, A.D., Geomagn. and Geoelectr. 31, 287,1979
19. Proelss, G.W., in Volland, H. (ed), "Atmospheric Electrodynamics, Vol. II, p.195, CRC Press, Boca Raton, FL, 1995
20. Nishida, A., and S. Kokubun, Rev. Geophys. Space Sci., 9, 417,1971
21. Svalgaard, L., J. Geophys. Res., 80, 2311, 1975

Further Reading

• M.C. Kelly (2009). The Earth' Ionosphere: Plasma Physics and Electrodynamics. Akademic press, New York.
• G. Proelss and M.K. Bird (2010). Physics of the Earth's Space Environment: An Introduction. Springer, Berlin.
• A. Brekke (2013). Physics of the Upper Polar Atmosphere. Springer, Berlin.

Category:Earth's Magnetic Field Category:Ionosphere Category:Magnetosphere Category:Atmospheric Electricity Category:Volland-Stern Model