Physics of the Solar Corona

Physics of the Solar Corona

other process is needed to close the chain Fig. 2 — A possible sequence of processes related to the origin of the solar cycle and allow for self-excitation. It is tempting Region Physical Description Processes Related to Magnetic Field and to assume a certain flow pattern that twists Activity Cycle the toroidal field in such a way that the net effect is a meridional component of the Interface Zone Transition between ω(core) and Generation of toroidal field by differential rota­ ω(envelope)· Shear zone with pos- tion. Field is kept down by topological pump­ field. This leads to the formulation of the sible turbulence driven by instabi­ ing until it has grown strong enough to escape kinematical dynamo problem: Can we find lities due to differential rotation. owing to buoyancy and magnetic instabilities ; a velocity field v(x, t) in such a way, that formation of flux tubes. Helical flows produced the electrical field vxB/c drives a current j in that phase regenerate the poloidal field. which amplifies the magnetic field B? Convection Zone Nearly adiabatically stratified re­ Flux tubes are transported, shredded and refor­ In 1955, E.N. Parker presented a concep­ gion. Energy is transported almost med by convection and buoyancy. Small frag­ tual picture of a possible dynamo process entirely by convection. The veloci­ ments can be carried around by convection and based on the influence of rotation on con­ ty field may consist of large-scale appear later as small active regions randomly vective motions due to the Coriolis force. eddies as well as small-scale tur­ distributed over the surface. F. Krause, K.H. Rädler and M. Steenbeck bulence. gave a more firm basis to it in the frame- Uppermost Transition between energy trans­ Flux tubes suffer from local instabilities leading work of the electrodynamics of mean Convection Zone port by convection and radiation. to loop formation, break through the photo­ and Photosphere Stratification is slightly super- sphere and build active regions. Adiabatic fields. It has become clear since then that adiabatic in the upper convection downflow along the loops cools relative to the the correlation between velocity and vor- zone and sub-adiabatic in the pho­ superadiabatic exterior and leads to an even ticity, called "helicity", is the key tosphere. Velocity field consists of stronger concentration of fields. Sunspots ap­ parameter determining the possibility of supergranulation (scale ~ l04 km), pear and are eventually disrupted by velocity granulation ( ~ 103 km) and small- fields. dynamo action of a flow. Helicity can be scale turbulence. understood as a "rest of order" in an other­ wise chaotic flow. Helical flows such as turbulent convection under the influence of logical pumping until it has grown strong REFERENCES enough to escape by means of magnetic a Coriolis force are able to sustain a The interested reader Is referred to : dynamo and build possible candidates for buoyancy or a related instability. Helical 1. Krause F. and Rädler K.H., Mean-Field Ma­ the "missing link" of the solar cycle, pro­ flows produced in that phase by the in­ gnetohydrodynamics and Dynamo Theory, (Per­ ducing meridional field out of toroidal field. fluence of the Coriolis force on the velocity gamon Press, Oxford), 1980. Furthermore, turbulent flows in some field possibly close the dynamo chain and 2. Moffatt H.K., Magnetic Field Generation in cases are shown to enhance the diffusion regenerate the meridional field. After the Electrically Conducting Fluids, (Cambridge Uni­ and dissipation of a mean magnetic field field has left the amplification region, it is versity Press, Cambridge) 1978. through the formation of structures with lifted upwards by the combined effects of 3. Parker E.N., Cosmical Magnetic Fields, (Cla­ small typical length scale, leading to a convection and buoyancy in the form of rendon Press, Oxford) 1979. 4. Stix M., "Theory of the Solar Cycle", Solar reduction of the effective electrical conduc­ concentrated flux tubes which break Physics 74 (1981) 79-101. tivity for the mean field. through the surface eventually and build 5. Piddington J.H., "Solar Magnetic Fields and The observed fact that stellar activity in­ active regions of all sizes. In the meantime, Convection. VII. A Review of the Primordial creases with the rate of rotation lends some differential rotation is already producing Field Theory", Eds. V. Bumba and J. Kleczek, support to the idea of turbulent dynamo the toroidal field for the next half cycle Proc. IAU — Symp. 71 Basic Mechanics of action because the efficiency of the pro­ from the regenerated poloidal field. Solar Activity, (Dordrecht) 1976, p.389. cess increases with angular velocity as well. Model calculations incorporating the combined effects of differential rotation and helical flows display cyclic behaviour Physics of the Solar Corona and can reproduce the basic features of the evolution of the large scale magnetic fields Claudio Chiuderi, Florence during the cycle: reversal of the polar (Istituto di Astronomia, Università di Firenze) fields, migration of the activity belt towards the equator and polarity rules. The solar corona is the outermost part of as well as in the X-ray region. The ter­ the atmosphere of the Sun, a tenous, hot restrial atmosphere is transparent to radio Tentative Conjecture plasma extending outwards from slightly waves and opaque to X-rays, so that while In view of all the uncertainties mentioned above the visible limb to well beyond the coronal observations at radio frequencies in the introduction, a coherent theory of Earth's orbit. The denser part of this can be made routinely, X-ray observations the physics of the solar cycle has not been plasma, close to the Sun's surface, forms can be only performed from space, and our given until now. But in order not to leave the corona proper, only visible during total information is necessarily more fragmented the reader alone with a bundle of concepts solar eclipses or by means of special instru­ in time. we give a conjecture (see Fig. 2) of how the ments, the coronagraphs, at least at optical The corona is in a state of continual ex­ solar cycle could operate, a picture pre­ wavelength. Typical values of the physical pansion, the consequent outflow of matter sently shared by at least a fraction of active corona parameters are a temperature of the constituting the solar wind, with an workers in the field. order of 1-2 x 106 K, with occasional localiz­ average flux of 3 x 10-16 g cm-2S-1, which Consider the transition region between ed Increases up to a few times 107 K, and a corresponds to a total mass loss of ~ 10-14 the solar core and the convective zone at a number density in the range 108 - 1010 cm-3. solar masses per year. The properties of the depth of ~ 200000 km from the surface. Because of the difficulty of observing solar wind have been studied in situ by ar­ The observations of solar oscillations indi­ optically the solar corona, a rapid develop­ tificial satellites from about 0.3 AU to 1 AU cate that this zone is also a shear region ment did not take place until observations (1 AU ~ 150 Mkm). between the slowly rotating convection at different wavelengths made this part of There are many reasons for our interest zone and the much faster rotating solar the atmosphere more accessible. From the in coronal studies : the Sun is the only star core. This differential rotation produces a typical values quoted above, it is clear that in our vicinity, and the solar corona can be toroidal field, which is kept down by topo- the corona will emit at radio wavelengths considered a giant plasma laboratory, 8 tion of the solar plasma. Q includes both propagated upwards and must be deposi­ the contribution of the continuum and that ted in the appropriate amount in the cor­ of the lines coming from partially ionized ona. There are many possible schemes that elements like C, Ο, N, Ne, Mg, Fe etc. The fulfill the above conditions. For instance, point of interest here is that φ ( T) is a acoustic noise can be generated by the tur­ decreasing function of the temperature in bulent motions known to exist in the sub- the range 105 K ≤ T ≤ 107 K. Thus a photospheric layers, the energy from which plasma with a temperature in this interval would be carried outwards by waves. In will react to a cooling perturbation by in­ principle, in a compressible atmosphere creasing its radiative output, which in turn embedded in a gravitational field, there are will decrease the temperature still further. two fundamental wave modes, the acous­ In other words, a homogeneous plasma tic mode and the internal gravity mode, ac­ cording to the nature of the restoring force, A spectacular example of solar corona loops. would be unstable to thermal instabilities : direct computations show that the final compressibility and buoyancy respectively. where experiments are continuously being equilibrium will be one with a thin transition The acoustic mode seems to be the most performed under conditions that are ure- layer separating a high temperature region likely candidate. These sound waves pro­ producible in terrestrial laboratories. from a low temperature one, as found in pagate in a medium of decreasing density Although very hot plasmas are currently the coronal structure. and eventually steepen into shocks, depo­ produced on Earth, their spatial and tem­ As the behaviour is quite insensitive to siting a fraction of their energy through the poral scales are so vastly different from changes in the heating mechanism that is dissipative processes operating in the those encountered in space, extrapolation assumed to be operating in the upper at­ shock front.

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