Acoustic waves (case k  = 0 ) -- Important for non-magnetized regions in the low solar atmosphere: Eqs. (10),(6)  = (12) Fig. 3: Defined by Eq(12) variation.

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Acoustic waves (case k  = 0 ) -- Important for non-magnetized regions in the low solar atmosphere: Eqs. (10),(6)  = (12) Fig. 3: Defined by Eq(12) variation of with height in the solar chromosphere (Ver nazza et al.1981). B. MHD wave damping in Prominences Prominence material is an important example of the solar partially ionized plasmas: T=(6...10)  10 3 K; n=(1...50)  cm -3 ; n n /n = , B 0 ~10 G. Eqs. (11), (12) can be used for calculation of the Alfvén, fast magnetoacoustic and acoustic waves collisional and viscous damping time ratios. Fig.4: Typical values of the collisional and viscous damping time ratios for  pro-pagating a) Alfvén and fast magnetoacoustic waves and b) acoustic wave calculated from Eqs.(11),(12) for the prominence plasma with B 0 =10 G and n n /n = 1. Of interest for prominences is also the transverse (k  =0 ) propagation of MHD waves with respect to the background magnetic field. Eqs. (4),(6),(9),(10)  (13) (14) Fig.5: Typical values of the collisional and viscous damping time ratios for  pro-pagating a) fast magnetoacoustic and b) acoustic wave calculated from Eqs. (13), (14) for the prominence plasma with B 0 =10 G and n n /n = 1. Conclusion Collisional damping of MHD waves in the partially ionized plasmas of the low solar atmosphere and prominences is always stronger than their viscous damping. For a self-consistent description of MHD wave collisional and viscous damping in the partially ionized plasmas, besides of inclusion of appropriate terms into momentum and energy equations, the kinetic pressures p k, k=i,e,n in the generalized Ohm’s lawshould be replaced by generalized pressures,, k=i,e,n containing the viscous stress tensors. The expressions used here are valid only if damping decrements d << 1 (linear approximation). Therefore our analysis is correct only for waves with f = (w/2p) << f c. Depending on plasma parameters, dissipation mechanism and particular MHD mode, the critical frequency f c varies from ~ 0.1 Hz till Hz. For more details see Khodachenko et al., The damping time of a wave measured in wave periods, can be ex- pressed as. References Braginskii, S.I., Transport processes in a plasma, in: Reviews of plasma physics, Vol.1, Consultants Bureau, New York, DePontieu, B., Haerendel, G., A&A, 338, 729, Khodachenko, M.L., Arber, T.D., Rucker, H.O., Hanslmeier, A., Collisional and viscous damping of MHD waves in partially ionized plasmas of the solar atmosphere, A&A, (submitted) Nakariakov, V.M., Verwichte, E., Berghmans, D., Robbrecht, E., A&A, 362, 1151, Ofman, L., ApJ, 568, L135, Piddington, J.H., MNRAS, 116, 314, Vernazza, J.E., Avrett, E.H., Loeser, R., ApJ Suppl, 45, 635, Abstract A comparative study of the efficiency of MHD wave damping in solar plasmas due to collisional and viscous energy dissipation mechanisms is presented here. The damping rates are taken from Braginskii (1965) and applied to the VAL C model of the quiet Sun (Vernazza et al., 1981). These estimations show which of the mechanisms are dominant in which regions. In general the correct description of MHD wave damping requires the consideration of all energy dissipation mechanisms via the inclusion of the appropriate terms in the generalized Ohm's law, the momentum, energy and induction equations. Specific forms of the generalized Ohm's Law and induction equation are presented that are suitable for regions of the solar atmosphere which are partially ionised. Introduction Magnetohydrodynamic (MHD) waves are widely considered as a possible source of heating for various parts of the outer solar atmosphere. The heating effect of MHD waves is connected with a certain dissipation mechanism which converts the energy of damped MHD waves into the energy of the background plasma. Among the main energy dissipation mechanisms which play an important role under the solar conditions, are collisional dissipation (resistivity) and viscosity. The presence of neutral atoms in the partially ionized plasmas of the solar photosphere, chromosphere and prominences enhances the efficiency of both these energy dissipation mechanisms. In previous publications collisional and viscous damping of MHD waves in partially ionized solar plasmas has been always considered separately. One group of researchers assumes the friction between ions and the neutral fraction is the dominant dissipation mechanism (Piddington, 1956; DePontieu & Haerendel, 1998). Another group of authors takes into account only the viscosity effects (Nakariakov et al., 2000; Ofman, 2002). Because of different physical nature of the above two mechanisms of MHD wave dissipation, in each particular case a certain reasoning is needed why one of the mechanisms is neglected and other is not. In the general case, the correct description of MHD wave damping requires the consideration of both dissipation mecha-nisms via the inclusion of the appropriate terms in the generalized Ohm's Law, as well the momentum and energy equations. While the frictional dissipation (electrical resistivity) can usually be safely neglected as compared to viscosity effects in the fully ionized solar corona, the relation and mutual role of both these dissipation mechanisms for the damping of different types of MHD waves in the lower (partially ionized) solar atmosphere requires a special comparative study. Here we give some elementary estimations of the frictional and viscous damping of MHD waves which are needed to conclude on which of two dissipation mechanisms is dominant in different regions of the solar atmosphere. MHD waves damping in the linear approximation In this section we summarize the results from Braginskii (1965) on the linear damping rates of MHD waves, obtained from the calculation of the energy decay time using the local heating rates Q frict, Q visc, etc. These results are applied in later sections. The decay of wave amplitude is described by the complex frequency w - i w d so that the energy in a particular wave mode will decay as e - t/t, where t = (2wd) - 1 is a characteristic wave damping time and d (<< 1) is the logarithmic damping decrement. A. The case of fully ionized plasma Alfvén wave (A.w.) : (1) (2) Fast magnetoacoustic (or magnetosonic) wave (f.ms.w.) : (3) (4) Acoustic (or sound) wave (s.w.) : (5) (6) Since in the fully ionized plasma, we use no- tation d Joule in place of d frict. s  and s  are components of electr.conductivity relative the magnetic field and  0,  1,  2 are viscosity coefficients. B. The case of partially ionized plasma In the partially ionized plasma the expression for the frictional heating besides of the Joule heating contains and extra term arising due to the plasma - neutral gas collisional friction (Braginskii, 1965): (7) where,. Here and are relative densities, and, k = e,i ; l = i,n are effective collisional frequencies. For an Alfvén wave G=0, while for a fast magnetoacoustic wave G is small as compared to the first term in brackets in (7). Thus the fricti-onal heating term for these modes in the partially ionized plasma has a form of the Joule heating:, where is well known Cowling conductivity. In a strong enough magnetic field s >> s C. Thus, the expressions (1) and (3) can be re-written for the damping decrements in a partially ionized plasma as the following: Alfvén wave (A.w.) : (8) Fast magnetoacoustic (or magnetosonic) wave (f.ms.w.) : (9) For Acoustic wave (s.w.) both terms in brackets in (7) are important, and the frictional damping decrement in the case m i = m n is (10) Note that throughout this poster variables with a tilde relate to partial-ly ionized plasmas. Application to the Sun From (1), (3) and (8), (9) follows that parallel propagating ( k  = 0 ) Alfven and fast magnetoacoustic waves are equally damped due to col-lisional (Joule) dissipation. But because of s >> s C ( see Fig. 1 ) this damping is much higher in the partially ionized plasma. Parallel propagating acoustic waves are not damped due to friction in a fully ionized corona (5), but are damped in partially ionized solar photo- spheric, chromospheric and prominence plasmas (10). Viscous damping of MHD waves ((2), (4), (6)) in different parts of the solar atmosphere is defined by chang- ing with height plasma densi ty and viscosity coefficients. Fig.1: Variation of s/s C with height for the quiet Sun model (Vernazza et al. 1981) for different B 0 : 1) 10 G; 2) 100 G; 3) 1000 G. A. MHD wave damping in Photosphere/Chromosphere Alfvén & Fast magnetoacoustic waves (case k  = 0 ): Eqs. (2),(4),(8),(9)  (11) Weakly ionized photosphere (, ): Eq. (11) gives, where, Fig.2: Variation of with height in the low solar atmosphere (Vernazza et al. 1981) for different B 0 : 1) 5G; 2) 10G; 3) 100G; 4) 1000G. Collisional and viscous damping of MHD waves in partially ionized plasmas of the solar atmosphere M. L. Khodachenko 1, T. D. Arber 2 and H. O. Rucker 1 (1) Space Research Institute, Austrian Academy of Sciences, Schmiedlstr.6, A-8042 Graz, Austria (2) Dept. of Physics, University of Warwick, Coventry, CV4 7AL, United Kingdom