Space Physics and Aeronomy, Ionosphere Dynamics and Applications. Группа авторов

Space Physics and Aeronomy, Ionosphere Dynamics and Applications - Группа авторов


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is driven by dayside reconnection, followed by a sharp excursion in AL associated with the formation of the current wedge. Variations in FPC allow estimation of ΦD and ΦN using equation (2.15), from which ΦPC can be inferred using equation (2.16). Such observations show that the substorm expansion phase typically lasts 1 hour, with ΦN ≈ 75 kV, closing approximately 0.3 GWb of flux, equivalent to approximately half the preexisting polar cap flux (Milan et al., 2007). There is ambiguity in such measurements as changes in FPC are related to the difference between ΦD and ΦN, not their absolute values. In this case, estimating ΦD from solar wind observations (e.g., Milan et al., 2012) removes this ambiguity. If convection measurements are available as well as observations of the polar cap boundary, then ΦD and ΦN can be measured independently from the rate of plasma flow across the dayside and nightside OCB (e.g., Baker et al., 1997; Grocott et al., 2002; Hubert et al., 2006, 2017; Chisham et al., 2008). Alternatively, observations of FPC, ΦD, and ΦN can be used to drive a model of convection to compare with measured flow velocities (e.g., Walach et al., 2017).

Schematic illustrations of three examples of observations of the expanding/contracting polar cap from global auroral imaging.

      (from Milan et al., 2007; Reproduced with permission of John Wiley and Sons).

      If the IMF remains southward for a prolonged period, the magnetosphere sometimes undergoes steady magnetospheric convection (e.g., Sergeev, 1977; Sergeev et al., 1996; McWilliams et al., 2008). During such events, ΦN ≈ ΦD so these are also known as “balanced reconnection intervals” (DeJong et al., 2008), and the polar cap remains of uniform size. Kissinger et al. (2012) and Walach and Milan (2015) showed that many such events begin as a substorm, but segue into SMC if the IMF does not shortly thereafter turn northward. Milan et al. (2018b) have suggested that during prolonged BZ < 0, SMC can be achieved if the initiating substorm is a high‐latitude onset and convection is unimpeded, but that a sequence of substorms is initiated if the onsets are low latitude and conductance arrests the flow such that a laminar convection state cannot be established.

      Although it is thought that most nightside reconnection occurs during substorms or the subsequent SMC, reconnection can also occur when the driving of the Dungey cycle is weak and substorm activity is not expected (for instance during periods of northward IMF), albeit at a low rate and in occasional bursts (Senior et al., 2002; Grocott et al., 2003, 2004, 2005, 2008). Such events have become known as “tail reconnection during IMF‐northward, non‐substorm intervals” or TRINNIs (Milan et al., 2005). Fast eastward or westward convection flows are associated with TRINNIs, the direction being determined by the prevailing sense of IMF BY, associated with the untwisting of newly closed field lines (Grocott et al., 2005, 2007, 2008; Pitkänen, 2015, 2016; Reistad et al., 2016, 2018); the untwisting of these field lines has also been implicated in the formation of transpolar arcs, auroral features that bisect the dark polar cap (Milan et al., 2005; Goudarzi et al., 2008; Fear et al., 2012a, 2012b).

      The question of how long it takes to develop nightside east‐west asymmetries in the nightside convection pattern, and the mechanism by which this occurs, is currently under debate. Mechanisms that have been suggested include pressure asymmetries in the lobe due to asymmetric loading of new open flux (Khurana et al., 1996; Tenfjord et al., 2015; Milan, 2015), and the reconnection of lobe field lines with a significant BY component introduced by asymmetric loading and magnetotail twisting (e.g., Cowley 1981b, Taguchi & Hoffman, 1996; Taguchi et al., 1994; Nishida et al., 1994, 1995, 1998; Tanaka, 2001; Grocott et al., 2005, 2007; Browett et al., 2017). It is possible that all these mechanisms are active, but are governed by different timescales, and manifest themselves in different parts of the convection pattern, that is, open and closed field lines, and at different phases of the substorm cycle (e.g., Grocott, 2017; Milan et al., 2018a).

      2.4.3 Lobe Reconnection

Schematic illustrations of (Left) the topology of field lines that can undergo reconnection when IMF BZ greater than 0. (Right) <hr><noindex><a href=Скачать книгу