Intraplate earthquake swarms in Central Europe The source mechanisms of the 2000 swarm differ substantially from those of the 1997 swarm. Simi- larly as in the swarm of 1997, both oblique-normal and oblique-thrust events occurred in 2000, however, the oblique-normal faulting prevailed; besides, the oblique-thrust events were limited to the first swarm phases. The predominant strikes and dips of the 2000- oblique-normal events matched the geometry of the main fault plane Nový Kostel (NK) as well as the strike, dip and rake of the largest ML=4.6 earth- quake of the swarm of 1985/86 (Antonini, 1988). This, together with the localization results (Fischer and Horálek, 2003), suggests that both location and faulting in 1985/86 and 2000 swarms were similar. The resultant mechanisms of all events are dominantly DCs with only insignificant non-DC components usu- ally not exceeding 10% as a whole. The massive dom- inance of the DC in all investigated events implies that the 2000-swarm consisted of a great number of pure shears along the fault plane. The resultant source mechanisms of 1997 and 2000 swarms are represented in two ways (Figure 8). The orientation of the fault planes (DC parts) is de- picted by the composite focal mechanism plots and the non-DC parts using the Hudson at al. (1989) source-type diagrams. Here, the moment tensor is parameterized by the quantities k and T , both vary- ing between –1 and 1. In general, a source with k=1 corresponds to a purely explosive event, while a source with k=–1 corresponds to a pure implosion. The parameter T corresponds to the content of CLVD part. The pure DC sources are uniquely described by k=T=0 (for more details refer to Hudson at al., 1989). The source type plots of 1997 and 2000 swarms significantly differ: while the 1997 sources align along dipole-type axis, the 2000 sources form a tight cluster near the DC source type. The common dipole character of the 1997 sources shows that all events were of the same type; however, the polarity of the dipole varied with time. The slightly compressive dipoles dominating in the first part of the swarm (blue symbols) were replaced by tensile dipoles in the sec- ond part of the swarm (red and yellow symbols). The larger non-DC part of the late events corresponds to the B-type events of tensile character, while the smaller non-DC part of early events corresponds to the A-type events of nearly DC character. However, the systematic non-DC part of most events (extension along common line in the source-type plot) suggests that the non-DC components may not be random. The plausibility of the non-DC character of the 1997 sources is supported by number of tests per- formed by Horálek et al. (2002) to rule out the possi- ble effect of insufficient focal sphere coverage, inac- curate or noisy input data, inexact localization of the hypocentre and poor velocity model on the origina- tion of spurious non-DC components. Another sup- porting argument is the fact that the A and B events were located within a compact cluster and the whole swarm was recorded by the same configuration of the stations. Thus the waves of the A and B events propagated along the similar travel paths. Further- more, we checked the reliability of MTs of the 2000 swarm by means of the jack-knife trials in which the number of stations used in the MT inversions varied from a complete set down to 7 and 6 (Horálek et al., 2010). The reduced data set differed in only two sta- tions (which did not operate in 2000) from that one used to retrieve the MT of the 1997 swarm. The tests proved stability and good constraints of these MT so- lutions. Besides, they evidenced high susceptibility to focal sphere coverage by stations: sparse station distribution resulted in the appearance of false non- DC components, mainly CLVD. However, for all the analyzed events of both 1997 and 2000 swarms, the focal-sphere coverage was sufficient thanks to suit- ably distributed stations NKC, KRC, KOC and LAC which were used in all MT inversions performed. The test also showed that the non-DC parts <15 % can not be consider as significant even in case of a sufficient focal-sphere coverage (for more information of the appearance of false non-DC components due to noise, mislocation of the hypocentre and velocity structure mismodelling, see Horálek et al., 2010). It is evident that the type of faulting depends on the orientation of the fault plane with respect to the lo- cal tectonic stress field. Providing that the stress esti- mations by Havír̆ (2000), Vavryc̆uk (2002) and Plene- fisch and Klinge (2003) (which are fairly similar) are consistent with a steady local stress in the NK zone, JÖKULL No. 60 77

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