Upptyppingar seismic swarms of 100 m (Rubin and Gillard, 1998). Also, the two standard-deviation uncertainties in our relative reloca- tions average to approximately 60 m. The RMS misfit to our best-fit plane (i.e., 114 m) is greater than the location uncertainty and earthquake rupture diameter; hence, the distribution of our hypocentral locations is amenable to some brittle fracture directly adjacent to the dyke, perhaps representing the ambient stress field that is near to failure. However, we do not ob- serve widespread brittle deformation away from the dyke. Additional improvements to the analysis pro- cedure and station configuration consistently reveal tighter clustering about the plane. We interpret this as evidence for minimal and localised brittle defor- mation surrounding the active dyke plane. The tight spatial clustering revealed by the ASN locations also indicates that the seismicity progressed along the same dip throughout the study period. This is consistent with recent theoretical and experimen- tal models of Maccaferri et al. (2010) that suggest it is energetically favourable for a dyke to continue to propagate along the same dip in a homogeneous, visco-elastic medium. A detailed discussion of focal mechanisms is be- yond the scope of this paper; however, we note that the 288 events consist of both reverse and normal fault- ing in an approximately 3:1 ratio. Moreover, an over- whelming majority of the events have inferred fault planes that are in alignment with the plane of the dyke (White et al., 2011). Although the Upptyppingar seismicity’s tilted ori- entation, manifestation in the ductile zone of the crust, and concomitant dominance of high-frequency im- pulsive P-wave arrivals is unusual, the Lake Tahoe seismicity exhibited similar anomalous characteristics (Smith et al., 2004). Linear regression models fit the seismicity beneath Lake Tahoe to a single planar structure dipping at 50◦ in visco-elastic crust. Additional information regarding the presence of melt may also be obtained from the ratio of P-wave velocity to S-wave velocity (VP /VS), since the nature of the host material controls wave propagation rates. VP /VS ratios are derived independently for each of the 288 events using Wadati diagrams (Wadati, 1933) and PPICK-determined arrival times. Wadati diagrams display the time difference between the S-wave and P-wave arrivals against the arrival time of the P-wave for each station. For any given event, the slope of the best-fit line to the plotted station data represents the ratio of the P-wave to S-wave velocity minus one (i.e., VP /VS –1). As depicted in Figure 13, two statistically sig- nificant populations emerge from the distribution of VP /VS ratios with hypocentral depth: one at <15.25 km depth with a mean VP /VS ratio of 1.78±0.02 (2σ) and another at 15.25–18.40 km depth with a mean VP /VS ratio of 1.80±0.03. Here, statistically signif- icant refers to a rejection of the null hypothesis that the two populations are independent random sam- ples from normal distributions with equal means but not necessarily equal variances at the 1% significance level, determined through a two-tailed t-test. Waves produced by earthquakes at 15.25–18.40 km depth must pass through the overlying region of lower VP /VS ; hence, it is possible to approximate the local VP /VS ratio of the deeper region. Assuming a two-layer model, with the average VP /VS ratio of the upper layer shallower than 15.25 km being 1.78 and a wave source at the centroid of the deeper cluster (∼16.3 km), we estimate the local VP /VS ratio of the deeper region to be ∼2.09. This is higher than that expected or measured for typical, solid high magne- sian gabbroic rocks at mid-depth in the Icelandic crust (Christensen, 1996; Allen et al., 2002; Bjarnason and Schmeling, 2009; Eccles et al., 2009); hence, it is con- sistent with the presence of melt. SUMMARY AND CONCLUSIONS We have presented a test case that demonstrates the benefits of a dense, local seismic network for resolv- ing fine morphological details within compact seismic swarms. However, we also show that high quality re- gional networks, such as the SIL system in Iceland, are more than sufficient for most interpretational re- quirements. Furthermore, we conclude that the net- work size and configuration dominate over the picking of phase arrivals in determining location accuracy and precision. This assumes, of course, that a reasonable effort has been made in picking phase arrivals. The IMO procedures as well as the techniques presented JÖKULL No. 60 63

Side 1
Side 2
Side 3
Side 4
Side 5
Side 6
Side 7
Side 8
Side 9
Side 10
Side 11
Side 12
Side 13
Side 14
Side 15
Side 16
Side 17
Side 18
Side 19
Side 20
Side 21
Side 22
Side 23
Side 24
Side 25
Side 26
Side 27
Side 28
Side 29
Side 30
Side 31
Side 32
Side 33
Side 34
Side 35
Side 36
Side 37
Side 38
Side 39
Side 40
Side 41
Side 42
Side 43
Side 44
Side 45
Side 46
Side 47
Side 48
Side 49
Side 50
Side 51
Side 52
Side 53
Side 54
Side 55
Side 56
Side 57
Side 58
Side 59
Side 60
Side 61
Side 62
Side 63
Side 64
Side 65
Side 66
Side 67
Side 68
Side 69
Side 70
Side 71
Side 72
Side 73
Side 74
Side 75
Side 76
Side 77
Side 78
Side 79
Side 80
Side 81
Side 82
Side 83
Side 84
Side 85
Side 86
Side 87
Side 88
Side 89
Side 90
Side 91
Side 92
Side 93
Side 94
Side 95
Side 96
Side 97
Side 98
Side 99
Side 100
Side 101
Side 102
Side 103
Side 104
Side 105
Side 106
Side 107
Side 108
Side 109
Side 110
Side 111
Side 112
Side 113
Side 114
Side 115
Side 116
Side 117
Side 118
Side 119
Side 120
Side 121
Side 122
Side 123
Side 124
Side 125
Side 126
Side 127
Side 128
Side 129
Side 130
Side 131
Side 132
Side 133
Side 134
Side 135
Side 136
Side 137
Side 138
Side 139
Side 140
Side 141
Side 142
Side 143
Side 144
Side 145
Side 146
Side 147
Side 148
Side 149
Side 150
Side 151
Side 152
Side 153
Side 154
Side 155
Side 156
Side 157
Side 158
Side 159
Side 160
Side 161
Side 162
Side 163
Side 164
Side 165
Side 166
Side 167
Side 168
Side 169
Side 170
Side 171
Side 172
Side 173
Side 174
Side 175
Side 176
Side 177
Side 178
Side 179
Side 180
Side 181
Side 182
Side 183
Side 184
Side 185
Side 186
Side 187
Side 188
Side 189
Side 190
Side 191
Side 192
Side 193
Side 194
Side 195
Side 196
Side 197
Side 198
Side 199
Side 200
Side 201
Side 202
Side 203
Side 204
Side 205
Side 206
Side 207
Side 208
Side 209
Side 210
Side 211
Side 212
Side 213
Side 214
Side 215
Side 216
Side 217
Side 218
Side 219
Side 220
Side 221
Side 222
Side 223
Side 224