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1.
The Kupaianaha vent, the source of the 48th episode of the 1983-to-present Pu'u 'O'o–Kupaianaha eruption, erupted nearly
continuously from July 1986 until February 1992. This investigation documents the geophysical and geologic monitoring of the
final 10 months of activity at the Kupaianaha vent. Detailed very low frequency (VLF) electromagnetic profiles across the
single lava tube transporting lava from the vent were used to determine the cross-sectional area of the molten lava within
the tube. Combined with measurements of lava velocity, these data provide an estimate of the lava output of Kupaianaha. In
addition, lava temperatures (calculated from analysis of quenched glass) and bulk-rock chemistry were obtained for samples
taken from the tube at the same site. The combined data set shows the lava flux from Kupaianaha vent declining linearly from
250 000 m3/day in April 1991 to 54 000 m3/day by November 1991. During that time surface breakouts of lava from weak points along the tube occurred progressively closer
to the vent, consistent with declining efficiency in lava transport. There were no significant changes in lava temperature
or in bulk MgO content during this period. Another eruptive episode (the 49th) began uprift of Kupaianaha on 8 November 1991
and erupted lava concurrently with Kupaianaha for 18 days. Lava flux from Kupaianaha decreased in response to this new episode,
but the response was delayed by approximately 1 day. After 14 November 1991, lava velocities were no longer measurable in
the tube because the lava stream beneath the skylight had crusted over; however, the VLF-derived electrical conductances documented
the decreasing flux of molten lava through the tube. Kupaianaha remained active, but output continued to decrease until early
February 1992 when the last active surface flows were seen. In November 1991 we used the linearly decreasing effusion rate
to accurately predict the date for the death of the Kupaianaha vent. The linear nature of the decline in lava tube conductance
and the delayed and slow response of the Waha'ula tube conductances to the 49th eruptive episode led us to speculate that
(a) the Kupaianaha vent shut down because of a decrease in driving pressure and not because of a freeze-up of the vent, and
(b) that Pu'u 'O'o, episode 49, and Kupaianaha were fed nearly vertically from a source deep within the rift zone.
Received: 29 September 1995 / Accepted: 21 November 1995 相似文献
2.
Pliocene–Recent volcanic outcrops at Seal Nunataks and Beethoven Peninsula (Antarctic Peninsula) are remnants of several
monogenetic volcanoes formed by eruption of vesiculating basaltic magma into shallow water, in an englacial environment. The
diversity of sedimentary and volcanic lithofacies present in the Antarctic Peninsula outcrops provides a clear illustration
of the wide range of eruptive, transportational and depositional processes which are associated with englacial Surtseyan volcanism.
Early-formed pillow lava and glassy breccia, representing a pillow volcano stage of construction, are draped by tephra erupted
explosively during a tuff cone stage. The tephra was resedimented around the volcano flanks, mainly by coarse-grained sediment
gravity flows. Fine-grained lithofacies are rare, and fine material probably bypassed the main volcanic edifice, accumulating
in the surrounding englacial basin. The pattern of sedimentation records variations in eruption dynamics. Products of continuous-uprush
eruptions are thought to be represented by stacks of poorly bedded gravelly sandstone, whereas better bedded, lithologically
more diverse sequences accumulated during periods of quiescence or effusive activity. Evidence for volcano flank failure is
common. In Seal Nunataks, subaerial lithofacies (mainly lavas and cinder cone deposits) are volumetrically minor and occur
at a similar stratigraphical position to pillow lava, suggesting that glacial lake drainage may have occurred prior to or
during deposition of the subaerial lithofacies. By contrast, voluminous subaerial effusion in Beethoven Peninsula led to the
development of laterally extensive stratified glassy breccias representing progradation of hyaloclastite deltas.
Received: 5 February 1996 / Accepted: 17 January 1997 相似文献