Cosiguina volcano, in northwestern Nicaragua, erupted violently on 20-24 January 1835, producing pumice, scoria, ash fall deposits, and pyroclastic flows with a bulk tephra volume of similar to 6 km(3). New geochemical data are presented for bulk-rocks, matrix glasses, melt inclusions and minerals from the 1835 deposits and a pre-1835 basaltic andesite tephra, with the aim of shedding light on the magmatic processes and associated timescales that led to the eruption. Our results reveal that the 1835 eruption was fed by a compositionally and thermally zoned magma reservoir situated similar to 4 km (P-H2O similar to 100 MPa) beneath the volcano. Small volumes of crystal-poor dacite (%26lt; 10 wt % phenocrysts, 63 center dot 8-64 center dot 8 wt % SiO2, similar to 950A degrees C) and silicic andesite (%26lt; 10 wt % phenocrysts, 62 center dot 2 wt % SiO2, 960-1010A degrees C) were erupted first, followed by relatively crystal-rich andesite (15-30 wt % phenocrysts, 57 center dot 4-58 center dot 8 wt % SiO2, 960-1010A degrees C), which accounts for similar to 90% of the erupted magma. The pre-1835 basaltic andesite (similar to 20 wt % phenocrysts, 52 center dot 4 wt % SiO2, 1110-1170A degrees C) represents a mafic end-member for Cosiguina. The major and trace element compositions of the bulk-rocks, melt inclusions and matrix glasses suggest that (1) the pre-1835 basaltic andesite is a plausible parent for the 1835 magmas, (2) the 1835 andesite bulk-rocks do not represent true melts, but instead mixtures of silicic andesite liquid and a component of accumulated crystals dominated by plagioclase, and (3) the silicic andesite and dacite formed from the andesite magma through liquid extraction followed by fractional crystallization. Observed bimodal to trimodal crystal populations are consistent with a multi-stage, polybaric differentiation process, with calcic plagioclase (An(75-90), An(90-95)) and magnesian clinopyroxene (Mg# = 67-75), plus olivine and magnetite, forming from mafic andesite, basaltic andesite and basalt in the lower crust. The calcic plagioclase exhibits sieve textures, which may be the result of H2O-undersaturated decompression during magma ascent to the upper crust; An(50-65) plagioclase lacking a sieve texture, orthopyroxene (Mg# = 61 and 63-72), clinopyroxene (Mg# = 67), magnetite and apatite crystallized from andesite to dacite liquids in the shallow magma reservoir. An(75-90) plagioclase comprising entire phenocrysts or cores with An(50-65) rims in the 1835 magmas is cognate from earlier stages of differentiation and shows evidence of extensive diffusion of Mg when compared with similar An(75-95) crystals hosted in the pre-1835 basaltic andesite. Using plagioclase-melt Mg partitioning and modelling of the Mg diffusion process, we constrain the residence time of these crystals in the silicic liquids to more than 100 years and less than 2000 years, with detailed analysis of three crystals yielding similar to 400 years. We propose that magma reservoir zonation occurred on timescales of 10(2)-10(3) years at Cosiguina. The occurrence of H2O-rich fluid inclusions in all 1835 samples and volatile element systematics in melt inclusions imply that the magmas were saturated with a vapour phase (H2O, S, +/- CO2) during much of their evolution in the upper crust. Accumulation of free gas at the top of the magma reservoir may have led to overpressurization of the system, triggering the eruption. %26lt;br%26gt;Catastrophic release of this exsolved vapour and syn-eruptive devolatilization of the melt injected several teragrams of S into the atmosphere. Our data, coupled with independent evidence from ice cores and tree rings, indicate that the Cosiguina eruption had a sizeable atmospheric impact comparable with or larger than that of the 1991 Pinatubo eruption. Stratigraphic evidence shows that Cosiguina has produced %26gt; 15 compositionally zoned explosive eruptions in the past, suggesting that similar future eruptions are likely. The products of the 1835 eruption of Cosiguina share many features with compositionally zoned eruptive sequences elsewhere, such as the climactic eruption of Mount Mazama, the ad 79 %26apos;Pompei%26apos; eruption of Vesuvius and the 1912 eruption of Novarupta-Katmai.

• 出版日期2014-6