"14"^^ . "http://dx.doi.org/10.1007/s00445-014-0873-z" . . "stratovolcano; pluton floor subsidence; magma emplacement; intrusive strain; aaldera; anisotropy of magnetic susceptibility (AMS)"@en . . "Chadima, Martin" . "I, P(GAP210/12/1385), S" . . . . . . "Magma flow paths and strain patterns in magma chambers growing by floor subsidence: a model based on magnetic fabric study of shallow-level plutons in the \u0160tiavnica volcano-plutonic complex, Western Carpathians"@en . "000343088400004" . "Bulletin of Volcanology" . . "\u017D\u00E1k, Ji\u0159\u00ED" . "Magma flow paths and strain patterns in magma chambers growing by floor subsidence: a model based on magnetic fabric study of shallow-level plutons in the \u0160tiavnica volcano-plutonic complex, Western Carpathians" . "The Miocene \u0160tiavnica volcano-plutonic complex, Western Carpathians, exposes two nearly coeval intra-caldera plutons, their roof (basement of a stratovolcano), and associated volcanic rocks. The complex thus provides insights into mechanisms of magma chamber growth beneath large volcanoes. As inferred from the anisotropy of magnetic susceptibility (AMS), these plutons were emplaced through significantly different processes: the diorite as a discordant stock with steep fabric and the granodiorite as a tabular, bell-jar pluton. In detail, we interpret that the latter was assembled in two stages. First, an upper %22layer%22 intruded as a thin sill along a major subhorizontal basement/cover detachment. The subhorizontal magnetic fabric and strongly oblate AMS ellipsoid in this layer record intrusive strain where the magma flow paths were subparallel to the pluton roof. Second, in the lower %22layer%22 of the pluton, magnetic foliations dip moderately to the similar to NW and similar to WNW to vertical and are associated with down-dip to subhorizontal lineations and prolate to weakly oblate shapes of the AMS ellipsoids. Such a fabric pattern is compatible with piecemeal floor subsidence, where magma flowed along multiple subsiding fault-bounded blocks. Based on this case example, we develop a conceptual model for magma flow paths and strain patterns for four main modes of floor subsidence: (1) piston (cauldron) subsidence is characterized by convergent flow and radial principal stretching above the magma chamber floor; (2) the piecemeal floor subsidence leads to steep to inclined magma flow paths in conduits along fault-bounded blocks; (3) asymmetric (trapdoor) subsidence produces first divergent flow paths near the conduit sides, changing into convergent paths in the narrower space near the kinematic hinge; and (4) symmetric cantilever (funnel) subsidencewill lead to divergent flow from a central feeder and thus circumferential principal stretching of the magma."@en . . "US - Spojen\u00E9 st\u00E1ty americk\u00E9" . "The Miocene \u0160tiavnica volcano-plutonic complex, Western Carpathians, exposes two nearly coeval intra-caldera plutons, their roof (basement of a stratovolcano), and associated volcanic rocks. The complex thus provides insights into mechanisms of magma chamber growth beneath large volcanoes. As inferred from the anisotropy of magnetic susceptibility (AMS), these plutons were emplaced through significantly different processes: the diorite as a discordant stock with steep fabric and the granodiorite as a tabular, bell-jar pluton. In detail, we interpret that the latter was assembled in two stages. First, an upper %22layer%22 intruded as a thin sill along a major subhorizontal basement/cover detachment. The subhorizontal magnetic fabric and strongly oblate AMS ellipsoid in this layer record intrusive strain where the magma flow paths were subparallel to the pluton roof. Second, in the lower %22layer%22 of the pluton, magnetic foliations dip moderately to the similar to NW and similar to WNW to vertical and are associated with down-dip to subhorizontal lineations and prolate to weakly oblate shapes of the AMS ellipsoids. Such a fabric pattern is compatible with piecemeal floor subsidence, where magma flowed along multiple subsiding fault-bounded blocks. Based on this case example, we develop a conceptual model for magma flow paths and strain patterns for four main modes of floor subsidence: (1) piston (cauldron) subsidence is characterized by convergent flow and radial principal stretching above the magma chamber floor; (2) the piecemeal floor subsidence leads to steep to inclined magma flow paths in conduits along fault-bounded blocks; (3) asymmetric (trapdoor) subsidence produces first divergent flow paths near the conduit sides, changing into convergent paths in the narrower space near the kinematic hinge; and (4) symmetric cantilever (funnel) subsidencewill lead to divergent flow from a central feeder and thus circumferential principal stretching of the magma." . . "0258-8900" . . . "11" . . "Magma flow paths and strain patterns in magma chambers growing by floor subsidence: a model based on magnetic fabric study of shallow-level plutons in the \u0160tiavnica volcano-plutonic complex, Western Carpathians"@en . "RIV/00216208:11310/14:10283108!RIV15-MSM-11310___" . . . . . . "76" . "Magma flow paths and strain patterns in magma chambers growing by floor subsidence: a model based on magnetic fabric study of shallow-level plutons in the \u0160tiavnica volcano-plutonic complex, Western Carpathians" . "RIV/00216208:11310/14:10283108" . . "3"^^ . "[E71A47D8AE14]" . "26864" . "11310" . "Tomek, Filip" . "10.1007/s00445-014-0873-z" . . . "2"^^ .