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    Melt generation, storage and ascent below Tongariro Volcanic Complex, Southern Taupo Volcanic Zone : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Earth Science at Massey University, Manawatu, New Zealand
    (Massey University, 2018) Arpa, Maria Carmencita B.
    The study of Tongariro Volcanic Complex in New Zealand gives an opportunity to view arc magmatism from a setting where the classic arc structure is overprinted by the regional tectonic setting. Instead of viewing the volcano (and associated magmatic processes) as a component of a volcanic arc to determine the origin of andesitic magmas, focus was given on magmatic processes within the volcanic complex. Processes within the plumbing system of the volcanic complex and their implications on andesitic magmatism and volcanic hazards were determined by tracking magma, of selected eruptive products, from their reservoirs to the surface. By focusing on processes that may determine the petrological characteristics of specific deposits (from known eruptions), the influence of local structures associated with eruptive centres within the complex and the diversity of resultant eruption styles may be interpreted as magmatic processes are evaluated. The deposits for this study are from the last 16 ka history of Tongariro, majority are from the last 10 ka. These are from known eruptions and the deposits were mapped, dated and studied by previous researchers. Lava flow eruptions are from Te Maari and Red Crater, and Plinian to vulcanian eruptions are represented by the Mangamate Tephra and Ngauruhoe deposits. For each eruptive deposit, whole rock major, trace and isotope compositions were determined. Groundmass and mineral components were analysed for major elements. Major element and volatile (H2O, CO2, S, Cl) compositions of melt inclusions in component olivine and pyroxene crystals were also determined. The deposits from the recent history of Tongariro Volcano can be related to a common source. The basalts can differentiate to more evolved andesitic to dacitic compositions by crystallization and/or melting. Magmatic differentiation takes place in different reservoirs, at different depths, within the complex. Differences were observed in the volatile contents of the magmas and these may be related to magma storage and ascent processes. Magmatic processes for the deposits in this study, interpreted from compositions, considered and are consistent with eruption styles.
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    Geophysical investigation into the internal dynamics of moving lahars : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Earth Science at Massey University, Palmerston North, New Zealand
    (Massey University, 2011) Cole, Susan Elizabeth
    Lahars and other mass flows are highly hazardous phenomena that can pose great risk to areas in their path. Due to their often unpredictable onsets, scientific observations are limited. In addition, the erosive capabilities of a lahar mean that the most commonly used monitoring and sampling methods, such as load cells and bedload traps, are often damaged early in the flow. The cost of repair and maintenance of these instrumentation prohibits comprehensive coverage of each channel that might be at risk from lahars. The development of seismic sensors as an alternative monitoring method could prove effective as they do not require contact with a flow and are therefore less at risk from damage. The complex behaviour of a lahar can be witnessed in the geophysical record of its passage which, in combination with more traditional monitoring methods, can be used to record the detailed evolution of a flow. The three-dimensional analysis of seismometer recordings can provide an approximation of the frontal velocity that may differ from maximum velocity estimates made using super-elevation calculations. Comparisons of the seismic records of different mass flow types illustrate that it is possible to differentiate between them. Frequency analysis allows for the distinction of the flow mechanisms, particle interactions, and dominant rheology of a lahar. Low frequencies are more indicative of bedload frictional motion, while higher frequencies reflect the collisional impacts of particles, either between themselves or with the substrate. Detailed records of a flow at a single site provide a comprehensive understanding of the temporal variations that occur within the duration of a lahar, while comparative analyses of numerous sites along a channel highlight its downstream evolution. While initial onset signals can be recorded at local-to-source sites, they are attenuated too quickly to be observed further downstream. The records at proximal sites can, however, reflect the stages, or packets, involved during the main bulk of lahar initiation. At more distal sites, observations show that a lahar transitions to a [minimal] 4-phase behaviour. This consists of a frontal bow wave of ambient streamwater that increases in volume with distance from source, and immediately precedes the lahar proper. The following phases are defined by variations in sediment concentration, velocity, stage, and, in the case of Crater Lake-originating lahars, water chemistry. The understanding of the variable behaviour possible during a lahar, as well as the identification of the specific flow type recorded, is fundamental to modelling approximations of flow volumes, sediment concentrations, likely inundation areas, and probable damage by the flow. It is essential for the development of future warning systems that the variations that can occur within a single lahar are better understood, as lahars represent a serious threat to the slopes of many volcanoes worldwide.