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Major-element chemical analyses of Hole 51-417D (2005)

Ui, Tadahide ; Bryan, Wilfred B ; Robinson, Paul T

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Publication Date: 2023-06-27

Keywords: 51-417D; Alteration; Aluminium oxide; Calcium oxide; Calculated; Comment; Deep Sea Drilling Project; DEPTH, sediment/rock; DRILL; Drilling/drill rig; DSDP; DSDP/ODP/IODP sample designation; Glomar Challenger; Iron oxide, Fe2O3, fractionated; Iron oxide, FeO; Iron oxide, FeO, fractionated; Leg51; Lithology/composition/facies; Magnesium oxide; Manganese oxide; Method comment; North Atlantic/CONT RISE; Phosphorus pentoxide; Potassium oxide; Rock type; Sample code/label; Sample ID; Sample method; Silicon dioxide; Sodium oxide; Titanium dioxide; Water content, dry mass

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Format: text/tab-separated-values, 736 data points

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Major-element chemical analyses of Hole 51-417A (2005)

Ui, Tadahide ; Bryan, Wilfred B ; Robinson, Paul T

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Publication Date: 2023-06-27

Keywords: 51-417A; Alteration; Aluminium oxide; Calcium oxide; Calculated; Deep Sea Drilling Project; DEPTH, sediment/rock; DRILL; Drilling/drill rig; DSDP; DSDP/ODP/IODP sample designation; Glomar Challenger; Iron oxide, Fe2O3, fractionated; Iron oxide, FeO, fractionated; Leg51; Lithology/composition/facies; Magnesium oxide; Manganese oxide; Method comment; North Atlantic/CONT RISE; Phosphorus pentoxide; Potassium oxide; Rock type; Sample code/label; Sample ID; Sample method; Silicon dioxide; Sodium oxide; Titanium dioxide; Water content, dry mass

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Format: text/tab-separated-values, 178 data points

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Major-element chemical analyses of Hole 52-417D (2005)

Ui, Tadahide ; Donelly, Thomas W ; Bryan, Wilfred B ; [et al.]

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Publication Date: 2023-06-27

Keywords: 52-417D; Alteration; Aluminium oxide; Calcium oxide; Comment; Deep Sea Drilling Project; DEPTH, sediment/rock; DRILL; Drilling/drill rig; DSDP; DSDP/ODP/IODP sample designation; Glomar Challenger; Iron oxide, FeO; Leg52; Lithology/composition/facies; Magnesium oxide; Manganese oxide; Method comment; Potassium oxide; Rock type; Sample code/label; Sample ID; Sample method; Silicon dioxide; Sodium oxide; Titanium dioxide

Type: Dataset

Format: text/tab-separated-values, 34 data points

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Internal structural variations in a debris-avalanche deposit from ancestral Mount Shasta, California, USA (1986)

Ui, Tadahide ; Glicken, Harry

Springer

Bulletin of volcanology 48 (1986), S. 189-194

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ISSN: 1432-0819

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract Various parameters of the internal structure of a debris-avalanche deposit from ancestral Mount Shasta (size and percentage of block facies in each exposure, number and width of jigsaw cracks, and number of rounded clasts in matrix facies) were measured in order to study flow and emplacement mechanisms. Three types of coherent blocks were identified: blocks of massive or brecciated lava flows or domes, blocks of layered volcaniclastic deposits, and blocks of accidental material, typically from sedimentary units underlying Shasta Valley. The mean maximum dimension of the three largest blocks of layered volcaniclastic material is 220 m, and that of the lava blocks, 110 m. This difference may reflect plastic deformation of blocks of layered volcaniclastic material; blocks of massive or brecciated volcanic rock deformated brittly and may have split into several smaller blocks. The blocks in the deposit are one order of magnitude larger, and the height of collapse 1100 m higher, than the Pungarehu debris-avalanche deposit at Mount Egmont, New Zealand, although the degree of fracturing is about the same.This suggests either that the Shasta source material was less broken, or that the intensity of any accompanying explosion was smaller at ancestral Mount Shasta. The Shasta debris-avalanche deposit covered the floor of a closed basin; the flanks of the basin may have retarded the opening of jigsaw cracks and the formation of stretched and deformed blocks such as those of the Pungarehu debris-avalanche deposit.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01087673

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Volcanic hazards from Bezymianny- and Bandai-type eruptions (1987)

Siebert, Lee ; Glicken, Harry ; Ui, Tadahide

Springer

Bulletin of volcanology 49 (1987), S. 435-459

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ISSN: 1432-0819

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract Major slope failures are a significant degradational process at volcanoes. Slope failures and associated explosive eruptions have resulted in more than 20 000 fatalities in the past 400 years; the historic record provides evidence for at least six of these events in the past century. Several historic debris avalanches exceed 1 km3 in volume. Holocene avalanches an order of magnitude larger have traveled 50–100 km from the source volcano and affected areas of 500–1500 km2. Historic eruptions associated with major slope failures include those with a magmatic component (Bezymianny type) and those solely phreatic (Bandai type). The associated gravitational failures remove major segments of the volcanoes, creating massive horseshoe-shaped depressions commonly of caldera size. The paroxysmal phase of a Bezymianny-type eruption may include powerful lateral explosions and pumiceous pyroclastic flows; it is often followed by construction of lava dome or pyroclastic cone in the new crater. Bandai-type eruptions begin and end with the paroxysmal phase, during which slope failure removes a portion of the edifice. Massive volcanic landslides can also occur without related explosive eruptions, as at the Unzen volcano in 1792. The main potential hazards from these events derive from lateral blasts, the debris avalanche itself, and avalanche-induced tsunamis. Lateral blasts produced by sudden decompression of hydrothermal and/or magmatic systems can devastate areas in excess of 500km2 at velocities exceeding 100 m s−1. The ratio of area covered to distance traveled for the Mount St. Helens and Bezymianny lateral blasts exceeds that of many pyroclastic flows or surges of comparable volume. The potential for large-scale lateral blasts is likely related to the location of magma at the time of slope failure and appears highest when magma has intruded into the upper edifice, as at Mount St. Helens and Bezymianny. Debris avalanches can move faster than 100 ms−1 and travel tens of kilometers. When not confined by valley walls, avalanches can affect wide areas beyond the volcano's flanks. Tsunamis from debris avalanches at coastal volcanoes have caused more fatalities than have the landslides themselves or associated eruptions. The probable travel distance (L) of avalanches can be estimated by considering the potential vertical drop (H). Data from a catalog of around 200 debris avalanches indicates that the H/L rations for avalanches with volumes of 0.1–1 km3 average 0.13 and range 0.09–0.18; for avalanches exceeding 1 km3, H/L ratios average 0.09 and range 0.5–0.13. Large-scale deformation of the volcanic edefice and intense local seismicity precede many slope failures and can indicate the likely failure direction and orientation of potential lateral blasts. The nature and duration of precursory activity vary widely, and the timing of slope faliure greatly affects the type of associated eruption. Bandai-type eruptions are particularly difficult to anticipate because they typically climax suddenly without precursory eruptions and may be preceded by only short periods of seismicity.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01046635

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Depositional ramps: asymmetrical distribution structure in the Ata pyroclastic flow deposit, Japan (1988)

Suzuki-Kamata, Keiko ; Ui, Tadahide

Springer

Bulletin of volcanology 50 (1988), S. 26-34

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ISSN: 1432-0819

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The asymmetrical distribution of the welded Ata large-scale pyroclastic flow deposit in Southern Kyushu, Japan was identified. This distribution pattern was defined as depositional ramps. Depositional ramps can be identified in valleys wider than 1 km and become smaller-scale with increasing distance from the source. Upslope directions of depositional ramps are generally radially away from the source caldera, suggesting that the structure was formed by the flow of pyroclastic material radially away from the source. The original depositional surface was reconstructed based on field mapping and density measurements of the pyroclastic flow deposit. Depositional ramps having a dip angle of more than 9° were reconstructed on the vent-facing slopes of the topography underlying the valley-filling deposits in the area within 10 km of the caldera rim. Such a dip angle is much larger than previously described dip angles. The size and gradient of the depositional ramps decreases with increasing distance from the source. Depositional ramps are recognized commonly in densely welded pyroclastic flow deposits. A high emplacement temperature is required to form the depositional ramps. This suggests that the pyroclastic flow was transported as a dense, fluidized layer to minimize heat loss.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01047506

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Flow behavior of large-scale pyroclastic flows — Evidence obtained from petrofabric analysis (1989)

Ui, Tadahide ; Suzuki-Kamata, Keiko ; Matsusue, Rumi ; [et al.]

Springer

Bulletin of volcanology 51 (1989), S. 115-122

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ISSN: 1432-0819

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The grain orientations within the matrix of two large-scale welded, two small-scale nonwelded and two nonwelded low-aspect ratio pyroclastic flow deposits are measured to analyze flow behavior. Preferred grain alignments are especially apparent in the middle part of layer 2 of each deposit. Preferred grain alignments do not vary laterally within a 10 m interval. The grain alignments obtained are radial from the source caldera, especially in proximal to medial and plateau-forming facies of pyroclastic flow deposits. Grain alignments are controlled by valley-channel directions for the valley-ponded facies of pyroclastic flow deposits, especially at medial to distal locations. Such local topographic factors strongly affect the data for high-aspect ratio and smallscale deposits, and weakly affect the data for widespread low-aspect ratio pyroclastic flow deposits. This work suggests that grain alignment analysis should be used with care when attempting to determine the location of an unknown source.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01081980

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Depositional features and transportation mechanism of valley-filling Iwasegawa and Kaida debris avalanches, Japan (1999)

Takarada, Shinji ; Ui, Tadahide ; Yamamoto, Yuko

Springer

Bulletin of volcanology 60 (1999), S. 508-522

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ISSN: 1432-0819

Keywords: Key words Debris avalanche ; Valley filling ; Debris-avalanche block ; Debris-avalanche matrix ; Wood orientation ; Basal structure ; Plug flow

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The depositional features of two valley-filling debris avalanche deposits were studied to reveal their transportation and depositional mechanisms. The valley-filling Iwasegawa debris avalanche deposit (ca. 0.1 km3) is distributed along the valleys at the southeastern foot of Tashirodake Volcano, northern Honshu, Japan. Debris-avalanche blocks range in size from 〈35 m proximally to 〈10 m in the distal zone and consist dominantly of fragile materials. Debris-avalanche matrix percentages increase from 35–60% in the proximal zone to 95% in the distal zone. The debris-avalanche matrix is greater in volume (80–90%) at the bottom and margins of the deposit. Normal grading of large clasts and reverse grading of wood logs and branches occur within the debris-avalanche matrix. Preferred orientation of 311 wood logs and branches within the deposit coincide with the interpreted local flow direction. The basal part of the deposit is characterized by (1) erosional features and incorporated clasts of underlying material; (2) a higher proportion (30–50%) of incorporated clasts than the upper part; and (3) reverse grading of clasts. The valley-filling Kaida debris avalanche deposit (50 000 y B.P., 〉0.3 km3) is distributed along the valleys at the eastern-southeastern foot of Ontake Volcano, central Japan. Debris-avalanche blocks range in size from 〈25 m proximally to 〈7 m in the medial zone. Debris-avalanche matrix percentages increase from 50–70% in the proximal zone to 80% in the distal zone. The debris-avalanche matrix is more abundant (80–90%) at the bottom part of the deposit. Deformation structures observed in the debris-avalanche blocks include elongation, folding, conjugate reverse faults, and numerous minor faults in unconsolidated materials. Lithic components within the debris-avalanche matrix tend to have a higher percentage of plucked clasts from the adjacent underlying formations. A Bingham "plug flow" model is consistent with the transportation and depositional mechanisms of the valley-filling debris avalanches. In the plug of the debris avalanche, fragile blocks were transported without major rupturing due to relatively small shear stresses in regions of small strain rate. The debris-avalanche matrix was mainly produced by shearing at the bottom and margins of the avalanche. Valley-filling debris avalanches tend to have smaller debris-avalanche blocks and larger amounts of debris-avalanche matrix than do unconfined debris avalanches. These differences may be due to disaggregation of debris-avalanche blocks by shearing against valley walls and interaction between debris-avalanche blocks and valley walls. Oriented wood logs and branches, reverse grading of clasts at the base, and a higher proportion of incorporated clasts at the base are interpreted to result from shearing along the bottom and valley walls.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004450050248

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