Sample: 96-15A


Sample ID: 96-15A [1]
Station ID: TDE-96-15
AT Num:
Volcano:
Possible source:
Eruption:
Collector: Dochat, T. M.
Date sampled:
Sample type 1: Tephra Fall
Color:
Final unit:
Text Description: From Dochat (1997): A 9 cm thick layer of pumice (individual pieces up to 1 cm in diameter) in silty matrix overlies the diamicton. The pumice is thought to be from an eruption of Mt. Dutton earlier than 9,090 +/- 140 14C yrs BP. A 66 cm thick sand layer of which the upper 1 cm is oxidized overlies the pumice deposit. Overlying the oxidized horizon is a layer of ash 1 cm thick and a 6 cm thick layer of medium grained silt. A wavy contact separates the silt from the overlying 1.5 cm of ash. A 4.5 cm thick layer of clayey silt occurs above the ash and is overlain by 12.5 cm of scoria. The middle scoria layer is 3 cm thick and oxidized. The upper 8 cm of black scoria corresponds with the Fisher caldera ash exposed throughout the Cold Bay and False Pass regions. Coarse sand, 8.5 cm thick, crops out above the Fisher caldera ash. A layer of medium-grained sand 35 cm thick occurs above this. A 20 cm thick horizon of clay caps the sand. Organic-rich material (6,020 +/- 340 14C yrs BP), 30 cm thick, overlies the clay. Within the organic material, thin ash layers (1 cm thick) occur with wavy contacts, dipping up to 20 degrees. A planar, horizontal contact separates the organic-rich layer from the overlying 2 cm of ash above which is 6 cm of additional organic-rich material. A 5 cm thick ash layer occurs at the base of the 122 cm of sand that cap the bluff. Unclear which samples correlate to which units, as no sample descriptions are provided.
Sample Location:

References Cited

[1] Quaternary stratigraphy and geomorphology of the Cold Bay region of the Alaska Peninsula: a basis for paleoenvironmental reconstruction (glacial deposits), 1997

Dochat, T. M., 1997, Quaternary stratigraphy and geomorphology of the Cold Bay region of the Alaska Peninsula: a basis for paleoenvironmental reconstruction (glacial deposits): The University of Wisconsin unpublished Ph.D. dissertation, Madison, Wisconsin, 330 p.