Geochemical fingerprinting of volcanic airfall deposits: A tool in
stratigraphic correlation
Soumava Adhya 2009
A Dissertation Submitted to the State University of New York at Albany
in Partial Fulfillment of the Requirements for the Degree of Doctor of
Philosophy
College of Arts and Sciences, Department of Earth & Atmospheric
Sciences
Advisor: J.W. Delano
ABSTRACT
Chemical fingerprints of volcanic airfall deposits
obtained from high-precision electron microprobe analysis of glass and
phenocrysts phases provide geochemical correlations with temporal
precision unattainable by other methods. In this research electron
microprobe analysis (EMA) techniques, to fingerprint chemically and
correlate fresh and altered volcanic airfall deposits, have been
utilized to test the value of this tool for future research on
stratigraphic correlation. The following samples were chosen from
within a variety of sedimentary rocks widely separated spatially and
temporally:
~450 Ma old upper Middle Ordovician K-bentonites
(altered volcanic airfall deposits) collected from eastern United
States.
Relatively fresh Pleistocene tuff from ~74 ka old
Youngest Toba Tuff (YTT) eruption in Sumatra (Indonesia).
Fresh Pleistocene volcanic ash from India, and Sulu
Sea ODP cores.
This research confirms 14 K-bentonite correlations, of which 10 are
reported for the first time, based on chemical compositions of apatite
phenocrysts and melt inclusions in quartz phenocrysts. Significant
K-bentonite research findings include:
1. Chemical correlation of Hounsfield K-bentonite
and the Milibrig K-bentonite.
2. Several new chemical correlations of K-bentonite
beds from within the Ordovician rocks in Taconic foreland basin.
3. Melt inclusion chemistry might be the more
effective tool for differentiating closely spaced K-bentonites than
that of apatite.
Biotite phenocrysts, melt inclusions in quartz and plagioclase
phenocrysts, and glass shard chemistry of proximal and distal YTT ash
successfully discriminate it with other closely spaced ash layers. This
research reports for the first time, the presence of melt inclusion
bearing plagioclase from Pleistocene volcanic ash from India and
correlates it chemically to the YTT. The Pleistocene ash from Sulu Sea
ODP was not produced by YTT eruption.
The best discriminating elements observed are:
1. Toba biotites - Mn, Ti, Cl, Mg and Fe.
2. Ordovician apatites - Mn, Mg, Fe, Cl, and F (new
finding).
3. Melt inclusions and glass shards - Ca, Fe, Mg,
Mn, Cl, Ti, K and Na.
Using a dual approach, i.e., glass as well as phenocryst chemical
signatures, makes a better tool for differentiating or correlating
vertically closely spaced or geographically widely spaced volcanic
airfall deposits.
Adhya, S.,
2009. Geochemical fingerprinting of volcanic airfall deposits: A tool
in stratigraphic correlation. Unpublished PhD dissertation, State
University of New
York
at Albany. pp., + .
University at Albany Science Library call number: SCIENCE MIC
Film QE 40 Z899 2009 A??
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