Hydrological and biogeochemical cycling along the Greenland ice sheet margin
Hydrological and biogeochemical cycling along the Greenland ice sheet margin
Date
2012-02
Authors
Bhatia, Maya P.
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Location
Greenland
DOI
10.1575/1912/5135
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Keywords
Glaciology
Biogeochemical cycles
Biogeochemical cycles
Abstract
Global warming has led to a significant increase in Greenland ice sheet (GrIS) melt and
runoff since 1990, resulting in escalated export of fresh water and associated sediment to
the surrounding North Atlantic and Arctic Oceans. Similar to alpine glacial systems,
surface meltwater on ice sheet surface drains to the base (subglacial) where it joins a
drainage system and can become chemically enriched from its origin as dilute snow- and
ice-melt. In this thesis, I examine the interdependence of glacial hydrology and
biogeochemical cycling in terms of export of carbon and iron from the Greenland ice
sheet. I develop a new isotope mixing-model to quantify water source contributions to the
bulk meltwater discharge draining a GrIS outlet glacier. Results illustrate (a) the new
application of a naturally occurring radioisotope (radon-222) as a quantitative tracer for
waters stored at the glacier bed, and (b) the seasonal evolution of the subglacial drainage
network from a delayed-flow to a quick-flow system. Model results also provide the
necessary hydrological context to interpret and quantify glacially-derived organic carbon
and iron fluxes. I combine bulk- and molecular-level studies of subglacial organic carbon
to show that GrIS discharge exports old (radiocarbon depleted), labile organic matter.
Similar investigations of dissolved and particulate iron reveal that GrIS discharge may be
a significant flux of labile iron to the North Atlantic Ocean during the summer
meltseason. Both carbon and iron are subject to proglacial processing prior to export to
the marine environment, and exhibit strong seasonal variability in correlation with the
subglacial drainage evolution. Low, chemically concentrated fluxes characterize the
spring discharge, whereas higher, chemically dilute fluxes typify the summer discharge.
Collectively, this thesis provides some of the first descriptions and flux estimates of
carbon and iron, key elements in ocean biogeochemical cycles, in GrIS meltwater runoff.
Description
Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution February 2012
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Citation
Bhatia, M. P. (2012). Hydrological and biogeochemical cycling along the Greenland ice sheet margin [Doctoral thesis, Massachusetts Institute of Technology and Woods Hole Oceanographic Institution]. Woods Hole Open Access Server. https://doi.org/10.1575/1912/5135