Your search keyword '"Glaser, Paul H."' showing total 3 results

1. Climatic drivers for multidecadal shifts in solute transport and methane production zones within a large peat basin.

Author

Glaser, Paul H., Siegel, Donald I., Chanton, Jeffrey P., Reeve, Andrew S., Rosenberry, Donald O., Corbett, J. Elizabeth, Dasgupta, Soumitri, and Levy, Zeno

Subjects

MOVEMENT of solutes in soils, METHANE cycle (Biogeochemistry), PEATLAND ecology, GREENHOUSE gases, METEOROLOGICAL precipitation, SEDIMENTATION & deposition

Abstract

Northern peatlands are an important source for greenhouse gases, but their capacity to produce methane remains uncertain under changing climatic conditions. We therefore analyzed a 43 year time series of the pore-water chemistry to determine if long-term shifts in precipitation altered the vertical transport of solutes within a large peat basin in northern Minnesota. These data suggest that rates of methane production can be finely tuned to multidecadal shifts in precipitation that drive the vertical penetration of labile carbon substrates within the Glacial Lake Agassiz Peatlands. Tritium and cation profiles demonstrate that only the upper meter of these peat deposits was flushed by downwardly moving recharge from 1965 to 1983 during a Transitional Dry-to-Moist Period. However, a shift to a moister climate after 1984 drove surface waters much deeper, largely flushing the pore waters of all bogs and fens to depths of 2 m. Labile carbon compounds were transported downward from the rhizosphere to the basal peat at this time producing a substantial enrichment of methane in Δ14C with respect to the solid-phase peat from 1991 to 2008. These data indicate that labile carbon substrates can fuel deep production zones of methanogenesis that more than doubled in thickness across this large peat basin after 1984. Moreover, the entire peat profile apparently has the capacity to produce methane from labile carbon substrates depending on climate-driven modes of solute transport. Future changes in precipitation may therefore play a central role in determining the source strength of peatlands in the global methane cycle. [ABSTRACT FROM AUTHOR]

Published

2016

2. Surface production fuels deep heterotrophic respiration in northern peatlands.

Author

Elizabeth Corbett, J., Burdige, David J., Tfaily, Malak M., Dial, Angela R., Cooper, William T., Glaser, Paul H., and Chanton, Jeffrey P.

Subjects

CARBON compounds, PEATLAND management, CHROMOGENIC compounds, VEGETATION & climate, MOLECULAR size

Abstract

Multiple analyses of dissolved organic carbon (DOC) from pore waters were conducted to define the processes that govern carbon balance in peatlands: (1) source, reactivity, and transport of DOC with respect to vegetation, peat, and age of carbon substrate, (2) reactivity of DOC with respect to molecular size, and (3) lability to photoxidation of surficial DOC. We found that surface organic production fuels heterotrophic respiration at depth in advection-dominated peatlands, especially in fens. Fen DOC was Δ14C enriched relative to the surrounding fen peat, and fen respiration products were similar to this enriched DOC indicating that DOC was the main microbial substrate. Bog DOC was more variable showing either enrichment in ∆14C at depth or ∆14C values that follow peat values. This variability in bogs is probably controlled by the relative importance of vertical transport of labile carbon substrates within the peat profile versus DOC production from bog peat. These results extended our set of observations to 10 years at one bog-fen pair and add two additional bog-fen pairs to our series of observations. Anaerobic incubations of peat, rinsed free of residual DOC, produced DOC and respiration products that were strikingly similar to the peat values in a bog and two fens. This result demonstrated conclusively that downward advection is the process responsible for the presence of modern DOC found at depth in the peat column. Fen DOC has lower C/N values and up to twice as much LMW (<1 kDa) DOC as bogs due to differences in organic inputs and greater microbial processing. Fluorescence irradiation experiments showed that fen DOC is more photolabile than bog DOC. [ABSTRACT FROM AUTHOR]

Published

2013

3. Temporal variations in dissolved methane deep in the Lake Agassiz Peatlands, Minnesota.

Author

Romanowicz, Edwin A., Siegel, Donald I., Chanton, Jeffrey P., and Glaser, Paul H.

Published

1995