Studies of sulfur biogeochemistry, microbiology and paleontology in three anoxic environments: The Black Sea, a salt marsh mat, and an Ordovician black shale
Thesis/Dissertation
·
OSTI ID:5430530
The author studied the biogeochemistry, microbial ecology and paleontology of three anoxic environments. In the Black Sea, three studies dealt with the role of particle fluxes in sulfur cycling and microbial ecology. In the water column, iron sulfides form at the oxic-anoxic interface from dissolved sulfide left after chemical oxidation, based on sulfur isotopes; formation in deep water is minimal and iron-limited. Sinking organic aggregates transport iron sulfides to the bottom. Sedimentary sulfides may originate from sulfide fluxes and record intensity of chemical vs. microbial oxidation at the oxic-anoxic interface. Sulfate reduction rates from modelled diagenesis of organic carbon fluxes agree with other measured rates. A box model summarizes sulfur cycling between water column and sediments. An algal sulfur compound, dimethylsulfoniopropionate (DMSP), precursor to dimethylsulfide (DMS), was measured in deep-sea particle fluxes. DMSP levels in particle fluxes vary seasonally and between oceans. Though DMSP is only 0.005% of organic carbon fluxes, its removal to the deep sea by fluxes may lessen sea-air DMS fluxes. A DMSP-DMS cycle for ocean and sediments is proposed. A third study compared bacteria biomass and morphology in particle fluxes and water column, using TEM and epifluorescence microscopy. Some bacteria had intracellular structures indicating autotrophy. Concentrations in particle fluxes were high compared to sediment bacteria populations elsewhere, but bacterial carbon is a tiny fraction of total organic carbon. In contrast, phototrophic bacteria dominated a microbial mat in a salt marsh where sulfate reduction is important. Cyanobacteria, purple and green sulfur bacteria species were strongly depth-zoned, and cell sizes decreased as depth increased. Also investigated was spatiotemporal change in a fossil lingulid brachiopod from a suboxic facies, using gradient analyses of benthic invertebrate and planktonic graptolite assemblages.
- Research Organization:
- Cornell Univ., Ithaca, NY (United States)
- OSTI ID:
- 5430530
- Country of Publication:
- United States
- Language:
- English
Similar Records
Metabolism of methylated sulfur compounds in anoxic salt marsh sediments
Production and fate of methylated sulfur compounds from methionine and dimethylsulfoniopropionate in anoxic salt marsh sediments
Marine microbial production of dimethylsulfide from dissolved dimethylsulfoniopropionate. Ph. D. Thesis
Thesis/Dissertation
·
Tue Dec 31 23:00:00 EST 1985
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OSTI ID:5964111
Production and fate of methylated sulfur compounds from methionine and dimethylsulfoniopropionate in anoxic salt marsh sediments
Journal Article
·
Thu Oct 01 00:00:00 EDT 1987
· Appl. Environ. Microbiol.; (United States)
·
OSTI ID:7160843
Marine microbial production of dimethylsulfide from dissolved dimethylsulfoniopropionate. Ph. D. Thesis
Technical Report
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Sun Jan 31 23:00:00 EST 1993
·
OSTI ID:6148497
Related Subjects
54 ENVIRONMENTAL SCIENCES
540310* -- Environment
Aquatic-- Basic Studies-- (1990-)
AQUATIC ECOSYSTEMS
BIOGEOCHEMISTRY
BLACK SEA
BLACK SHALES
CHALCOGENIDES
CHEMISTRY
DIMETHYL SULFIDE
ECOSYSTEMS
ENVIRONMENTAL TRANSPORT
GEOCHEMISTRY
MARSHES
MASS TRANSFER
ORGANIC COMPOUNDS
ORGANIC SULFUR COMPOUNDS
ROCKS
SEAS
SEDIMENTARY ROCKS
SHALES
SULFIDES
SULFUR COMPOUNDS
SULFUR CYCLE
SURFACE WATERS
WETLANDS
540310* -- Environment
Aquatic-- Basic Studies-- (1990-)
AQUATIC ECOSYSTEMS
BIOGEOCHEMISTRY
BLACK SEA
BLACK SHALES
CHALCOGENIDES
CHEMISTRY
DIMETHYL SULFIDE
ECOSYSTEMS
ENVIRONMENTAL TRANSPORT
GEOCHEMISTRY
MARSHES
MASS TRANSFER
ORGANIC COMPOUNDS
ORGANIC SULFUR COMPOUNDS
ROCKS
SEAS
SEDIMENTARY ROCKS
SHALES
SULFIDES
SULFUR COMPOUNDS
SULFUR CYCLE
SURFACE WATERS
WETLANDS