The Paleozoic record is punctuated by multiple, large positive carbon isotope excursions that are expressed regionally if not globally. In younger records, similar excursions are often linked through direct observation to ocean-scale events of enhanced organic carbon burial--typically under well-characterized anoxic conditions. In older sequences, lacking preserved deep seafloor, the nature of oceanic redox on the broad scale can only be surmised through use of geochemical proxies that are typically ground-truthed in younger settings. In particular, our work and that of other researchers has illuminated the great potential of the molybdenum isotope proxy for quantifying global deep-ocean redox, when applied with careful consideration to local oxygen conditions and the basinal Mo inventory.

In this study we expand the concept of an Oceanic Anoxic Event--first defined for episodes of pervasive deep-ocean and epicontinental black shale deposition during the Mesozoic--to address the nature of ocean-scale redox in the Paleozoic. We focus on the Late Cambrian SPICE event (Steptoean Positive Carbon Isotope Excursion), suggested by our preliminary C and S isotope data from shelf carbonates and our geochemical box model to be a prime candidate for an early Paleozoic OAE. The Alum black shale in Sweden shows clear signs of the SPICE excursion in the organic C fraction and evidence for at least local euxinia before, during, and after the event--making it an ideal candidate for Mo isotope analysis. A central goal, then, is to extrapolate the OAE concept to the Paleozoic, which has numerous positive C isotope excursions of varying global expression but little physical evidence for conditions in the deep ocean. We will specifically test whether the SPICE is an OAE. Strongly analogous patterns of C and S isotope behavior, black shale geochemistry, and biotic extinction have been described from the better-known Toarcian event. We therefore seek to compare the shale geochemistry and supporting carbonate proxies for seawater composition for these two intervals to ask: 1) Do Mo isotope records from the Upper Cambrian Alum Shale in Sweden point to the globally expanded anoxia inferred from our high-resolution delta13C and delta34S carbonate data from the United States? 2) Do the SPICE and Toarcian C isotope excursions show analogous Mo isotope and C-S-Fe-trace metal behavior, such that significant new light is shed on the nature of the Cambrian event? 3) Do organic biomarker patterns associated with the SPICE match those observed from the Toarcian OAE, suggesting that euxinia shallowed as its areal extent increased? 4)By analogy, can we extrapolate models for the Toarcian to understand invertebrate extinction patterns in the early Paleozoic, including problematic trilobite extinctions? 5)Using our integrated data for the SPICE as a template, are Paleozoic intervals of pronounced positive delta13C and epicontinental black shale deposition analogous to the OAEs of the Mesozoic? All of these questions will be addressed through collaboration with experts on each time interval and through use of the geochemical proxies that are staples in our combined research groups--specifically Fe speciation, trace metal chemistry (emphasizing Mo), and novel isotope approaches for S, Fe, and Mo.

Broader Impacts. In a sincere effort to extend the impact of this study beyond the Lyons/Anbar research groups, we have designed a two-pronged approach for outreach in the greater Riverside-LA area. First, Lyons/Anbar/Gill will participate during each of the project years in the UCR Mentoring Summer Research Internship Program, whereby students from ethnic groups historically underrepresented in the sciences (particularly the earth sciences) will receive hands-on experience in the two labs. Second, Lyons/Anbar/Gill will work with the Aquarium of the Pacific in Long Beach, CA, to design an exhibit centered on the global epidemic of anthropogenic coastal hypoxia. Happily, the LA area has seen an improvement in its coastal water quality in recent years. Building from this success and lessons learned from the past--including the very deep past--we expect to reach out to the public about the health of coastal environments in an informative, optimistic, and hopefully entertaining way. Given the 1.3 million annual visitors to the aquarium, we are certain our message will spread widely.

Agency
National Science Foundation (NSF)
Institute
Division of Earth Sciences (EAR)
Type
Standard Grant (Standard)
Application #
0719911
Program Officer
Enriqueta Barrera
Project Start
Project End
Budget Start
2007-09-01
Budget End
2010-08-31
Support Year
Fiscal Year
2007
Total Cost
$164,803
Indirect Cost
Name
University of California Riverside
Department
Type
DUNS #
City
Riverside
State
CA
Country
United States
Zip Code
92521