Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Coastal Heritage

The South Carolina Sea Grant Consortium publishes Coastal Heritage, a quarterly publication that covers environmental policy, science, history, and culture.

Giant magnetofossils and hyperthermal events

Magnetotactic bacteria biomineralize magnetic minerals with precisely controlled size, morphology, and stoichiometry. These cosmopolitan bacteria are widely observed in aquatic environments. If preserved after burial, the inorganic remains of magnetotactic bacteria act as magnetofossils that record ancient geomagnetic field variations. They also have potential to provide paleoenvironmental information. In contrast to conventional magnetofossils, giant magnetofossils (most likely produced by eukaryotic organisms) have only been reported once before from Paleocene-Eocene Thermal Maximum (PETM; 55.8 Ma) sediments on the New Jersey coastal plain. Here, using transmission electron microscopic observations, we present evidence for abundant giant magnetofossils, including previously reported elongated prisms and spindles, and new giant bullet-shaped magnetite crystals, in the Southern Ocean near Antarctica, not only during the PETM, but also shortly before and after the PETM. Moreover, we have discovered giant bullet-shaped magnetite crystals from the equatorial Indian Ocean during the Mid-Eocene Climatic Optimum (similar to 40 Ma). Our results indicate a more widespread geographic, environmental, and temporal distribution of giant magnetofossils in the geological record with a link to "hyperthermal" events. Enhanced global weathering during hyperthermals, and expanded suboxic diagenetic environments, probably provided more bioavailable iron that enabled biomineralization of giant magnetofossils. Our micromagnetic modelling indicates the presence of magnetic multi-domain (i.e., not ideal for navigation) and single domain (i.e., ideal for navigation) structures in the giant magnetite particles depending on their size, morphology and spatial arrangement. Different giant magnetite crystal morphologies appear to have had different biological functions, including magnetotaxis and other non-navigational purposes. Our observations suggest that hyperthermals provided ideal conditions for giant magnetofossils, and that these organisms were globally distributed. Much more work is needed to understand the interplay between magnetofossil morphology, climate, nutrient availability, and environmental variability.

Age and strontium isotope composition for Cretaceous in DSDP Hole 74-525

Firm stratigraphic correlations are needed to evaluate the global significance of unconformity bounded units (sequences). We correlate the well-developed uppermost Campanian and Maestrichtian sequences of the New Jersey Coastal Plain to the geomagnetic polarity time scale (GPTS) by integrating Sr-isotopic stratigraphy and biostratigraphy. To do this, we developed a Maestrichtian (ca. 73-65 Ma) Sr-isotopic reference section at Deep Sea Drilling Project Hole 525A in the southeastern Atlantic Ocean. Maestrichtian strata can then be dated by measuring their 87Sr/86Sr composition, calibrating to the GPTS of S. C. Cande and D. V. Kent (1993, personal commun.), and using the equation Age (Ma) = 37326.894-52639.89 (87Sr/86Sr). Sr-stratigraphic resolution for the Maestrichtian is estimated as +-1.2 to +-2 m.y. At least two unconformity-bounded units comprise the uppermost Campanian to Maestrichtian strata in New Jersey. The lower one, the Marshalltown sequence, is assigned to calcareous nannofossil Zones CC20/21 (~NC19) and CC22b (~NC20). It ranges in age from ~74.1 to 69.9 Ma based on Sr-isotope age estimates. The overlying Navesink sequence is assigned to calcareous nannoplankton Zones CC25-26 (~NC21-23); it ranges in age from 69.3 to 65 Ma based on Sr-isotope age estimates. The upper part of this sequence, the Tinton Formation, has no calcareous planktonic control; Sr-isotopes provide an age estimate of 66 +- 1.2 Ma (latest Maestrichtian). Sequence boundaries at the base and the top of the Marshalltown sequence match boundaries elsewhere in the Atlantic Coastal Plain (Owens and Gohn, 1985) and the inferred global sea-level record of Haq et al. (1987); they support eustatic changes as the mechanism controlling depositional history of this sequence. However, the latest Maestrichtian record in New Jersey does not agree with Haq et al. (1987); we attribute this to correlation and time-scale differences near the Cretaceous/Paleogene boundary. High sedimentation rates in the latest Maestrichtian of New Jersey (Shrewsbury Member of the Red Bank Formation and the Tinton Formation) suggest tectonic uplift and/or rapid progradation during deposition of the highstand systems tract.