Your search keyword '"Frantz, Carie M."' showing total 11 results

1. Toxic elements in benthic lacustrine sediments of Utah's Great Salt Lake following a historic low in elevation.

Author

Jung, Julie, Frantz, Carie M., Fernandez, Diego P., and Werner, Michael S.

Subjects

INDUCTIVELY coupled plasma mass spectrometry, ENDORHEIC lakes, LEAD, COPPER, HEAVY metals, ARSENIC

Abstract

Terminal lakes (without outflow) retain elements and compounds that reach them through fluvial, point source or atmospheric deposition. If the lake sediment is exposed, some of these chemicals could become toxic dust particulates. The Great Salt Lake (GSL) in Utah is a terminal lake that experienced record-low lake elevation in 2021-22, exposing vast areas of playa. Here, we used inductively coupled plasma mass spectrometry to analyze the environmental chemistry of GSL shallow sediment during historic lows in spring, summer, and fall of 2021. Contaminants at the subsurface interface are most able to influence diffusion into the water column and uptake by benthic biota. We focused our analysis on copper, thallium, arsenic, mercury, lead, and zinc, which have been historically deposited in this region and are toxic when at high concentrations. We compared records of regional mining activity to understand the current contamination and assess relevant spatial and temporal gradients. We also used two different extraction methods (EPA 3050b and NH4AcO at pH=7) that can distinguish "environmentally available" vs. tightly associated and less available fractions. We observed consistent concentration of copper across sites indicating a larger relative impact of atmospheric deposition, with some evidence indicating further impacts of point sources. Arsenic, on the other hand, is maintained at high levels in submerged sediments and is likely geologically-and fluvially- derived. Thallium and mercury fluctuate seasonally and correlate with lake elevation. Lead and zinc levels are relatively low in GSL sites compared with freshwater input sites, indicating the deep brine layer may sequester these heavy metals, preventing their release into the water column. Overall, the concentrations of most metals in GSL sediments have declined from historic highs. However, each contaminant has distinct sources, seasonality, mobility and transmission. Complete recovery (if possible) may require many more decades and individual remediation strategies. [ABSTRACT FROM AUTHOR]

Published

2024

2. Primary to post‐depositional microbial controls on the stable and clumped isotope record of shoreline sediments at Fayetteville Green Lake.

Author

Leapaldt, Hanna C., Frantz, Carie M., Olsen‐Valdez, Juliana, Snell, Kathryn E., Trower, Elizabeth J., and Ingalls, Miquela

Subjects

*MICROBIOLOGICAL chemistry, *LAKE sediments, *CARBON isotopes, *COMPOSITION of sediments, *ISOTOPE geology

Abstract

Lacustrine carbonates are a powerful archive of paleoenvironmental information but are susceptible to post‐depositional alteration. Microbial metabolisms can drive such alteration by changing carbonate saturation in situ, thereby driving dissolution or precipitation. The net impact these microbial processes have on the primary δ18O, δ13C, and Δ47 values of lacustrine carbonate is not fully known. We studied the evolution of microbial community structure and the porewater and sediment geochemistry in the upper ~30 cm of sediment from two shoreline sites at Green Lake, Fayetteville, NY over 2 years of seasonal sampling. We linked seasonal and depth‐based changes of porewater carbonate chemistry to microbial community composition, in situ carbon cycling (using δ13C values of carbonate, dissolved inorganic carbon (DIC), and organic matter), and dominant allochems and facies. We interpret that microbial processes are a dominant control on carbon cycling within the sediment, affecting porewater DIC, aqueous carbon chemistry, and carbonate carbon and clumped isotope geochemistry. Across all seasons and sites, microbial organic matter remineralization lowers the δ13C of the porewater DIC. Elevated carbonate saturation states in the sediment porewaters (Ω > 3) were attributed to microbes from groups capable of sulfate reduction, which were abundant in the sediment below 5 cm depth. The nearshore carbonate sediments at Green Lake are mainly composed of microbialite intraclasts/oncoids, charophytes, larger calcite crystals, and authigenic micrite—each with a different origin. Authigenic micrite is interpreted to have precipitated in situ from the supersaturated porewaters from microbial metabolism. The stable carbon isotope values (δ13Ccarb) and clumped isotope values (Δ47) of bulk carbonate sediments from the same depth horizons and site varied depending on both the sampling season and the specific location within a site, indicating localized (μm to mm) controls on carbon and clumped isotope values. Our results suggest that biological processes are a dominant control on carbon chemistry within the sedimentary subsurface of the shorelines of Green Lake, from actively forming microbialites to pore space organic matter remineralization and micrite authigenesis. A combination of biological activity, hydrologic balance, and allochem composition of the sediments set the stable carbon, oxygen, and clumped isotope signals preserved by the Green Lake carbonate sediments. [ABSTRACT FROM AUTHOR]

Published

2024

3. Stromatolites in Walker Lake (Nevada, Great Basin, USA) record climate and lake level changes ~ 35,000 years ago

Author

Petryshyn, Victoria A., Juarez Rivera, Marisol, Agić, Heda, Frantz, Carie M., Corsetti, Frank A., and Tripati, Aradhna E.

Published

2016

4. Desiccation of ecosystem-critical microbialites in the shrinking Great Salt Lake, Utah (USA)

Author

Frantz, Carie M., primary, Gibby, Cecilia, additional, Nilson, Rebekah, additional, Nguyen, Maggie, additional, Ellsworth, Cody, additional, Stern, Cole J., additional, Dolan, Hank, additional, Sihapanya, Alvin, additional, and Baxter, Bonnie K., additional

Published

2023

5. Dramatic local environmental change during the Early Eocene Climatic Optimum detected using high resolution chemical analyses of Green River Formation stromatolites

Author

Frantz, Carie M., Petryshyn, Victoria A., Marenco, Pedro J., Tripati, Aradhna, Berelson, William M., and Corsetti, Frank A.

Published

2014

6. Lake level controls the recurrence of giant stromatolite facies

Author

Ingalls, Miquela, primary, Fetrow, Anne C., additional, Snell, Kathryn E., additional, Frantz, Carie M., additional, and Trower, Elizabeth J., additional

Published

2022

7. Carbonate facies‐specific stable isotope data record climate, hydrology, and microbial communities in Great Salt Lake, UT

Author

Ingalls, Miquela, primary, Frantz, Carie M., additional, Snell, Kathryn E., additional, and Trower, Elizabeth J., additional

Published

2020

8. Physical and optical characteristics of heavily melted “rotten” Arctic sea ice

Author

Frantz, Carie M., primary, Light, Bonnie, additional, Farley, Samuel M., additional, Carpenter, Shelly, additional, Lieblappen, Ross, additional, Courville, Zoe, additional, Orellana, Mónica V., additional, and Junge, Karen, additional

Published

2019

9. Magnetic susceptibility as a biosignature in stromatolites

Author

Petryshyn, Victoria A., Corsetti, Frank A., Frantz, Carie M., Lund, Steve P., and Berelson, William M.

Published

2016

10. RESEARCH FOCUS: They might be Giants: Colossal lacustrine stromatolites

Author

Frantz, Carie M., primary

Published

2015

11. They might be Giants: Colossal lacustrine stromatolites.

Author

Frantz, Carie M.

Subjects

*STROMATOLITES, *SEDIMENTARY structures, *GEOLOGICAL formations, *PALEOENVIRONMENTAL studies, *EOCENE Epoch

Abstract

The article discusses a study which describes the giant stromatolites that occur in the Green River Formation deposited in alkaline lakes that covered much of Wyoming, Colorado and Utah for several million years in the Eocene. Topics covered include a description of stromatolites and other microbialites from a paleontologic and astrobiologic perspective, the different properties of stromatolites that are critical to oil recovery, and stromatolites as paleoenvironmental records.

Published

2015