Age model built from planktic foraminifera radiocarbon in the eastern Pacific during the last deglaciation determined from core MAZ-1E-04 collected on cruise MAZ-I aboard the R/V El Puma in April 2015
Project
| Contributors | Affiliation | Role |
|---|---|---|
| Davis, Catherine V. | North Carolina State University (NCSU) | Principal Investigator |
| Glock, Nicolaas | University of Hamburg | Scientist |
| Machain-Castillo, Maria Luisa | Universidad Nacional Autónoma de México (UNAM) | Scientist |
| Ontiveros-Cuadras, Jorge Feliciano | Universidad Nacional Autónoma de México (UNAM) | Scientist |
| Alcorn, Rachel | North Carolina State University (NCSU) | Student |
| Govindankutty menon, Anjaly | University of Hamburg | Student |
| Mickle, Audrey | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Abstract
Please see Alcorn et al. (2026) for a more detailed methodology.
Core MAZ-1E-04 (MAZ-I E04G) was collected on the oceanographic cruise MAZ-I aboard the R/V "El Puma" on April 28, 2015 using a gravity corer.
Two batches of mixed planktic foraminifera from the >150 µm size fraction were sent to the National Ocean Sciences Accelerator Mass Spectrometry Facility (NOSAMS) for analysis. A third batch was analyzed at the Alfred Wegener Institute using their Mini Carbon Dating System. Planktic 14C ages were corrected to atmospheric 14C ages by subtracting Marine Reservoir Ages (MRAs) from the planktic ages. The MRA corrections are reported from previous literature near our site (Butzin et al., 2020). The MRA-corrected planktic 14C ages were then calibrated against the IntCal20 curve using the Bchron software package (Haslett & Parnell, 2008). Midpoints of the 13 calibrated planktic 14C ages were used to create this core’s age-depth model using Bchron’s Bchronology function.
Planktic 14C ages were corrected to atmospheric 14C ages by subtracting Marine Reservoir Ages (MRAs) from the planktic ages. The MRA corrections are reported from previous literature close to our core (Butzin et al., 2020). The MRA-corrected planktic 14C ages were then calibrated against the IntCal20 curve using the Bchron software package (Haslett & Parnell, 2008). Midpoints of the 13 calibrated planktic 14C ages were used to create this core’s age-depth model using Bchron’s Bchronology function.
- Loaded sheet 1 from "Supplementary Table S3.xlsx" using filename as resource name; treated "nd" and empty strings as missing values
- Renamed fields: Depth (cm) to Depth_core, Mean Age (ybp) to Mean_Age, 1 SD to Age_model_1_SD
- Exported file as "991455_v1_age_model.csv"
| File |
|---|
991455_v1_age_model.csv (Comma Separated Values (.csv), 7.07 KB) MD5:9b7338a00932d87a5f081eaf9da7a218 Primary data file for dataset ID 991455, version 1 |
Relationship Description: Analysis of same sampling events
Relationship Description: Analysis of same sampling events
Relationship Description: Analysis of same sampling events
Relationship Description: Analysis of same sampling events
Relationship Description: Analysis of same sampling events
| Parameter | Description | Units |
| Depth_core | Depth in sediment core | centimeter (cm) |
| Mean_Age | Calibrated sediment age in years before present | years before present (yr BP) |
| Age_model_1_SD | Age model standard deviation | years before present (yr BP) |
| Median | Median age | years before present (yr BP) |
| Dataset-specific Instrument Name | Accelerator Mass Spectrometer |
| Generic Instrument Name | Accelerator Mass Spectrometer |
| Dataset-specific Description | Methods Description: Two batches of mixed planktic foraminifera from the >150 µm size fraction were sent to the National Ocean Sciences Accelerator Mass Spectrometry Facility (NOSAMS) for analysis.
Instrument Description: National Ocean Sciences Accelerator Mass Spectrometry Facility- Continuous-Flow AMS System (radiocarbon) |
| Generic Instrument Description | An AMS measures "long-lived radionuclides that occur naturally in our environment. AMS uses a particle accelerator in conjunction with ion sources, large magnets, and detectors to separate out interferences and count single atoms in the presence of 1x1015 (a thousand million million) stable atoms, measuring the mass-to-charge ratio of the products of sample molecule disassociation, atom ionization and ion acceleration." AMS permits ultra low-level measurement of compound concentrations and isotope ratios that traditional alpha-spectrometry cannot provide. More from Purdue University: http://www.physics.purdue.edu/primelab/introduction/ams.html |
| Dataset-specific Instrument Name | Mini Carbon Dating System |
| Generic Instrument Name | Accelerator Mass Spectrometer |
| Dataset-specific Description | Methods Description: A third batch was analyzed at the Alfred Wegener Institute using their Mini Carbon Dating System.
Instrument Description: Alfred Wegener Institute - Mini Carbon Dating System (radiocarbon) |
| Generic Instrument Description | An AMS measures "long-lived radionuclides that occur naturally in our environment. AMS uses a particle accelerator in conjunction with ion sources, large magnets, and detectors to separate out interferences and count single atoms in the presence of 1x1015 (a thousand million million) stable atoms, measuring the mass-to-charge ratio of the products of sample molecule disassociation, atom ionization and ion acceleration." AMS permits ultra low-level measurement of compound concentrations and isotope ratios that traditional alpha-spectrometry cannot provide. More from Purdue University: http://www.physics.purdue.edu/primelab/introduction/ams.html |
| Dataset-specific Instrument Name | gravity corer |
| Generic Instrument Name | Gravity Corer |
| Dataset-specific Description | Core MAZ-1E-04 (MAZ-I E04G) was collected on the oceanographic cruise MAZ-I aboard the R/V "El Puma" on April 28, 2015 using a gravity corer. |
| Generic Instrument Description | The gravity corer allows researchers to sample sediment layers at the bottom of lakes or oceans. The coring device is deployed from the ship and gravity carries it to the seafloor. (http://www.whoi.edu/instruments/viewInstrument.do?id=1079). |
MAZ-I
| Website | |
| Platform | R/V El Puma |
| Start Date | 2015-04-27 |
| End Date | 2015-04-29 |
Glacial-Interglacial Changes in Oxygen Minimum Zones Using Deep-Dwelling, Low-Oxygen Planktic Foraminifera (OMZ forams)
NSF abstract:
Oxygen minimum zones (OMZs) are naturally occurring regions of low oxygen found across large swaths of the ocean at depths of 100 to 1000 meters below the surface. OMZs play an important role in biogeochemical cycling and ecosystem function and any change in the expanse of their low oxygen waters can have far reaching implications for marine life and valuable fisheries resources. Marine oxygenation is variable on multiple timescales in response to global climate change, with recent observations showing that OMZs have expanded over the past half century. This project will explore promising new geochemical and morphologic proxies applicable to low-oxygen environments in the planktic foraminifer Globorotaloides hexagonus, a unicellular calcifying organism whose fossil record in seafloor sediments is well suited to reconstructing past low-oxygen environments in the water column. The project will focus on the extensive OMZ of the eastern tropical Pacific. The first goal is to evaluate and calibrate the targeted measurements for modern G. hexagonus collected live in plankton tows. The second goal is to apply these proxies to fossil specimens in sediment cores to generate records of glacial-Holocene change. The outcomes will be useable proxies for generating records of the OMZ environment, and a better understanding of how a major regional OMZ changed during the most recent period of rapid climate change. Both outcomes represent important progress towards understanding natural oscillations in the OMZ as well as modeling and planning for a changing OMZ in the face of global climate perturbations. The project will provide opportunities for undergraduate researchers as well as support a female early career researcher.
The marine sedimentary record is the most promising archive from which to reconstruct long term marine oxygenation. However, significant limitations exist in the available proxies for low oxygen marine environments. This project aims to address this need by evaluating and applying a range of promising geochemical (trace element and stable isotope) and morphologic (area-density and porosity) proxies relevant to low oxygen environments in the planktic foraminifer Globorotaloides hexagonus. The project will develop viable proxies based on the morphology and geochemistry of G. hexagonus shells previously collected in depth-distributed MOCNESS (Multiple Opening/Closing Net and Environmental Sensing System) tows from the eastern Pacific. The results from this proxy development in modern shells will then be ground-truthed and applied to two already well characterized sediment cores from the Mexican Margin and Panama Basin that span from the Last Glacial Maximum through the Holocene. The sediment records will be used to reconstruct past conditions in the eastern tropical Pacific OMZ, where significant questions about glacial-interglacial oxygenation persist. This research will lead to a more mechanistic understanding of how OMZs respond to climate more broadly.
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |
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