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1. Novel Insights into Ocean Trace Element Cycling from Biogeochemical Models

   https://doi.org/10.5670/oceanog.2024.418  

   Tagliabue, Alessandro; Weber, Thomas (January 2024, Oceanography)

   Ocean biogeochemical models have become critical tools for interpreting trace element and isotope (TEI) distributions observed during the GEOTRACES program and understanding their driving processes. Models stimulate new research questions that cannot be addressed with observations alone, for instance, concerning processes that occur over vast spatial scales and linkages between TEIs and other elemental cycles. A spectrum of modeling approaches has been applied to date, including (1) fully prognostic models that couple TEIs to broader biogeochemical frameworks, (2) simpler element-specific mechanistic models that allow for assimilation of observations, and (3) machine learning models that have no mechanistic underpinning but allow for skillful extrapolation of sparse data. Here, we evaluate the strengths and weaknesses of these approaches and review three sets of novel insights they have facilitated. First, models have advanced our understanding of global-scale micronutrient distributions, and their deviations from macronutrients, in terms of a “ventilation-regeneration-scavenging” balance. Second, models have yielded global-scale estimates of TEI inputs to and losses from the ocean, revealing, for instance, a rapid iron (Fe) cycle with an oceanic residence time on the order of decades. Third, models have identified novel links among various TEI cycling processes and the global ocean carbon cycle, such as tracing the supply of hydrothermally sourced Fe to iron-starved microbial communities in the Southern Ocean. We foresee additional important roles for modeling work in the next stages of trace element research, including synthesizing understanding from the GEOTRACES program in the form of TEI state estimates, and projecting the responses of TEI cycles to global climate change. 

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2. Intercalibration: A Cornerstone of the Success of the GEOTRACES Program

   https://doi.org/10.5670/oceanog.2024.404  

   Aguilar-Islas, Ana; Planquette, Hélène; Lohan, Maeve; Geibert, Walter; Cutter, Gregory (January 2024, Oceanography)

   The international GEOTRACES program was developed to enhance knowledge about the distribution of trace elements and their isotopes (TEIs) in the ocean and to reduce the uncertainty about their sources, sinks, and internal cycling. Recognizing the importance of intercalibration from the outset, GEOTRACES implemented intercalibration efforts early in the program, and consensus materials were generated that included the full range of TEIs dissolved in seawater, in suspended particles, and from aerosols. The GEOTRACES section cruises include “crossover station(s)” that are occupied by two or more sections and whereby all aspects of sample collection, preservation, and processing can be compared and intercalibrated. Once datasets are generated, an international intercalibration committee reviews intercalibration reports and works with the community to address issues and provide intercalibrated data for intermediate data products. This process has resulted in a highly cooperative community that shares advances in protocols to strengthen capacity building and GEOTRACES outcomes, including an unprecedented oceanic atlas of TEIs, with data quality that is state-of-the-art. This article outlines the development and implementation of the successful GEOTRACES intercalibration process. 

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3. A Young Scientist’s Perspective on GEOTRACES

   https://doi.org/10.5670/oceanog.2024.403  

   Halbeisen, Dylan (January 2024, Oceanography)

   GEOTRACES is an international endeavor to elucidate the biogeochemical cycles of trace elements and their isotopes in the ocean. Inherently, this interdisciplinary program provides ample opportunities for students to develop professional, academic, and seagoing skills. This perspective recalls first-hand experiences gained from five years in the GEOTRACES community, spanning undergraduate and graduate research, including international engagement in Germany and seagoing oceanography in the South Pacific and Southern Ocean. Description of these opportunities reveals the framework that makes the GEOTRACES program a success and the culture that will ensure its ongoing legacy. 

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4. Three-Minute Videos to Learn About Marine Geochemistry

   https://doi.org/10.5670/oceanog.2024.401  

   Masferrer_Dodas, Elena; Jeandel, Catherine; Artis, Adrian (January 2024, Oceanography)

   The international GEOTRACES program (https://www.geotraces.org/) is a marine geochemical project involving scientists from more than 35 countries that aims to improve understanding of trace elements and their isotopes in the marine environment (Anderson, 2024, in this issue). However, terms such as trace elements and isotopes can be very challenging concepts to communicate to a non-scientific audience. GEOTRACES scientists face this difficulty when explaining their research to the general public. To overcome it, the GEOTRACES International Project Office launched a series of short (about three minutes) educational videos aimed at introducing and explaining the science of the GEOTRACES program to the general public. These videos explain marine geochemical science and concepts such as trace elements and isotopes in an easy and fun format while keeping the scientific message accurate. They also constitute a powerful teaching resource and offer an accessible and appealing method for students to learn about marine geochemistry. 

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5. New Insights into the Organic Complexation of Bioactive Trace Metals in the Global Ocean from the GEOTRACES Era

   https://doi.org/10.5670/oceanog.2024.419  

   Whitby, Hannah; Park, Jiwoon; Shaked, Yeala; Boiteau, Rene; Buck, Kristen; Bundy, Randelle (May 2024, Oceanography)

   The GEOTRACES program has greatly expanded measurements of dissolved trace metal concentrations across ocean basins, but to understand the behavior and cycling of metals and their impacts on primary productivity, we must understand the chemical forms in which they are present in the environment. Organic ligands play a central role in the speciation and cycling of trace metals in the marine environment, controlling their chemical reactivity and bioavailability. Here, we present an overview of the contributions the GEOTRACES program has made to understanding ocean metal speciation through advancing our knowledge of the distribution, sources, and sinks of metal-binding organic ligands across the global ocean, particularly for iron. Detailed assessments and intercalibration of the speciation methods most commonly applied have allowed integration of metal-binding ligand measurements across datasets. Work to characterize specific ligand groups within the wider pool of dissolved organic matter, along with their sources and sinks, is starting to unravel the role of metal-binding organic ligands in global biogeochemical cycles. Recent advances in complementary analytical techniques using liquid chromatography and mass spectrometry present a molecular picture of metal speciation and bioavailability—and also pose new questions. Moving forward, we need to address knowledge gaps in our understanding of how metal speciation and complexation relates to bioavailability in order to recognize the impacts of ocean metal distributions and cycling on marine productivity and the global carbon cycle. 

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