| NSF Org: |
OCE Division Of Ocean Sciences |
| Recipient: |
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| Initial Amendment Date: | March 3, 2017 |
| Latest Amendment Date: | May 24, 2022 |
| Award Number: | 1658042 |
| Award Instrument: | Standard Grant |
| Program Manager: |
Henrietta Edmonds
hedmonds@nsf.gov (703)292-7427 OCE Division Of Ocean Sciences GEO Directorate for Geosciences |
| Start Date: | July 1, 2017 |
| End Date: | June 30, 2023 (Estimated) |
| Total Intended Award Amount: | $221,390.00 |
| Total Awarded Amount to Date: | $221,390.00 |
| Funds Obligated to Date: |
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| History of Investigator: |
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| Recipient Sponsored Research Office: |
910 GENESEE ST ROCHESTER NY US 14611-3847 (585)275-4031 |
| Sponsor Congressional District: |
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| Primary Place of Performance: |
518 Hylan Drive Rochester NY US 14627-0140 |
| Primary Place of
Performance Congressional District: |
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| Unique Entity Identifier (UEI): |
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| Parent UEI: |
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| NSF Program(s): | Chemical Oceanography |
| Primary Program Source: |
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| Program Reference Code(s): | |
| Program Element Code(s): |
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| Award Agency Code: | 4900 |
| Fund Agency Code: | 4900 |
| Assistance Listing Number(s): | 47.050 |
ABSTRACT
Tiny marine organisms called phytoplankton play a critical role in Earth's climate, by absorbing carbon dioxide from the atmosphere. In order to grow, these phytoplankton require nutrients that are dissolved in seawater. One of the rarest and most important of these nutrients is iron. Even though it is a critical life-sustaining nutrient, oceanographers still do not know much about how iron gets into the ocean, or how it is removed from seawater. In the past few years, scientists have made many thousands of measurements of the amount of dissolved iron in seawater, in environments ranging from the deep sea, to the Arctic, to the tropical oceans. They found that the amount of iron in seawater varies dramatically from place to place. Can this data tell us about how iron gets into the ocean, and how it is ultimately removed? Yes. In this project, scientists working on making measurements of iron in seawater will come together with scientists who are working on computer models of iron inputs and removal in the ocean. The goal is to work together to create a program that allows our computer models to "learn" from the data, much like an Artificial Intelligence program. This program will develop a "best estimate" of where and how much iron is coming into the ocean, how long it stays in the ocean, and ultimately how it gets removed. This will lead to a better understanding of how climate change will impact the delivery of iron to the ocean, and how phytoplankton will respond to climate change. With better climate models, society can make more informed decisions about how to respond to climate change. The study will also benefit a future generation of scientists, by training graduate students in a unique collaboration between scientists making seawater measurements, and those using computer models to interpret those measurements. Finally, the project aims to increase the participation of minority and low-income students in STEM (Science, Technology, Engineering, and Mathematics) research, through targeted outreach programs.
Iron (Fe) is an important micronutrient for marine phytoplankton that limits primary productivity over much of the ocean; however, the major fluxes in the marine Fe cycle remain poorly quantified. Ocean models that attempt to synthesize our understanding of Fe biogeochemistry predict widely different Fe inputs to the ocean, and are often unable to capture first-order features of the Fe distribution. The proposed work aims to resolve these problems using data assimilation (inverse) methods to "teach" the widely used Biogeochemical Elemental Cycling (BEC) model how to better represent Fe sources, sinks, and cycling processes. This will be achieved by implementing BEC in the efficient Ocean Circulation Inverse Model and expanding it to simulate the cycling of additional tracers that constrain unique aspects of the Fe cycle, including aluminum, thorium, helium and Fe isotopes. In this framework, the inverse model can rapidly explore alternative representations of Fe-cycling processes, guided by new high-quality observations made possible in large part by the GEOTRACES program. The work will be the most concerted effort to date to synthesize these rich datasets into a realistic and mechanistic model of the marine Fe cycle. In addition, it will lead to a stronger consensus on the magnitude of fluxes in the marine Fe budget, and their relative importance in controlling Fe limitation of marine ecosystems, which are areas of active debate. It will guide future observational efforts, by identifying factors that are still poorly constrained, or regions of the ocean where new data will dramatically reduce remaining uncertainties and allow new robust predictions of Fe cycling under future climate change scenarios to be made, ultimately improving climate change predictions. A broader impact of this work on the scientific community will be the development of a fast, portable, and flexible global model of trace element cycling, designed to allow non-modelers to test hypotheses and visualize the effects of different processes on trace metal distributions. The research will also support the training of graduate students, and outreach to low-income and minority students in local school districts.
PUBLICATIONS PRODUCED AS A RESULT OF THIS RESEARCH
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PROJECT OUTCOMES REPORT
Disclaimer
This Project Outcomes Report for the General Public is displayed verbatim as submitted by the Principal Investigator (PI) for this award. Any opinions, findings, and conclusions or recommendations expressed in this Report are those of the PI and do not necessarily reflect the views of the National Science Foundation; NSF has not approved or endorsed its content.
The purpose of this research was to build computer models to help us understand the cycling of iron (Fe) in the global ocean. Fe is an important nutrient required by phytoplankton (algae) that grow in ocean surface waters and extract carbon dioxide from the atmosphere. However, the processes that supply iron to the surface ocean remain poorly understood. Iron inputs to the ocean from atmospheric dust, seafloor sediments, and hydrothermal vents, are difficult to quantify, as is the timescale of iron removal from seawater due to its tendancy to stick to sinking organic detritus.
Our computer models were designed to teach us about the ocean Fe cycle by determining the balance of processes required to explain a growing database of Fe concentration measurements, as well as measurements of other "complementary" trace elements. These elements often share some sources and sinks with Fe, but otherwise exhibit simpler cycling behavior than Fe, which has complicated chemistry and biological functions. Our computer models were designed to be fast and efficient enought to run very quickly, allowing thousands of simulations to determine the processes that best explain the data.
By modeling the oceanic aluminum (Al) dustribution, we learned important lessons about the supply of trace elements from dust: almost half of the global source is focused in the Atlantic Ocean downwind of the Sahara Desert, and the trace element supply to remote regions of the ocean is buffered by the enhanced solubility of dust that has undergone chemical processing in the atmosphere. The total supply of Fe to the ocean from dust was found to be at the low end of previous estimates, and falls short of the biological Fe demand in most of the ocean (Fig. 1). By modeling isotopes of the element thorium, we learned that physical stirring ("resuspension") of seafloor sediments acts as a major source of trace elements to the water column, especially in regions where sandy sediments accumulate rapidly at the seafloor, due to sediment inputs from land. We estimates that iron inputs from this mechanism are larger than previously recognized, and combined with other sedimentary processes make the seafloor the largest single source of Fe to the ocean. By modeling the trace metal zinc (Zn), we learned about the role of sinking organic detritus in redistribution trace elements through the water column, by collecting molecules near the surface and releasing them at depth after the particles sink - a set of processes referred to as "reversible scavenging".
Additional work led by our collaborators examined the pathways of Fe transport from hydrothermal vents towards the ocean surface, and concluded that the majority of this hydrothermal Fe is trapped in the deep ocean due to the reversible scavenging process, rather than emerging at the ocean surface. Taken together, all of our results paint a picture of the ocean Fe cycle in which sediments are the dominant source to the ocean as a whole, but atmospheric dust plays an outsized role in supplying Fe to surface ocean ecosystems, because Fe supplied from sediments and vents is efficiently scavenged before reaching the surface. We estimate the oceanic lifetime of Fe to be 15-45 years (Fig. 2), towards the low end of previous estimates.
Broader impacts of this project include: (1) The development of a simple modeling framework that has been made widely available to the scientific community to help interpret datasets and test hypotheses; (2) Training of a graduate student, who was supported through most of her Ph.D. by this award; (3) Development of teaching materials for oceanography classes at the University of Rochester; (4) Development of an outreach workshop focused on ocean chemistry and climate change, offered twice to high school students from the low-income Rochester City Schools District.
Last Modified: 11/16/2023
Modified by: Thomas S Weber
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