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energy.mit.edu
research
https://energy.mit.edu/publication/is-ocean-fertilization-a-good-carbon-seque…
One such approach involves the addition of otherwise scarce (limiting) nutrients to surface ocean waters to manipulate marine biological production, thus
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www2.lbl.gov
official
https://www2.lbl.gov/Science-Articles/Archive/sea-carb-bish.html
The other major approach to sequestration is to "prime the biological pump" by fertilizing the ocean. Near the surface, carbon is fixed by plant-like
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scor-int.org
article
https://www.scor-int.org/High-CO2_World/AndyWatson.pdf
• 1988: Fe fertilization proposed as a method of “curing” greenhouse effect (Gribbin, J., Nature 331, 570, 1988) • 1990 Martin suggests iron instrumental in causing lower atmospheric CO2 concentrations in glacial time. • Open ocean diatoms have an Fe-limited C:Fe ~3 x 105 • However, the ratio of phytoplankton C sequestered to Fe added is much lower than this in Iron enrichment experiments: • Ironex II: C:Fe = 3 x 104 (fixed, not necessarily sequestered) • SOIREE: 0.2 - 0.8 x 104 • SOFEX 0.7 x 104 (sequestered below 100m, Buessler etal) • Fe may be used more efficiently – By larger-scale, longer time fertilizations?
E
edf.org
article
https://www.edf.org/sites/default/files/documents/Ocean%20Fertilization.pdf
Page 9 OCEAN CARBON DIOXIDE REMOVAL METHODS NRDC EDF OCEAN CONSERVANCY Ocean Fertilization: At a Glance Marine plants and algae, like phytoplankton, take up CO2 during photosynthesis, and this can increase the ocean’s uptake of atmospheric CO2. 42 Technical Readiness: OF experiments using iron in the 1990s and 2000s confirmed that fertilization does induce phytoplankton blooms and carbon capture, but scientists found that only some of these blooms led to longer-term carbon storage or atmospheric CO2 drawdown beyond already naturally occurring processes. 49 Page 10 OCEAN CARBON DIOXIDE REMOVAL METHODS NRDC EDF OCEAN CONSERVANCY 36 � National Academies of Sciences, Engineering, and Medicine (hereinafter NASEM), A Research Strategy for Ocean-Based Carbon Dioxide Removal and Sequestration (Washington, D.C.: National Academies Press, 2022), https://doi.org/10.17226/26278.
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nature.com
article
https://www.nature.com/articles/s41565-022-01226-w
Artificial ocean fertilization (AOF) aims to safely stimulate phytoplankton growth in the ocean and enhance carbon sequestration.
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whoi.edu
research
https://www.whoi.edu/ocean-learning-hub/ocean-topics/climate-weather/ocean-ba…
Iron fertilization is a Carbon Dioxide Removal (CDR) technique that would artificially add iron to the ocean’s surface to stimulate growth of phytoplankton. When the plume of dust or ash settles over the ocean’s surface, it triggers massive blooms of phytoplankton that remove substantial amounts of carbon dioxide from the atmosphere. Iron fertilization is a Carbon Dioxide Removal (CDR) technique that would mimic this natural system, artificially adding iron to the ocean’s surface to stimulate growth of phytoplankton. If relatively small amounts of iron can be added to the ocean’s surface to effectively remove large amounts of carbon dioxide from the atmosphere, iron fertilization has the potential to play a pivotal role in reducing additional impacts associated with climate change. Until experiments are done to test these potential outcomes and determine how much carbon can be sequestered in the ocean depths, iron fertilization should not be put to use as a method of slowing climate change. ### Fertilizing the Ocean with Iron.
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dosi-project.org
article
https://www.dosi-project.org/wp-content/uploads/Ocean-Fertilization-Policy-Br…
DEEP-OCEAN STEWARDSHIP INITIATIVE Fig. 1 Elements of the biological pump (Fig. 1 From McClain (2010) American Scientist) Deep Ocean Climate Intervention Impacts Deep Ocean Climate Intervention Impacts Ocean Fertilization Key Points DECEMBER 2021 Policy Brief Page 2 DOSI Scaling and Effectiveness The subarctic Northern Pacific, Eastern Equatorial Pacific and Southern Ocean are high-nutrient, low-chlorophyll regions where iron scarcity limits phytoplankton growth, and thus have been proposed for OIF (Yoon et al., 2018, GESAMP, 2019). The alteration of natural phytoplankton communities may result in changes in the seasonality of particulate organic carbon flux to the deep-sea floor (benthic-pelagic coupling) and in compositions of phytoplankton species in the marine snow, potentially impacting deep-sea benthic communities that rely on food from the ocean surface (Billet et al., 1983; Gooday, 1988; Graf, 1989; Ruhl and Smith, 2004; Nomaki et al., 2021).
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naturetechcollective.org
article
https://www.naturetechcollective.org/stories/ocean-iron-fertilization-a-promi…
# Ocean Iron Fertilization: A Promising Path for Carbon Removal? As a marine radiochemist and the director of the non-profit Exploring Ocean Iron Solutions (ExOIS), Dr. Buesseler shared insights on how adding small amounts of iron to the ocean could amplify its natural ability to store carbon, the potential impacts on marine ecosystems, and the path toward responsible research. When scientists compared different climate models' predictions of natural carbon flux in the ocean, the estimates ranged from 5 to 12 billion tons per year. Every marine carbon dioxide removal approach, whether it involves adding minerals, growing seaweed, or fertilizing with iron, will change ocean conditions. We need roughly 5 to 10 billion tons per year of carbon dioxide removal alongside dramatic emissions reductions to address climate change. Ocean iron fertilization might contribute 1 to 2 billion tons annually if deployed widely, though much more research is needed to confirm these estimates and assess full-scale impacts.