Keeping global warming well below 2°C will require an almost complete decarbonization of the global economy by the 2050s. This in itself is a herculean effort, but the challenge is even greater: in addition to phasing out fossil fuels, hundreds of gigatons of CO2 must be pulled out of the atmosphere and permanently stored in safe reservoirs. To achieve this, many “carbon dioxide removal” or “negative emission technologies (NETS)” have been proposed; however, it is currently unclear which NETs could be operated cost-effectively and in a sustainable way.
While early NET research has focused predominantly on terrestrial-based NETs, ocean-based NETs (ONETs) are gaining increasing attention. ONETs comprise methods to enhance natural oceanic CO2 sinks (e.g., ocean fertilization) or engineered isolation of CO2 with subsequent storage in some reservoir, e.g., the deep ocean or under the seafloor. ONETs may have significant co-benefits and/or risks for the Earth system and human societies. These must be identified and evaluated before applications can start. Furthermore, their application will inevitably have major costs and logistical issues as well as ethical, legal, and political challenges.
Here, we initiate the first article collection on theoretical, environmental, economic, legal, governmental, and ethical aspects of ocean-based negative emission technologies for climate mitigation. Our multidisciplinary collection aims to initiate and catalyze a new branch in marine research that will help to guide post-Paris climate policy and will therefore be vital for the Earth’s future.
As such, this Research Topic will focus on a variety of technologies and methodologies including, but not limited to:
• Ocean alkalinity enhancement
• Blue carbon sink enhancement
• Macroalgae mariculture for carbon removal methodologies (e.g., utilizing the biomass to create bioenergy with carbon capture and storage, BECCS, or for biochar)
• Ocean fertilization
• Direct removal of CO2 from seawater (with storage)
• Artificial upwelling or downwelling
• Biochar additions to marine environments
Keeping global warming well below 2°C will require an almost complete decarbonization of the global economy by the 2050s. This in itself is a herculean effort, but the challenge is even greater: in addition to phasing out fossil fuels, hundreds of gigatons of CO2 must be pulled out of the atmosphere and permanently stored in safe reservoirs. To achieve this, many “carbon dioxide removal” or “negative emission technologies (NETS)” have been proposed; however, it is currently unclear which NETs could be operated cost-effectively and in a sustainable way.
While early NET research has focused predominantly on terrestrial-based NETs, ocean-based NETs (ONETs) are gaining increasing attention. ONETs comprise methods to enhance natural oceanic CO2 sinks (e.g., ocean fertilization) or engineered isolation of CO2 with subsequent storage in some reservoir, e.g., the deep ocean or under the seafloor. ONETs may have significant co-benefits and/or risks for the Earth system and human societies. These must be identified and evaluated before applications can start. Furthermore, their application will inevitably have major costs and logistical issues as well as ethical, legal, and political challenges.
Here, we initiate the first article collection on theoretical, environmental, economic, legal, governmental, and ethical aspects of ocean-based negative emission technologies for climate mitigation. Our multidisciplinary collection aims to initiate and catalyze a new branch in marine research that will help to guide post-Paris climate policy and will therefore be vital for the Earth’s future.
As such, this Research Topic will focus on a variety of technologies and methodologies including, but not limited to:
• Ocean alkalinity enhancement
• Blue carbon sink enhancement
• Macroalgae mariculture for carbon removal methodologies (e.g., utilizing the biomass to create bioenergy with carbon capture and storage, BECCS, or for biochar)
• Ocean fertilization
• Direct removal of CO2 from seawater (with storage)
• Artificial upwelling or downwelling
• Biochar additions to marine environments