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Crevassed Thwaites ice (Credit: NASA / J. Yungel)

Press release Glacial engineering could limit sea-level rise, if we get our emissions under control

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European Geosciences Union

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Glacial engineering could limit sea-level rise, if we get our emissions under control

20 September 2018

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Targeted engineering projects to hold off glacier melting could slow down the collapse of ice sheets and limit sea-level rise, according to a new study published in the European Geosciences Union journal The Cryosphere. While an intervention similar in size to existing large civil engineering projects could only have a 30% chance of success, a larger project would have better odds of holding off ice-sheet collapse. But study authors Michael Wolovick and John Moore caution that reducing emissions still remains key to stopping climate change and its dramatic effects.

“Doing geoengineering means often considering the unthinkable,” says Moore, a scientist at Beijing Normal University, China, and a professor of climate change at the University of Lapland, Finland. The term ‘geoengineering’ is usually applied to large-scale interventions to combat climate change. But instead of trying to change the entire climate, Wolovick and Moore say we could apply a more targeted approach to limit one of the most drastic consequences of climate change: sea-level rise.

Their “unthinkable” idea is glacial geoengineering: making changes to the geometry of the seafloor near glaciers that flow into the ocean, forming an ice shelf, to prevent them from melting further. Some glaciers, such as the Britain- or Florida-sized Thwaites ice stream in West Antarctica, are retreating fast. “Thwaites could easily trigger a runaway [West Antarctic] ice sheet collapse that would ultimately raise global sea level by about 3 metres,” explains Wolovick, a researcher at Princeton University’s Department of Geosciences, US. This could have dramatic effects to the millions of people living in the world’s coastal areas.

Instead of, or in addition to, limiting the effects of rising seas through traditional coastal protection, using glacier geoengineering to stop the flood at the source could be a viable option, as Wolovick and Moore show. “The most important result [of our study] is that a meaningful ice sheet intervention is broadly within the order of magnitude of plausible human achievements,” says Wolovick.

The team looked into two glacial-geoengineering designs. One idea would be to build a wall underwater to block warm water reaching an ice shelf’s base, which is very sensitive to melting. A simpler design consists of constructing artificial mounds or columns on the seafloor: they wouldn’t block warm water but could support and hold back the glacier, helping it regrow. “In either case, we were imagining very simple structures, simply piles of sand or gravel on the ocean floor,” says Wolovick.

The team ran computer models where they applied these designs to Thwaites Glacier in a warming world. Thwaites is projected to be the largest individual source of future sea-level rise and, at 80 to 100 km wide, it’s one of the widest glaciers in the world. “If [glacial geoengineering] works there then we would expect it to work on less challenging glaciers as well,” the authors write in The Cryosphere study.

The research shows that even the simpler design could slow down the rate of sea-level rise, giving more time to coastal societies to adapt to rising waters. The smallest intervention has a 30% probability of preventing a runaway collapse of the West Antarctic Ice Sheet for the foreseeable future, according to the models. This intervention would consist of building isolated 300-metre-high mounds or columns on the seafloor using between 0.1 and 1.5 cubic kilometres of aggregate, depending on the strength of the material. This is similar to the amount of material that was excavated to build the Suez Canal in Egypt (1 cubic kilometre) or used in Dubai’s Palm Islands (0.3 cubic kilometres).

A more sophisticated project, going beyond the scale humanity has attempted so far, would have higher chances of success in avoiding a runaway ice-sheet collapse within the next 1000 years (the time the simulations run for), as well as better odds of causing the ice sheet to regain mass. A small underwater wall blocking about 50% of warm water from reaching the ice shelf base could have 70% chance of succeeding, while larger walls would be even more likely to delay or even stop ice-sheet collapse.

Despite the encouraging results, the scientists say they don’t advocate starting these ambitious projects any time soon. While the simplest design would be similar in scale to existing engineering projects, it would be built in one of Earth’s harshest environments. So, the engineering details still need to be worked out. Nonetheless, the team wanted to see whether glacial geoengineering could work in theory, and wanted to get the scientific community to think about, and improve on, the designs.

“We all understand that we have an urgent professional obligation to determine how much sea level rise society should expect, and how fast that sea level rise is likely to come. However, we would argue that there is also an obligation to try to come up with ways that society could protect itself against a rapid ice-sheet collapse,” says Wolovick.

Ice physics shows glacial geoengineering could work to hold off ice-sheet collapse, but both Wolovick and Moore are adamant that reducing greenhouse-gas emissions remains a priority in the fight against climate change. “There are dishonest elements of society that will try to use our research to argue against the necessity of emissions’ reductions. Our research does not in any way support that interpretation,” they say.

Engineering glaciers would only limit sea-level rise, while reducing emissions could also limit other harmful consequences of climate change, such as ocean acidification, floods, droughts and heat waves. In addition, the team points out that more warming would mean glacial engineering projects would become less feasible and would have lower chances of success. After all, their underwater structures might protect the bottom of the ice shelves, but wouldn’t prevent warm air from eating away the ice at the top.

“The more carbon we emit, the less likely it becomes that the ice sheets will survive in the long term at anything close to their present volume,” Wolovick concludes.

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Please mention the name of the publication (The Cryosphere) if reporting on this story and, if reporting online, include a link to the paper (https://www.the-cryosphere.net/12/2955/2018) or to the journal website (https://www.the-cryosphere.net).

More information

This research is presented in the paper ‘Stopping the flood: could we use targeted geoengineering to mitigate sea level rise?’ published in the EGU open access journal The Cryosphere on 20 September 2018.

Citation: Wolovick, M. J. and Moore, J. C.: Stopping the flood: could we use targeted geoengineering to mitigate sea level rise?, The Cryosphere, 12, 2955–2967, https://doi.org/10.5194/tc-12-2955-2018, 2018.

The study was conducted by Michael J. Wolovick (Princeton University, Princeton, USA) and John C. Moore (Beijing Normal University, Beijing, China and University of Lapland, Finland).

Wolovick was supported under award NA14OAR4320106 from the National Oceanic and Atmospheric Administration, US Department of Commerce. The statements, findings, conclusions and recommendations of the study are those of the authors and do not necessarily reflect the views of the National Oceanic and Atmospheric Administration or the US Department of Commerce. Moore was supported by Chinese MOST grant 2015CB953602.

The European Geosciences Union (EGU) is Europe’s premier geosciences union, dedicated to the pursuit of excellence in the Earth, planetary, and space sciences for the benefit of humanity, worldwide. It is a non-profit interdisciplinary learned association of scientists founded in 2002 with headquarters in Munich, Germany. The EGU publishes a number of diverse scientific journals, which use an innovative open access format, and organises a number of topical meetings, and education and outreach activities. Its annual General Assembly is the largest and most prominent European geosciences event, attracting over 14,000 scientists from all over the world. The meeting’s sessions cover a wide range of topics, including volcanology, planetary exploration, the Earth’s internal structure and atmosphere, climate, energy, and resources. The EGU 2019 General Assembly is taking place in Vienna, Austria, from 7 to 12 April 2019. For information and press registration, please check https://media.egu.eu closer to the time of the meeting, or follow the EGU on Twitter and Facebook.

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The Cryosphere (TC) is an international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are ice sheets and glaciers, planetary ice bodies, permafrost, river and lake ice, seasonal snow cover, sea ice, remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.

Contact

Researchers

Michael Wolovick
Department of Geosciences, Princeton University
Princeton, USA
Email wolovick@princeton.edu

John C. Moore
College of Global Change and Earth System Science, Beijing Normal University, Beijing, China
Arctic Centre, University of Lapland, Finland
Phone +358 400194850
Email john.moore.bnu@gmail.com

Press officer

Bárbara Ferreira
EGU Media and Communications Manager
Munich, Germany
Phone +49-89-2180-6703
Email media@egu.eu
X @EuroGeosciences

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