Surface Albedo Modification and Arctic Ice Management

Type

Solar Radiation Management

Areas of deployment

Forests and plantations, Arctic ice and glaciers, Urban areas

Proposal

Modifying the surface of the Earth in order to reflect more sunlight back into space.

Featured project

Name: Real Ice Development: Nome & Fort Davis
Location: Alaska, USA

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A wide range of proposals fall within the category of surface albedo modification—from genetically engineering crops to reflect more light, to clearing boreal forests in snow covered areas; from covering large desert or ice areas with reflective materials to whitening mountaintops and roofs with white paint— all with the aim of increasing the Earth’s surface albedo.

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Description and purpose of the technology

Surface Albedo Modification is a theoretical solar geoengineering technique that aims to reflect more sunlight back to space by enhancing albedo—the extent to which sunlight is reflected off a surface. Proposals span a wide range and include growing crops that reflect more light, clearing boreal forests in snow-covered areas, covering large areas of desert or ice with reflective materials and whitening mountaintops and roofs with white paint—all with the common goal of increasing the Earth’s surface albedo. 

Albedo describes how much solar radiation is reflected by a surface. A high albedo means most solar radiation is reflected, for example polar ice sheets. A surface with a low albedo, for example a dark ocean surface, reflects only a relatively small share and absorbs most of the solar radiation in the form of heat, thus warming the surrounding area. 

Creating large surfaces with a higher albedo could increase the amount of solar radiation reflected from the Earth’s surface and could therefore theoretically reduce surface temperatures. However, the proposal would not reduce the concentration of greenhouse gases in the atmosphere, which would continue increasing. In most cases, the unwanted side effects on ecosystems and the human communities that depend on them could be devastating.

Covering areas of ice

This method involves applying a layer of reflective material to Arctic ice as a “reflective band aid,” to insulate rapidly-melting snowpack and glaciers. [1] The California-based Arctic Ice Project (formerly Ice911), founded by Leslie Field in 2007, proposes using a reflective silica glass as a cover material. The material consists mostly of silicon dioxide and comes in the shape of tiny glass spheres. For over a decade now, the project has carried out trials on frozen lakes in Canada and the USA and tested various reflective materials. The project’s largest trial site is the North Meadow Lake, an Indigenous area near Utqiagvik, Alaska.

Although the members of the local community have never been consulted about or consented to the trials, testing at this site commenced in the winter of 2015, and covered up to 17,500m². The Arctic Ice Project also plans to conduct trials on sea ice at the University of Manitoba’s sea ice test facility in Winnipeg, while looking for funding and permission to conduct large-scale testing on Arctic ice. Leslie Field proposed to cover up to 100,000km² with silica glass in selected Arctic regions, e.g. in the Fram Strait or the Beaufort Gyre.

Possible negative effects of this proposal, for example changing weather patterns, changes to the hydrologic cycle and water temperature, or effects on the delicate Arctic ecosystems, and the environmental impact of the covering material itself, have not been considered in depth so far. The community members in the North Meadow Lake area have many concerns about the likely effects of the proposal, including impacts on the food web and on migrating birds by ingestion of the material, or on human health following inhalation of silica dust. [2]

Covering glaciers

A modelling study conducted by researchers at the German Potsdam Institute for Climate Change (PIK) suggested slowing sea level rise by shooting very large amounts of artificial snow onto two glaciers in western Antarctica. PIK has further estimated that more than 12,000 wind turbines would be needed to lift, desalinate and spray this great quantity of water. The entire project would involve ecological devastation on a massive scale with huge disruptions to sensitive Antarctic marine habitats. [3]

A research group at the Swiss Academia Engiadina hopes to save Switzerland’s glaciers with a comparable approach—by blowing reflective artificial snow across their surface. In 2017, the research group conducted a smaller pilot demonstration trial in a section of the Swiss Diavolezzafirn glacier to prove the technology. Further trials will be conducted at the Morteratsch glacier, with funding provided by the Swiss Innovation Agency. The approach requires a very large quantity of water and energy. [4]

Researchers at Ohio State University have proposed covering sections of the Greenland ice sheet with reflective material to prevent glaciers from melting further. In 2009, the proposal was demonstrated by covering an area of two acres with reflective polypropylene blankets. The idea has been adopted from the Alps where white blankets are regularly used by local mountain lift companies to cover glaciers as a reflective shield to protect skiing areas (and ski resort income). The implementation of this proposal means an increased consumption of fossil raw materials and high costs: The polypropylene blanket material is produced from crude oil and the material costs for covering one square kilometer of glacier ice are estimated at US$ 4,6 million. This estimate excludes the costs of recycling at the end of the product’s lifetime. [5]

High albedo crops

Several researchers, particularly a team of researchers at the University of Bristol, UK, have proposed modifying agricultural crops to create plants with more reflective leaves. Proponents claim that if crops with a higher albedo would be grown on farmland, this would help to cool the atmosphere by reflecting more solar radiation back into space. To increase crop albedo, both traditional breeding techniques and genetic engineering have been proposed. [6]

Little is known about the potential risks of increased leaf reflectivity to the nutritional content of plants and their photosynthetic capacity, or to soil health. Similarly, genetically engineered plants could also spread their engineered “reflectivity” characteristic to other relatives, with unknown consequences. Growing genetically modified crops or trees carries all of the biosafety and land use impacts of these cultivations, including soil erosion and heavy use of contaminating agrochemicals.

Snow Forest Clearance 

An international team of researchers modelled the influence of boreal forest areas on the climate and developed the theory that clearing the planet’s remaining areas of boreal forest—north of 45 degrees latitude, largely in Russia and Canada—would have a cooling effect because snow cover reflects solar radiation, whereas boreal forest absorbs most of the radiation. The studies were led by the forestry school at Yale and by Dartmouth college, with partial funding from the US Department of Energy.

The creation of “white deserts” could destroy subarctic ecosystem productivity and negatively affect the plants and people that depend on them, as well as caribou, migrating birds and other species. [7] Eliminating forests would also negatively affect the regulation of regional and local climates, and the carbon contained in the forests would also be lost. Proponents admit that there are many complexities, and that it would also be a one-time, final bonanza for timber companies. [8]

Covering deserts

More than a decade ago, entrepreneur Alvia Gaskill laid out a scheme to cover a significant portion of the world’s deserts with a white, polyethylene film to reflect sunlight and lower surface temperatures. [9]

Deserts have plants, animals and people living in them, and it is difficult to imagine life continuing in a plastic-covered ecosystem. Desert dust, which will be hindered by plastic coverings, is essential for the global climate because it influences solar radiation, cloud formation and even ocean cooling. [10] Cooler desert temperatures may also bring unexpected changes.

Like many geoengineering proponents, Gaskill suggests if there are too many political, ecological or weather-related challenges (the plastic has to be kept in place for several hundred years, for example), the projects could be conducted on a more localized scale. However, local applications would have a minimal climate effect and would not justify the expense and socio-ecological disruption.

Painting roofs, pavements and mountaintops

In 2010, the World Bank awarded a small grant to Glaciares Peru, a company founded by Eduardo Gold, so that he could paint a Peruvian mountaintop white. [11] Painting mountaintops would negatively affect fragile ecosystems, flora and fauna, and seems unlikely to be pursued any further. Urban albedo enhancement—painting surfaces such as roofs and pavements white or adding a reflective layer—has been considered and modelled by various researchers, among them Hashem Akbari of Concordia University in Montreal, who has promoted the idea of government grants to cover rooftops and tarmac with white paint. [12] Several initiatives worldwide have taken up the idea, among them the CoolRoofs Initiative in New York City, which painted 50 hectares of roof surfaces with a bright, reflective coating. [13] Painting roofs could have some local cooling effects, though a Royal Society report states that “the overall cost of a ‘white roof method’ covering an area of 1% of the land surface would cost about US$300 billion/year, making this one of the least effective and most expensive methods considered.” [14] Scientists at Stanford University have suggested that “roofs covered in photovoltaic panels would do a better job, by producing electricity that then obviates the need for more fossil fuel–burning power plants.” [15]

Marine albedo enhancement

There are also proposals to alter the albedo (reflectivity) of water surfaces and of marine clouds. These approaches are detailed in the Technology Briefings on Microbubbles/Sea Foam and Marine Cloud Brightening.

Reality check

So far, most of the approaches described have been based on modelling, but various small-scale trials with reflective materials on ice have been conducted and larger-scale trials are planned. Research into high-albedo crops aligns with global efforts to engineer the world’s food supply, so this idea may gain attention and funding.

All of these proposals are clear examples of the narrow-minded, reductionist mentality that characterizes geoengineering, which ignores the profound value of biodiversity and overlooks the multifunctionality and interconnectedness of ecosystems.

End notes

[1] McGlynn (2017) One big reflective band-aid, in: Berkeley Engineering Blogpost, January 17, 2017, http://engineering.berkeley.edu/2017/01/one-big-reflective-band-aid 

[2] ETC Group and Heinrich Böll Foundation (2020) Geoengineering Map, https://map.geoengineeringmonitor.org; Field, et al. (2018) Increasing Arctic Sea Ice Albedo Using Localized Reversible Geoengineering, in Earth’s Future, Vol. 6(6): 882 – 901, https://doi.org/10.1029/2018EF000820; Jay (2019) Arctic Geoengineering Experiment Is Dangerous, Lacks Community Consent: Inupiaq Organizer, in Geoengineering Monitor, published: February 14, 2019, https://www.geoengineeringmonitor.org/2019/02/arctic-geoengineering-experiment-is-dangerous-lacks-community-consent-inupiaq-organizer/ 

[3] Feldmann, et al. (2019) Stabilizing the West Antarctic Ice Sheet by surface mass deposition, in Science Advances, Vol. 5(7), https://doi.org/10.1126/sciadv.aaw4132; Geoengineering Monitor (2019) Sacrificing Antarctica with geoengineering to save northern cities from the fossil fuel industry?, published: July 19, 2019, https://www.geoengineeringmonitor.org/2019/07/sacrificing-antarctica-with-geoengineering-to-save-northern-cities-from-the-fossil-fuel-industry/; ETC Group and Heinrich Böll Foundation (2020)

[4] ETC Group and Heinrich Böll Foundation (2020)

[5] ETC Group and Heinrich Böll Foundation (2020)

[6] Marshall (2009) Reflective crops could soften climate change blow, in NERC Planet Earth, published: January 20, 2009, http://www.nerc.ac.uk/planetearth/stories/298/; Morton (2009) Crops that cool, in Nature, published: January 15, 2009, https://doi.org/10.1038/news.2009.33; ETC Group and Heinrich Böll Foundation (2020)

[7] Lee, et al. (2011) Observed increase in local cooling effect of deforestation at higher latitudes, in Nature, Vol. 479: 384 – 387, https://doi.org/10.1038/nature10588; Yale University (2011) Deforestation causes cooling, study shows, in Phys.org, published: November 16, 2011, https://phys.org/news/2011-11-deforestation-cooling.html; ETC Group and Heinrich Böll Foundation (2020)

[8] Swaminathan (2007) More Trees, Less Global Warming – Right? Not Exactly, in Scientific American, published: April 10, 2007, https://www.scientificamerican.com/article/tropical-forests-cool-earth/; Walsh (2011) How (Some) Deforestation Might Slow Warming, in: Time, published: November 16, 2011, http://science.time.com/2011/11/16/how-some-deforestation-might-slow-warming/ 

[9] ETC Group and Heinrich Böll Foundation (2020)

[10] Goudie and Middleton (2006) Desert Dust in the Global System, published by Springer, ISBN-10: 3540323546, https://www.springer.com/la/book/9783540323549 

[11] ETC Group and Heinrich Böll Foundation (2020)

[12] Akbari: List of publications, Concordia University, http://concordia.academia.edu/HashemAkbari; Biello (2014) Cool Roofs Might Be Enough to Save Cities from Climate Overheating, in Scientific American, published: February 14, 2014, https://www.scientificamerican.com/article/cool-roofs-might-be-enough-to-save-cities-from-climate-overheating/ 

[13] ETC Group and Heinrich Böll Foundation (2020)

[14] The Royal Society (2009) Geoengineering the climate: Science, governance and uncertainty, ISBN: 978-0-85403-773-5, https://royalsociety.org/~/media/Royal_Society_Content/policy/publications/2009/8693.pdf 

[15] Biello (2014)

Surface Albedo Modification and Arctic Ice Management

TIPO

Solar Radiation Management

Zonas de despliegue

Forests and plantations, Arctic ice and glaciers, Urban areas

Propuesta

Modifying the surface of the Earth in order to reflect more sunlight back into space.

Proyecto destacado

Nombre: Real Ice Development: Nome & Fort Davis
Localización: Alaska, USA

Mostrar en el mapa

A wide range of proposals fall within the category of surface albedo modification—from genetically engineering crops to reflect more light, to clearing boreal forests in snow covered areas; from covering large desert or ice areas with reflective materials to whitening mountaintops and roofs with white paint— all with the aim of increasing the Earth’s surface albedo.

Última actualización de la tecnología

Mostrar actualización

Descripción y propósito de la tecnología

Surface Albedo Modification is a theoretical solar geoengineering technique that aims to reflect more sunlight back to space by enhancing albedo—the extent to which sunlight is reflected off a surface. Proposals span a wide range and include growing crops that reflect more light, clearing boreal forests in snow-covered areas, covering large areas of desert or ice with reflective materials and whitening mountaintops and roofs with white paint—all with the common goal of increasing the Earth’s surface albedo. 

Albedo describes how much solar radiation is reflected by a surface. A high albedo means most solar radiation is reflected, for example polar ice sheets. A surface with a low albedo, for example a dark ocean surface, reflects only a relatively small share and absorbs most of the solar radiation in the form of heat, thus warming the surrounding area. 

Creating large surfaces with a higher albedo could increase the amount of solar radiation reflected from the Earth’s surface and could therefore theoretically reduce surface temperatures. However, the proposal would not reduce the concentration of greenhouse gases in the atmosphere, which would continue increasing. In most cases, the unwanted side effects on ecosystems and the human communities that depend on them could be devastating.

Covering areas of ice

This method involves applying a layer of reflective material to Arctic ice as a “reflective band aid,” to insulate rapidly-melting snowpack and glaciers. [1] The California-based Arctic Ice Project (formerly Ice911), founded by Leslie Field in 2007, proposes using a reflective silica glass as a cover material. The material consists mostly of silicon dioxide and comes in the shape of tiny glass spheres. For over a decade now, the project has carried out trials on frozen lakes in Canada and the USA and tested various reflective materials. The project’s largest trial site is the North Meadow Lake, an Indigenous area near Utqiagvik, Alaska.

Although the members of the local community have never been consulted about or consented to the trials, testing at this site commenced in the winter of 2015, and covered up to 17,500m². The Arctic Ice Project also plans to conduct trials on sea ice at the University of Manitoba’s sea ice test facility in Winnipeg, while looking for funding and permission to conduct large-scale testing on Arctic ice. Leslie Field proposed to cover up to 100,000km² with silica glass in selected Arctic regions, e.g. in the Fram Strait or the Beaufort Gyre.

Possible negative effects of this proposal, for example changing weather patterns, changes to the hydrologic cycle and water temperature, or effects on the delicate Arctic ecosystems, and the environmental impact of the covering material itself, have not been considered in depth so far. The community members in the North Meadow Lake area have many concerns about the likely effects of the proposal, including impacts on the food web and on migrating birds by ingestion of the material, or on human health following inhalation of silica dust. [2]

Covering glaciers

A modelling study conducted by researchers at the German Potsdam Institute for Climate Change (PIK) suggested slowing sea level rise by shooting very large amounts of artificial snow onto two glaciers in western Antarctica. PIK has further estimated that more than 12,000 wind turbines would be needed to lift, desalinate and spray this great quantity of water. The entire project would involve ecological devastation on a massive scale with huge disruptions to sensitive Antarctic marine habitats. [3]

A research group at the Swiss Academia Engiadina hopes to save Switzerland’s glaciers with a comparable approach—by blowing reflective artificial snow across their surface. In 2017, the research group conducted a smaller pilot demonstration trial in a section of the Swiss Diavolezzafirn glacier to prove the technology. Further trials will be conducted at the Morteratsch glacier, with funding provided by the Swiss Innovation Agency. The approach requires a very large quantity of water and energy. [4]

Researchers at Ohio State University have proposed covering sections of the Greenland ice sheet with reflective material to prevent glaciers from melting further. In 2009, the proposal was demonstrated by covering an area of two acres with reflective polypropylene blankets. The idea has been adopted from the Alps where white blankets are regularly used by local mountain lift companies to cover glaciers as a reflective shield to protect skiing areas (and ski resort income). The implementation of this proposal means an increased consumption of fossil raw materials and high costs: The polypropylene blanket material is produced from crude oil and the material costs for covering one square kilometer of glacier ice are estimated at US$ 4,6 million. This estimate excludes the costs of recycling at the end of the product’s lifetime. [5]

High albedo crops

Several researchers, particularly a team of researchers at the University of Bristol, UK, have proposed modifying agricultural crops to create plants with more reflective leaves. Proponents claim that if crops with a higher albedo would be grown on farmland, this would help to cool the atmosphere by reflecting more solar radiation back into space. To increase crop albedo, both traditional breeding techniques and genetic engineering have been proposed. [6]

Little is known about the potential risks of increased leaf reflectivity to the nutritional content of plants and their photosynthetic capacity, or to soil health. Similarly, genetically engineered plants could also spread their engineered “reflectivity” characteristic to other relatives, with unknown consequences. Growing genetically modified crops or trees carries all of the biosafety and land use impacts of these cultivations, including soil erosion and heavy use of contaminating agrochemicals.

Snow Forest Clearance 

An international team of researchers modelled the influence of boreal forest areas on the climate and developed the theory that clearing the planet’s remaining areas of boreal forest—north of 45 degrees latitude, largely in Russia and Canada—would have a cooling effect because snow cover reflects solar radiation, whereas boreal forest absorbs most of the radiation. The studies were led by the forestry school at Yale and by Dartmouth college, with partial funding from the US Department of Energy.

The creation of “white deserts” could destroy subarctic ecosystem productivity and negatively affect the plants and people that depend on them, as well as caribou, migrating birds and other species. [7] Eliminating forests would also negatively affect the regulation of regional and local climates, and the carbon contained in the forests would also be lost. Proponents admit that there are many complexities, and that it would also be a one-time, final bonanza for timber companies. [8]

Covering deserts

More than a decade ago, entrepreneur Alvia Gaskill laid out a scheme to cover a significant portion of the world’s deserts with a white, polyethylene film to reflect sunlight and lower surface temperatures. [9]

Deserts have plants, animals and people living in them, and it is difficult to imagine life continuing in a plastic-covered ecosystem. Desert dust, which will be hindered by plastic coverings, is essential for the global climate because it influences solar radiation, cloud formation and even ocean cooling. [10] Cooler desert temperatures may also bring unexpected changes.

Like many geoengineering proponents, Gaskill suggests if there are too many political, ecological or weather-related challenges (the plastic has to be kept in place for several hundred years, for example), the projects could be conducted on a more localized scale. However, local applications would have a minimal climate effect and would not justify the expense and socio-ecological disruption.

Painting roofs, pavements and mountaintops

In 2010, the World Bank awarded a small grant to Glaciares Peru, a company founded by Eduardo Gold, so that he could paint a Peruvian mountaintop white. [11] Painting mountaintops would negatively affect fragile ecosystems, flora and fauna, and seems unlikely to be pursued any further. Urban albedo enhancement—painting surfaces such as roofs and pavements white or adding a reflective layer—has been considered and modelled by various researchers, among them Hashem Akbari of Concordia University in Montreal, who has promoted the idea of government grants to cover rooftops and tarmac with white paint. [12] Several initiatives worldwide have taken up the idea, among them the CoolRoofs Initiative in New York City, which painted 50 hectares of roof surfaces with a bright, reflective coating. [13] Painting roofs could have some local cooling effects, though a Royal Society report states that “the overall cost of a ‘white roof method’ covering an area of 1% of the land surface would cost about US$300 billion/year, making this one of the least effective and most expensive methods considered.” [14] Scientists at Stanford University have suggested that “roofs covered in photovoltaic panels would do a better job, by producing electricity that then obviates the need for more fossil fuel–burning power plants.” [15]

Marine albedo enhancement

There are also proposals to alter the albedo (reflectivity) of water surfaces and of marine clouds. These approaches are detailed in the Technology Briefings on Microbubbles/Sea Foam and Marine Cloud Brightening.

Visión realista

So far, most of the approaches described have been based on modelling, but various small-scale trials with reflective materials on ice have been conducted and larger-scale trials are planned. Research into high-albedo crops aligns with global efforts to engineer the world’s food supply, so this idea may gain attention and funding.

All of these proposals are clear examples of the narrow-minded, reductionist mentality that characterizes geoengineering, which ignores the profound value of biodiversity and overlooks the multifunctionality and interconnectedness of ecosystems.

Notas finales

[1] McGlynn (2017) One big reflective band-aid, in: Berkeley Engineering Blogpost, January 17, 2017, http://engineering.berkeley.edu/2017/01/one-big-reflective-band-aid 

[2] ETC Group and Heinrich Böll Foundation (2020) Geoengineering Map, https://map.geoengineeringmonitor.org; Field, et al. (2018) Increasing Arctic Sea Ice Albedo Using Localized Reversible Geoengineering, in Earth’s Future, Vol. 6(6): 882 – 901, https://doi.org/10.1029/2018EF000820; Jay (2019) Arctic Geoengineering Experiment Is Dangerous, Lacks Community Consent: Inupiaq Organizer, in Geoengineering Monitor, published: February 14, 2019, https://www.geoengineeringmonitor.org/2019/02/arctic-geoengineering-experiment-is-dangerous-lacks-community-consent-inupiaq-organizer/ 

[3] Feldmann, et al. (2019) Stabilizing the West Antarctic Ice Sheet by surface mass deposition, in Science Advances, Vol. 5(7), https://doi.org/10.1126/sciadv.aaw4132; Geoengineering Monitor (2019) Sacrificing Antarctica with geoengineering to save northern cities from the fossil fuel industry?, published: July 19, 2019, https://www.geoengineeringmonitor.org/2019/07/sacrificing-antarctica-with-geoengineering-to-save-northern-cities-from-the-fossil-fuel-industry/; ETC Group and Heinrich Böll Foundation (2020)

[4] ETC Group and Heinrich Böll Foundation (2020)

[5] ETC Group and Heinrich Böll Foundation (2020)

[6] Marshall (2009) Reflective crops could soften climate change blow, in NERC Planet Earth, published: January 20, 2009, http://www.nerc.ac.uk/planetearth/stories/298/; Morton (2009) Crops that cool, in Nature, published: January 15, 2009, https://doi.org/10.1038/news.2009.33; ETC Group and Heinrich Böll Foundation (2020)

[7] Lee, et al. (2011) Observed increase in local cooling effect of deforestation at higher latitudes, in Nature, Vol. 479: 384 – 387, https://doi.org/10.1038/nature10588; Yale University (2011) Deforestation causes cooling, study shows, in Phys.org, published: November 16, 2011, https://phys.org/news/2011-11-deforestation-cooling.html; ETC Group and Heinrich Böll Foundation (2020)

[8] Swaminathan (2007) More Trees, Less Global Warming – Right? Not Exactly, in Scientific American, published: April 10, 2007, https://www.scientificamerican.com/article/tropical-forests-cool-earth/; Walsh (2011) How (Some) Deforestation Might Slow Warming, in: Time, published: November 16, 2011, http://science.time.com/2011/11/16/how-some-deforestation-might-slow-warming/ 

[9] ETC Group and Heinrich Böll Foundation (2020)

[10] Goudie and Middleton (2006) Desert Dust in the Global System, published by Springer, ISBN-10: 3540323546, https://www.springer.com/la/book/9783540323549 

[11] ETC Group and Heinrich Böll Foundation (2020)

[12] Akbari: List of publications, Concordia University, http://concordia.academia.edu/HashemAkbari; Biello (2014) Cool Roofs Might Be Enough to Save Cities from Climate Overheating, in Scientific American, published: February 14, 2014, https://www.scientificamerican.com/article/cool-roofs-might-be-enough-to-save-cities-from-climate-overheating/ 

[13] ETC Group and Heinrich Böll Foundation (2020)

[14] The Royal Society (2009) Geoengineering the climate: Science, governance and uncertainty, ISBN: 978-0-85403-773-5, https://royalsociety.org/~/media/Royal_Society_Content/policy/publications/2009/8693.pdf 

[15] Biello (2014)