Solar geoengineering, or, solar radiation management (SRM) is a type of climate engineering in which sunlight (solar radiation) is reflected back to space to limit or reverse global warming. Proposed methods include increasing the planetary albedo (reflectivity), for example with stratospheric sulfate aerosol injection. Localized protective or restorative methods have also been proposed regarding the protection of natural heat reflectors including sea ice, snow, and glaciers.[1][2][3] Their principal advantages as an approach to climate engineering is the speed with which they can be deployed and become fully active, their low financial cost, and the reversibility of their direct climatic effects.
Solar radiation management could serve as a temporary response while levels of greenhouse gases in the atmosphere are reduced through the reduction of greenhouse gas emissions and carbon dioxide removal. Solar geoengineering would not directly reduce greenhouse gas concentrations in the atmosphere, and thus does not address problems such as ocean acidification caused by excess carbon dioxide (CO2). However, solar geoengineering has been shown in climate models to be capable of reducing global average temperatures to pre-industrial levels, therefore solar geoengineering can prevent the climate change associated with global warming.[4]
Purpose
editAveraged over the year and the day, the Earth's atmosphere receives 340 W/m2 of solar irradiance from the sun.[5] Due to elevated atmospheric greenhouse gas concentrations, the net-difference between the amount of sunlight absorbed by the Earth and the amount radiated back to space has risen from 1.7 W/m2 in 1980, to 3.1 W/m2 in 2019.[6] This net-imbalance - called radiative forcing - means that the Earth absorbs more energy than it lets off, causing global average temperatures to rise.[7] The goal of solar geoengineering is to reduce radiative forcing by increasing Earth's reflectance (albedo). An increase in reflectance by about 1% of the incident solar radiation would be sufficient to eliminate radiative forcing and thereby global warming, (3.1 W/m2 is around 1% of 340 W/m2).
As early as 1974, Russian expert Mikhail Budyko suggested that if global warming ever became a serious threat, it could be countered with airplane flights in the stratosphere, burning sulphur to make aerosols that would reflect sunlight away.[8] In recent years, US presidential candidate Andrew Yang included funding for solar geoengineering research in his climate policy and suggested its potential use as an emergency option.[9] The annual cost of delivering a sufficient amount of sulfur to counteract expected greenhouse warming is estimated at $8 billion US dollars, which is around $1 per person in the world.[10]
One of the most prominently considered methods of solar geoengineering is to scatter reflective aerosols - such as sulfur dioxide - in the stratosphere to reduce or eliminate elevated global temperatures caused by the greenhouse gas effect. This phenomenon occurs naturally by the eruption of volcanoes. In 1991, the massive eruption of Mt Pinatubo emitted large amounts of sulfur dioxide into the stratosphere, which caused a recorded drop in global average temperatures of about 0.5 °C (0.9 °F) over the following few years.[11]
Solar geoengineering is widely viewed as a complement, not a substitute, to climate change mitigation and adaptation efforts. The Royal Society concluded in its 2009 report: "Geoengineering methods are not a substitute for climate change mitigation, and should only be considered as part of a wider package of options for addressing climate change."[12] Harvard University launched its Solar Geoengineering Research Program under the broad statement that "Solar geoengineering in particular could not be a replacement for reducing emissions (mitigation) or coping with a changing climate (adaptation); yet, it could supplement these efforts".[13]
The National Academy of Sciences stated in a 2015 report: "Modeling studies have shown that large amounts of cooling, equivalent in scale to the predicted warming due to doubling the CO2 concentration in the atmosphere, can be produced by the introduction of tens of millions of tons of aerosols into the stratosphere. ... Preliminary modeling results suggest that albedo modification may be able to counter many of the damaging effects of elevated greenhouse gas concentrations on temperature and the hydrological cycle and reduce some impacts to sea ice."[14]
It has been suggested that a 2% albedo increase would roughly halve the effect of doubling the concentration of CO2 in the atmosphere.[15] Solar geoengineering has been suggested as a means of stabilizing regional climates - such as limiting heat waves,[16] but precise control over the geographical boundaries of the effect is not reasonable to assume. Even if the effects in computer simulation models or of small-scale interventions are known, there may be cumulative problems such as ozone depletion, which become apparent only from large-scale experiments.[17][18]
Advantages
editSolar radiation management has certain advantages relative to emission cuts, adaptation, and carbon dioxide removal. It could reduce the impact of climate change within months after deployment,[19] whereas the effects of emission cuts and carbon dioxide removal are delayed because the climate change that they prevent is itself delayed. Some proposed solar radiation management techniques are expected to have very low direct financial costs of implementation,[20] relative to the expected costs of both unabated climate change and aggressive mitigation. This creates a different problem structure.[21][22] Whereas the provision of emissions reduction and carbon dioxide removal present collective action problems (because ensuring a lower atmospheric carbon dioxide concentration is a public good), a single country or a handful of countries could implement solar radiation management. Finally, the direct climatic effects of solar radiation management are reversible within short timescales.[19]
Limitations and risks
editAs well as the imperfect cancellation of the climatic effect of greenhouse gases, there are other significant problems with solar radiation management as a form of climate engineering. Solar radiation management is temporary in its effect, and thus any long-term restoration of the climate would rely on long-term deployment, until sufficient carbon dioxide is removed.[23][24]
Incomplete solution to CO2 emissions
editSolar radiation management does not remove greenhouse gases from the atmosphere and thus does not reduce other effects from these gases, such as ocean acidification.[25] While not an argument against solar radiation management per se, this is an argument against reliance on climate engineering to the exclusion of greenhouse gas reduction.
Control and predictability
editMost of the information on solar radiation management comes from climate models and volcanic eruptions, which are both imperfect analogues of stratospheric aerosol injection. The climate models used in impact assessments are the same that scientists use to predict the impacts of anthropogenic climate change. Some uncertainties in these climate models (such as aerosol microphysics, stratospheric dynamics, and sub-grid scale mixing) are particularly relevant to solar radiation management and are a target for future research.[26] Volcanoes are an imperfect analogue as they release the material in the stratosphere in a single pulse, as opposed to sustained injection.[27]
Side effects
editThere may be unintended climatic consequences of solar radiation management, such as changes to the hydrological cycle.[28] Ozone depletion is a risk of techniques involving sulfur delivery into the stratosphere.[29] An increase in agricultural productivity has also been predicted by some studies due to the combination of more diffuse light and elevated carbon dioxide concentration.[30] The surface deposition of sulfate injected in the stratosphere may also have an impact on ecosystems.[31]
Termination shock
editIf solar radiation management were masking a significant amount of warming and then were to abruptly stop, the climate would rapidly warm.[32] This would cause a sudden rise in global temperatures towards levels which would have existed without the use of the climate engineering technique. The rapid rise in temperature may lead to more severe consequences than a gradual rise of the same magnitude.
Disagreement
editThe U.N. Convention on the Prohibition of Military or Any Other Hostile Use of Environmental Modification Techniques, which generally prohibits weaponizing climate engineering techniques, came into force in 1978.[33] But leaders of countries and other actors may disagree as to whether, how, and to what degree solar radiation management be used, which could exacerbate international tensions.[34]
Effect on sunlight, sky and clouds
editManaging solar radiation using aerosols or cloud cover would involve changing the ratio between direct and indirect solar radiation. This would affect plant life[35] and solar energy.[36] There would be an effect on the appearance of the sky from stratospheric aerosol injection, notably a slight hazing of blue skies and a change in the appearance of sunsets.[37][38] How stratospheric aerosol injection may affect clouds remains uncertain.[39]
Proposed forms
editAtmospheric
editThese projects seek to modify the atmosphere, either by enhancing naturally occurring stratospheric aerosols, or by using artificial techniques such as reflective balloons.
Stratospheric aerosols
editInjecting reflective aerosols into the stratosphere is the proposed solar radiation management method that has received the most sustained attention. This technique could give much more than 3.7 W/m2 of globally averaged negative forcing,[40] which is sufficient to entirely offset the warming caused by a doubling of CO2, which is a common benchmark for assessing future climate scenarios. Sulfates are the most commonly proposed aerosols for climate engineering, since there is a good natural analogue with (and evidence from) volcanic eruptions. Explosive volcanic eruptions inject large amounts of sulfur dioxide gas into the stratosphere, which form sulfate aerosol and cool the planet. Alternative materials such as using photophoretic particles, titanium dioxide, and diamond have been proposed.[41][42][43] Delivery could be achieved using artillery, aircraft (such as the high-flying F15-C) or balloons.[44][45][46] Broadly speaking, stratospheric aerosol injection is seen as a relatively more credible climate engineering technique[by whom?], although one with potential major risks and challenges for its implementation. Risks include changes in precipitation and, in the case of sulfur, possible ozone depletion.
Marine cloud brightening
editVarious cloud reflectivity methods have been suggested, such as that proposed by John Latham and Stephen Salter, which works by spraying seawater in the atmosphere to increase the reflectivity of clouds.[47] The extra condensation nuclei created by the spray would change the size distribution of the drops in existing clouds to make them whiter.[48] The sprayers would use fleets of unmanned rotor ships known as Flettner vessels to spray mist created from seawater into the air to thicken clouds and thus reflect more radiation from the Earth.[49] The whitening effect is created by using very small cloud condensation nuclei, which whiten the clouds due to the Twomey effect.
This technique can give more than 3.7 W/m2 of globally averaged negative forcing,[40] which is sufficient to reverse the warming effect of a doubling of CO2.
Ocean sulfur cycle enhancement
editEnhancing the natural marine sulfur cycle by fertilizing a small portion with iron—typically considered to be a greenhouse gas remediation method—may also increase the reflection of sunlight.[50][51] Such fertilization, especially in the Southern Ocean, would enhance dimethyl sulfide production and consequently cloud reflectivity. This could potentially be used as regional solar radiation management, to slow Antarctic ice from melting.[citation needed] Such techniques also tend to sequester carbon, but the enhancement of cloud albedo also appears to be a likely effect.
Terrestrial
editCool roof
editPainting roof materials in white or pale colours to reflect solar radiation, known as 'cool roof' technology, is encouraged by legislation in some areas (notably California).[52] This technique is limited in its ultimate effectiveness by the constrained surface area available for treatment. This technique can give between 0.01–0.19 W/m2 of globally averaged negative forcing, depending on whether cities or all settlements are so treated.[40] This is small relative to the 3.7 W/m2 of positive forcing from a doubling of CO2. Moreover, while in small cases it can be achieved at little or no cost by simply selecting different materials, it can be costly if implemented on a larger scale. A 2009 Royal Society report states that, "the overall cost of a 'white roof method' covering an area of 1% of the land surface (about 1012 m2) would be about $300 billion/yr, making this one of the least effective and most expensive methods considered."[53] However, it can reduce the need for air conditioning, which emits CO2 and contributes to global warming.
Ocean and ice changes
editOceanic foams have also been suggested, using microscopic bubbles suspended in the upper layers of the photic zone. A less costly proposal is to simply lengthen and brighten existing ship wakes.[54]
Arctic sea ice formation could be increased by pumping deep cooler water to the surface.[55] Sea ice (and terrestrial) ice can be thickened by increasing albedo with silica spheres.[56] Glaciers flowing into the sea may be stabilized by blocking the flow of warm water to the glacier.[57] Salt water could be pumped out of the ocean and snowed onto the West Antarctic ice sheet.[58][59]
Vegetation
editReforestation in tropical areas has a cooling effect.
Changes to grassland have been proposed to increase albedo.[60] This technique can give 0.64 W/m2 of globally averaged negative forcing,[40] which is insufficient to offset the 3.7 W/m2 of positive forcing from a doubling of CO2, but could make a minor contribution.
Selecting or genetically modifying commercial crops with high albedo has been suggested.[61] This has the advantage of being relatively simple to implement, with farmers simply switching from one variety to another. Temperate areas may experience a 1 °C cooling as a result of this technique.[62] This technique is an example of bio-geoengineering. This technique can give 0.44 W/m2 of globally averaged negative forcing,[40] which is insufficient to offset the 3.7 W/m2 of positive forcing from a doubling of CO2, but could make a minor contribution.
Space-based
editSpace-based climate engineering projects are seen by many commentators and scientists as being very expensive and technically difficult, with the Royal Society suggesting that "the costs of setting in place such a space-based armada for the relatively short period that solar geoengineering may be considered applicable (decades rather than centuries) would likely make it uncompetitive with other solar geoengineering approaches."[63]
Proposed by Roger Angel with the purpose to deflect a percentage of solar sunlight into space, using mirrors orbiting around the Earth.[47][64]
Mining moon dust to create a shielding cloud was proposed by Curtis Struck at Iowa State University in Ames.[65][66][67]
Several authors have proposed dispersing light before it reaches the Earth by putting a very large diffraction grating (thin wire mesh) or lens in space, perhaps at the L1 point between the Earth and the Sun. Using a Fresnel lens in this manner was proposed in 1989 by J. T. Early.[68] Using a diffraction grating was proposed in 1997 by Edward Teller, Lowell Wood, and Roderick Hyde.[69] In 2004, physicist and science fiction author Gregory Benford calculated that a concave rotating Fresnel lens 1000 kilometres across, yet only a few millimeters thick, floating in space at the L1 point, would reduce the solar energy reaching the Earth by approximately 0.5% to 1%. He estimated that this would cost around US$10 billion up front, and another $10 billion in supportive cost during its lifespan.[70] One issue with implementing such a solution is the need to counteract the effects of the solar wind moving such megastructures out of position.
Governance
editClimate engineering poses several challenges in the context of governance because of issues of power and jurisdiction.[33] Climate engineering as a climate change solution differs from other mitigation and adaptation strategies. Unlike a carbon trading system that would be focused on participation from multiple parties along with transparency, monitoring measures and compliance procedures; this is not necessarily required by climate engineering. Bengtsson[71] (2006) argues that "the artificial release of sulphate aerosols is a commitment of at least several hundred years". Yet this is true only if a long-term deployment strategy is adopted. Under a short-term, temporary strategy, implementation would instead be limited to decades.[72] Both cases, however, highlight the importance for a political framework that is sustainable enough to contain a multilateral commitment over such a long period and yet is flexible as the techniques innovate through time. There are many controversies surrounding this topic and hence, climate engineering has become a very political issue. Most discussions and debates are not about which climate engineering technique is better than the other, or which one is more economically and socially feasible. Discussions are broadly on who will have control over the deployment of climate engineering and under what governance regime the deployment can be monitored and supervised. This is especially important due to the regional variability of the effects of many climate engineering techniques, benefiting some countries while damaging others. The main challenge posed by climate engineering is not how to get countries to do it. It is to address the fundamental question of who should decide whether and how climate engineering should be attempted – a problem of governance.[73]
Solar radiation management raises a number of governance challenges. David Keith argues that the cost is within the realm of small countries, large corporations, or even very wealthy individuals.[74] David Victor suggests that climate engineering is within the reach of a lone "Greenfinger," a wealthy individual who takes it upon him or herself to be the "self-appointed protector of the planet".[75][76] However, it has been argued that a rogue state threatening solar radiation management may strengthen action on mitigation.[77]
Legal and regulatory systems may face a significant challenge in effectively regulating solar radiation management in a manner that allows for an acceptable result for society. There are, however, significant incentives for states to cooperate in choosing a specific climate engineering policy, which make unilateral deployment a rather unlikely event.[78]
Some researchers have suggested that building a global agreement on climate engineering deployment will be very difficult, and instead power blocs are likely to emerge.[79]
Public attitudes
editThere have been a handful of studies into attitudes to and opinions of solar radiation management. These generally find low levels of awareness, uneasiness with the implementation of solar radiation management, cautious support of research, and a preference for greenhouse gas emissions reduction.[80][81] As is often the case with public opinions regarding emerging issues, the responses are highly sensitive to the questions' particular wording and context.
One cited objection to implementing a short-term temperature fix is that there might then be less incentive to reduce carbon dioxide emissions until it caused some other environmental catastrophe, such as a chemical change in ocean water that could be disastrous to ocean life.[82]
Ever since the idea of artificial cooling of planet was proposed, there has been major backlash and skepticism.[citation needed] Many people oppose the suggestion, but a recent study from the journal of Nature Climate Change has shown the speculation that solar geoengineering could cause extreme temperatures and increase severity of storms is actually incorrect. This journal shows that only 0.4% of places on the Earth would experience worsened weather conditions.[citation needed] Although no action has been carried out for spraying these gases and clouds into the atmosphere, this discovery could have a major influence on the course of action humans choose to take for reducing the greenhouse gas effect.
Many critics and concerned scientists are whole-heartedly against the idea of solar geoengineering. A geophysics professor, Alan Robock, has reprimanded the Nature Climate Change journal for neglecting to mention other environmental effects that will occur from the atmospheric spray. Robock had said the choice to cool the Earth by artificial emissions would be very costly and it could serve a potential threat to different plant and animal species.[citation needed] Likewise, a study in the journal Nature Ecology and Evolution warned that implementing or ending solar engineering too suddenly could cause cooling or warming rapid enough that many animal and plant species might not be able to keep pace.[83]
References
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has generic name (help)CS1 maint: multiple names: authors list (link) - ^ Latham, J. (1990). "Control of global warming" (PDF). Nature. 347 (6291): 339–340. Bibcode:1990Natur.347..339L. doi:10.1038/347339b0. S2CID 4340327. Archived from the original (PDF) on 16 July 2011.
- ^ Wingenter, Oliver W.; Haase, Karl B.; Strutton, Peter; Friederich, Gernot; Meinardi, Simone; Blake, Donald R.; Rowland, F. Sherwood (8 June 2004). "Changing concentrations of CO, CH4, C5H8, CH3Br, CH3I, and dimethyl sulfide during the Southern Ocean Iron Enrichment Experiments". Proceedings of the National Academy of Sciences of the United States of America. 101 (23): 8537–8541. Bibcode:2004PNAS..101.8537W. doi:10.1073/pnas.0402744101. ISSN 0027-8424. PMC 423229. PMID 15173582.
- ^ Wingenter, Oliver W.; Elliot, Scott M.; Blake, Donald R. (November 2007). "New Directions: Enhancing the natural sulfur cycle to slow global warming". Atmospheric Environment. 41 (34): 7373–5. Bibcode:2007AtmEn..41.7373W. doi:10.1016/j.atmosenv.2007.07.021.
- ^ Hashem Akbari; et al. (2008). "Global Cooling: Increasing World-wide Urban Albedos to Offset CO2" (PDF).
- ^ "The Royal Society" (PDF). royalsociety.org. Retrieved 9 November 2015.
- ^ Hand, Eric (29 January 2016). "Could bright, foamy wakes from ocean ships combat global warming?". Science. Retrieved 30 December 2017.
- ^ Desch, Steven J.; et al. (19 December 2016). "Arctic Ice Management". Earth's Future. 5 (1): 107–127. Bibcode:2017EaFut...5..107D. doi:10.1002/2016EF000410.
- ^ McGlynn, Daniel (17 January 2017). "One big reflective band-aid". Berkeley Engineering. University of California, Berkeley. Retrieved 2 January 2018.
- ^ Meyer, Robinson (8 January 2018). "A Radical New Scheme to Prevent Catastrophic Sea-Level Rise". The Atlantic. Retrieved 12 January 2018.
- ^ "How vast snow cannons could save melting ice sheets". The Independent. 17 July 2019. Retrieved 18 July 2019.
- ^ Green, Matthew (17 July 2019). "'Artificial snow' could save stricken Antarctic ice sheet -study". CNBC. Retrieved 18 July 2019.
- ^ Hamwey, Robert M. (2005). "Active Amplification of the Terrestrial Albedo to Mitigate Climate Change: An Exploratory Study". Mitigation and Adaptation Strategies for Global Change. 12 (4): 419. arXiv:physics/0512170. Bibcode:2005physics..12170H. doi:10.1007/s11027-005-9024-3. S2CID 118913297.
- ^ "A high-albedo diet will chill the planet – environment – 15 January 2009". New Scientist. Retrieved 16 October 2013.
- ^ Ridgwell, A; Singarayer, J; Hetherington, A; Valdes, P (2009). "Tackling Regional Climate Change By Leaf Albedo Bio-geoengineering". Current Biology. 19 (2): 146–50. doi:10.1016/j.cub.2008.12.025. PMID 19147356.
- ^ "The Royal Society" (PDF). royalsociety.org. Retrieved 18 November 2015.
- ^ David W. Keith (2000). "Geoengineering the climate: History and Prospect". Annual Review of Energy and the Environment. 25 (1): 245–284. doi:10.1146/annurev.energy.25.1.245. S2CID 154687119.
- ^ Journal of the British Interplanetary Society, vol 60, p 1
- ^ Roger Angel; S. Pete Worden (Summer 2006). "Making Sun-Shades from Moon Dust". National Space Society, Ad Astra. 18 (1).
- ^ "Space Ring Could Shade Earth and Stop Global Warming". LiveScience. 27 June 2005. Retrieved 16 October 2013.
- ^ J. T. Early (1989). "Space-Based Solar Shield To Offset Greenhouse Effect". Journal of the British Interplanetary Society. Vol. 42. pp. 567–569. This proposal is also discussed in footnote 23 of Edward Teller; Roderick Hyde; Lowell Wood (1997). "Global Warming and Ice Ages: Prospects for Physics-Based Modulation of Global Change" (PDF). Lawrence Livermore National Laboratory. Archived from the original (PDF) on 27 January 2016. Retrieved 21 January 2015.
{{cite journal}}
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(help) - ^ Edward Teller; Roderick Hyde; Lowell Wood (1997). "Global Warming and Ice Ages: Prospects for Physics-Based Modulation of Global Change" (PDF). Lawrence Livermore National Laboratory. Archived from the original (PDF) on 27 January 2016. Retrieved 21 January 2015. See pages 10–14 in particular.
{{cite journal}}
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(help)CS1 maint: postscript (link) - ^ See Russell Dovey, "Supervillainy: Astroengineering Global Warming and Bill Christensen, "Reduce Global Warming by Blocking Sunlight" Archived 17 April 2009 at the Wayback Machine.
- ^ Bengtsson, L. (2006) 'Geo-engineering to confine climate change: is it at all feasible?' Climatic Change 77: 229–234
- ^ Keith, David W.; MacMartin, Douglas G. (2015). "A temporary, moderate and responsive scenario for solar geoengineering" (PDF). Nature Climate Change. 5 (3): 201–206. Bibcode:2015NatCC...5..201K. doi:10.1038/nclimate2493.
- ^ Barrett, S (2007) Why cooperate? The incentive to supply global public goods. Oxford University Press, Oxford
- ^ David Keith. "Engineering the Planet" (PDF). pp. 3–4, 8. Retrieved 8 April 2008.
- ^ David G. Victor (2008). "On the regulation of geoengineering". Oxford Review of Economic Policy. 24 (2): 322–336. CiteSeerX 10.1.1.536.5401. doi:10.1093/oxrep/grn018.
- ^ "The Geoengineering Option". Foreign Affairs (March/April 2009). March 2009. Retrieved 18 November 2015.
- ^ Millard-Ball, A. (2011). "The Tuvalu Syndrome". Climatic Change. 110 (3–4): 1047–1066. doi:10.1007/s10584-011-0102-0. S2CID 153990911.
- ^ Joshua Horton (2011). "Geoengineering and the myth of unilateralism: pressures and prospects for international cooperation". Stanford J Law Sci Policy (2): 56–69.
- ^ Ricke, K. L.; Moreno-Cruz, J. B.; Caldeira, K. (2013). "Strategic incentives for climate geoengineering coalitions to exclude broad participation". Environmental Research Letters. 8 (1): 014021. Bibcode:2013ERL.....8a4021R. doi:10.1088/1748-9326/8/1/014021.
- ^ Mercer, A. M.; Keith, D. W.; Sharp, J. D. (2011). "Public understanding of solar radiation management". Environmental Research Letters. 6 (4): 044006. Bibcode:2011ERL.....6d4006M. doi:10.1088/1748-9326/6/4/044006.
- ^ Merk, Christine; Pönitzsch, Gert; Kniebes, Carola; Rehdanz, Katrin; Schmidt, Ulrich (10 February 2015). "Exploring public perceptions of stratospheric sulfate injection". Climatic Change. 130 (2): 299–312. Bibcode:2015ClCh..130..299M. doi:10.1007/s10584-014-1317-7. ISSN 0165-0009. S2CID 154196324.
- ^ Gregory Benford (Comments at the 64th World Science Fiction Convention, August 2006.)
- ^ Trisos, Christopher; Amatulli, Giuseppe; Gurevitch, Jessica; Robock, Alan; Xia, Lili; Zambri, Brian (2018). "Potentially dangerous consequences for biodiversity of solar geoengineering implementation and termination". Nature Ecology and Evolution. 2: 475–482. doi:10.1038/s41559-017-0431-0. Retrieved 25 March 2021.
Further reading
edit- Granger Morgan, Katharine Ricke (2010). An Opinion Piece for the International Risk Governance Council. Cooling the Earth Through Solar Radiation Management: The need for research and an approach to its governance. ISBN 978-2-9700672-8-3
- National Research Council. Climate Intervention: Reflecting Sunlight to Cool Earth. Washington, DC: The National Academies Press, 2015. ISBNs: Prepublication: 978-0-309-36821-6; Paperback (forthcoming): 978-0-309-31482-4
Category:Climate change policy
Category:Planetary engineering
Category:Climate engineering