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An oceanic phytoplankton bloom in the South Atlantic Ocean, off the coast of Argentina. Encouraging such blooms with iron fertilization could lock up carbon on the seabed.

The concept of geoengineering (or climate engineering, climate remediation, and climate intervention[1]) refers to the deliberate large-scale engineering and manipulation of the planetary environment, often to combat or counteract anthropogenic changes in atmospheric chemistry.[2][3] The Intergovernmental Panel on Climate Change concluded in 2007 that geoengineering options, such as ocean fertilization to remove CO2 from the atmosphere, remained largely unproven.[4] It was judged that reliable cost estimates for geoengineering had not yet been published.

Geoengineering accompanies mitigation and adaptation to form a three-stranded 'MAG' approach to tackling global warming, notably advocated by the Institution of Mechanical Engineers.[5] Some geoengineering techniques are based on carbon dioxide removal (CDR).[2] These techniques seek to reduce greenhouse gases in the atmosphere directly. These include direct methods (e.g. carbon dioxide air capture) and indirect methods (e.g. ocean iron fertilization). These techniques can be regarded as mitigation of global warming.

Alternatively, solar radiation management techniques (SRM),[2] 'Reflective Approaches' (RA), [6] do not reduce greenhouse gas concentrations, and can only address the warming effects of carbon dioxide and other gases; they cannot address problems such as ocean acidification, which are expected as a result of rising carbon dioxide levels. Examples of proposed solar radiation management techniques include the production of stratospheric sulfur aerosols, which was suggested by Paul Crutzen,[7] space mirrors, and cloud reflectivity enhancement. Most techniques have at least some side effects.

To date, no large-scale geoengineering projects have been undertaken. Some limited tree planting[8] and cool roof[9] projects are already underway, and ocean iron fertilization is at a beginning stage of research, with small-scale research trials and global modelling having been completed.[10] Field research into sulfur aerosols has also started.[11] Some commentators have suggested that consideration of geoengineering presents a moral hazard because it threatens to reduce the political and popular pressure for emissions reduction.[12] Scientists do not typically suggest geoengineering as an alternative to emissions control, but rather an accompanying strategy.[13] Reviews of geoengineering techniques have emphasised that they are not substitutes for emission controls and have identified potentially stronger and weaker schemes.[14][15][16]

Definition

Geoengineering is the idea of applying planetary engineering to Earth. Geoengineering would involve the deliberate modification of Earth's environment on a large scale "to suit human needs and promote habitability".[17] Typically, the term is used to describe proposals to counter the effects of human-induced climate change. However, others define it more narrowly as nature-integrated engineering projects.[18] The term geoengineering is distinct from environmental damage and accidental anthropogenic climate change, which are side-effects of human activity, rather than an intended consequence. The global extraction of hydrocarbons from the sub-surface using integrated geoscience and engineering technology has been termed 'petroleum geoengineering' as an activity with global impact.[19] Definitions of the term are not universally accepted.[20] Oxford Dictionary defines geoengineering as "the deliberate large-scale manipulation of an environmental process that affects the earth’s climate, in an attempt to counteract the effects of global warming."

Background

Several notable organizations have investigated geoengineering with a view to evaluating its potential, including, NASA,[21] the Royal Society,[22] the Institute of Mechanical Engineers,[23][24] and the UK Parliament,.[25] The Asilomar International Conference on Climate Intervention Technologies was convened to identify and develop risk reduction guidelines for climate intervention experimentation.[26]

The major environmental organisations such as Friends of the Earth[27] and Greenpeace[28] have typically been reluctant to endorse geoengineering. Some have argued that any public support for geoengineering may weaken the fragile political consensus to reduce greenhouse gas emissions.[29]

Proposed strategies

Several geoengineering strategies have been proposed. IPCC documents detail several notable proposals.[30] These fall into two main categories: solar radiation management and carbon dioxide removal. However, other proposals exist.

Solar radiation management

Solar radiation management (SRM)[2][31] projects seek to reduce the net incoming short-wave (ultra-violet and visible) solar radiation received, by deflecting sunlight, or by increasing the reflectivity (albedo) of the atmosphere. They do not reduce greenhouse gas concentrations in the atmosphere, and thus do not address problems such as ocean acidification caused by these gases. Solar radiation management projects often have the advantage of speed. While greenhouse gas remediation offers a comprehensive possible solution to climate change, it does not give instant results; for that, solar radiation management is required.

SRM methods[2] may be:

  • Surface-based (land or ocean albedo modification); e.g. Cool roof—using pale-coloured roofing and paving materials.
  • Troposphere-based (cloud modification methods, etc.); Creating reflective aerosols, such as stratospheric sulfur aerosols, aluminum oxide particles, even specifically designed self-levitating aerosols with the purpose of increasing the up-air residence time.[32] Another often mentioned approach is Cloud whitening – using fine sea water spray to whiten clouds and thus increase cloud reflectivity.
  • Upper atmosphere-based (tropopause and above, i.e., stratosphere, mesosphere);
  • Space-based: E.g. Space sunshade—obstructing solar radiation with space-based mirrors or other structures.

Carbon dioxide removal

Carbon dioxide removal projects seek to remove greenhouse gases from the atmosphere, and thus tackle the root cause of global warming. They either directly remove greenhouse gases, or alternatively seek to influence natural processes to remove greenhouse gases indirectly. These projects offer a comprehensive solution to the problem of excess greenhouse gases in the atmosphere, but they will take many years to work fully. Many projects overlap with carbon capture and storage and carbon sequestration projects, and may not be considered to be geoengineering by all commentators. Techniques in this category include:

Significant reduction in ice volume in the Arctic Ocean in the range between 1979 and 2007 years

Heat transport

The use of vertical ocean pipes to mix cooler deep water and warmer surface water has been proposed. This technology has also been suggested for the disruption of hurricanes by Bill Gates and others in a recent patent application.[33][34] Modification of hurricanes may be considered weather modification rather than geoengineering, depending on the definition used.

Justification

Tipping points and positive feedback

Climate change during the last 65 million years. The Paleocene–Eocene Thermal Maximum is labelled PETM.

It is argued that climate change has already, or is soon to have passed one or more tipping points[35] where aspects of the climate system may 'tip' from one stable state to another stable state, much like a glass tipping over. When the new stable state is reached, it may trigger or accelerate warming positive feedback effects,[36] such as the collapse of Arctic sea ice triggering the release of methane from permafrost in Siberia.[37][38] The "nightmare scenario" is that a domino effect will occur, with successive parts of the climate system tipping one after the other, with each change being caused by the previous one and causing the next one. Such a situation will lead to spiralling and potentially sudden climate change.

The precise identity of such "tipping points" is not clear, with scientists taking differing views on whether specific systems are capable of "tipping" and the point at which this "tipping" will occur.[39] An example of a previous tipping point is that which preceded the rapid warming leading up to the Paleocene–Eocene Thermal Maximum. Once the tipping point is reached, cuts in greenhouse gas emissions will not be able to reverse the change. Depending on the precise nature of the individual system that "tips", positive feedbacks may occur, with warming causing more warming, which causes yet more warming—a runaway global warming event.[40] Therefore, some commentators suggest that more conservative use of resources is not enough to mitigate global warming. Even if all greenhouse emissions suddenly came to a complete halt, the world would continue to be affected for centuries,[41] and further warming may occur due to positive feedback. Conservation of resources and reduction of greenhouse emissions, used in conjunction with geoengineering, are therefore considered a viable option.[42][43][44] Geoengineering offers the hope of temporarily reversing some aspects of climate change and allowing the natural climate to be substantially preserved whilst greenhouse gas emissions are brought under control and removed from the atmosphere by natural or artificial processes.

Costs

Some geoengineering techniques, such as cool roof techniques, can be achieved at little or no cost, and may even offer a financial payback.[45] IPCC (2007) concluded that reliable cost estimates for geoengineering options had not been published.[4]

In 2008 the Council on Foreign Relations (CFR) mentioned the 1992 report of the National Research Council (Policy Implications of Greenhouse Warming) to be the first systematical estimate of the potential costs of a stratospheric aerosol program. This reports states total costs of 100 billion USD for a 40-year project to deliver aluminum oxide dust via standard naval gun systems. More recent analysis however suggest that "well designed systems" might reduce such costs to a few hundred million dollars per year, which are clearly much lower costs than any program to reduce CO2 emissions. Such costs would be clearly within the budget of most nations, and even a handful of rich individuals.[46]

Alan Robock calculates the annual costs for delivering 1 Teragram (equals 1 Megaton) of sulphur gas from 225 Million USD (using KC-135 tankers) up to 30 billion USD (using naval rifles or stratosheric balloons).[47]

In their 2009 report Geoengineering the climate the Royal Society defines afforestation and stratospheric aerosols as methods with the "highest affordibility" (meaning lowest costs). Furthermore stratospheric aerosol injection, having the highest effectiveness and affordability, would be the nearest approximation to the "ideal method", with the disadvantage of high uncertainties considering unwanted side effects.(see Table 5.1, Figure 5.1., pages 48-49)[2]

Ethics and Responsibility

Climate engineering would represent a large-scale, intentional effort to modify the environment, which differ from inadvertent climate change through activities such as burning fossil fuels. Intentional climate change is viewed very differently from a moral standpoint.[48] This raises questions of whether we as humans have the right to change the climate. The selection of a globally-agreed target temperature is a significant problem in any geoengineering governance regime, as different countries or interest groups may seek different global temperatures[49]

Solar radiation management is an incomplete solution to global warming.[50] The possible option of geoengineering may reduce incentives to reduce emissions of greenhouse gases. It is argued that geoengineering could be used to ‘buy time’ before drastic climate change happens, allowing mitigation and adaptation measures more time to be implemented and work.[51] But the opposition points out that there are issues regarding the interference this causes with actual efforts for climate change, creating an unnecessary distraction.

Political viability

It has been argued that regardless of the economic, scientific and technical aspects, the difficulty of achieving concerted political action on climate change requires other approaches.[52] Those arguing political expediency say the difficulty of achieving meaningful emissions cuts[53] and the effective failure of the Kyoto Protocol demonstrate the practical difficulties of achieving carbon dioxide emissions reduction by the agreement of the international community.[54] However, others point to support for geoengineering proposals among think tanks with a history of climate change skepticism and opposition to emissions reductions as evidence that the prospect of geoengineering is itself already politicized and being promoted as part of an argument against the need for (and viability of) emissions reductions; that, rather than geoengineering being a solution to the difficulties of emissions reductions, the prospect of geoengineering is being used as part of an argument to stall emissions reductions in the first place.[55]

Geoenginering poses several challenges in the context of governance because of issues of power and jurisdiction.[47] Geoengineering 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 geoengineering. Bengtsson[56] (2006) argues that “the artificial release of sulphate aerosols is a commitment of at least several hundred years”. This highlights 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, geoengineering has been made into a very political issue. Most discussions and debates are not about which geoengineering 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 geoengineering 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 geoengineering techniques, benefiting some countries while damaging others. The challenge posed by geoengineering is not how to get countries to do it. It is to address the fundamental question of who should decide whether and how geoengineering should be attempted – a problem of governance.[57]

Risks and criticisms

Change in sea surface pH caused by anthropogenic CO2 between the 1700s and the 1990s. This ocean acidification will still be a major problem unless atmospheric CO2 is reduced.

Various criticisms have been made of geoengineering.[58] Some commentators appear fundamentally opposed. Groups such as ETC Group[59] and individuals such as Raymond Pierrehumbert have called for a moratorium on geoengineering techniques.[60][61]

Ineffectiveness

The effectiveness of the schemes proposed may fall short of predictions. In ocean iron fertilization, for example, the amount of carbon dioxide removed from the atmosphere may be much lower than predicted, as carbon taken up by plankton may be released back into the atmosphere from dead plankton, rather than being carried to the bottom of the sea and sequestered.[62]

Incomplete solution to CO2 emissions

Techniques that do not remove greenhouse gases from the atmosphere may control global warming, but do not reduce other effects from these gases, such as ocean acidification.[63] While not an argument against geoengineering per se, this is an argument against reliance on geoengineering to the exclusion of greenhouse gas reduction.

Control and predictability problems

The picture from space of a large natural accumulations of phytoplankton in the Bering Sea

The full effects of various geoengineering schemes are not well understood.[64] Matthews et al.[65] compared geoengineering to a number of previous environmental interventions and concluded that "Given our current level of understanding of the climate system, it is likely that the result of at least some geoengineering efforts would follow previous ecological examples where increased human intervention has led to an overall increase in negative environmental consequences."

Performance of the systems may become ineffective, unpredictable or unstable as a result of external events, such as volcanic eruptions, phytoplankton blooms, El Niño, solar flares, etc., potentially leading to profound and unpredictable disruption to the climate system.

It may be difficult to predict the effectiveness of projects,[66] with models of techniques giving widely varying results.[67] In the instances of systems which involve tipping points, this may result in irreversible effects. Climate modelling is far from an exact science even when applied to comparatively well-understood natural climate systems, and it is made more complex by the need to understand novel and unnatural processes which by definition lack relevant observation data.[68]

Side effects

The techniques themselves may cause significant foreseen or unforeseen harm. For example, the use of reflective balloons may result in significant litter,[69] which may be harmful to wildlife.

Ozone depletion is a risk of some geoengineering techniques, notably those involving sulfur delivery into the stratosphere.[70]

The active nature of geoengineering may in some cases create a clear division between winners and losers. Most of the proposed interventions are regional, such as albedo modification in the Arctic. Necessarily, such interventions compel those in the affected regions to tolerate the effects of geoengineering for the supposed benefit of the global climate.[71]

There may be unintended climatic consequences, such as changes to the hydrological cycle[72] including droughts[73] or floods, caused by the geoengineering techniques, but possibly not predicted by the models used to plan them.[74] Such effects may be cumulative or chaotic in nature, making prediction and control very difficult.[75]

Unreliable systems

The performance of the interventions may be inconsistent due to mechanical failure, non-availability of consumables or funding problems.

The geoengineering techniques would, in many instances, be vulnerable to being switched off or deliberately destroyed. As examples, cloud making ships could be switched off or sunk and space mirrors could be tilted to make them useless. Anyone capable of exerting such power may seek to abuse it for commercial gain, military advantage or simple terrorism.

Weaponisation

Geoengineering research began as a war tactic in the 1940s for the US and the Soviet Union during the Cold War.[49] During the Vietnam War, the US used geoengineering to flood certain areas. Then in 1976, 85 countries signed the U.N. Convention on the Prohibition of Military or Any Other Hostile Use of Environmental Modification Techniques.[47]

The Environmental Modification Convention generally prohibits weaponising geoengineering techniques. However, this does not eliminate the risk. Geoengineering techniques may serve as weapons of mass destruction, creating droughts or famines designed to destroy or disable an enemy.[76] They could also be used simply to make battlefield conditions more favourable to one side or the other in a war[77] (such as in Operation Popeye). For example, laser-guided weapons are confounded by clouds, and thus switching off cloud machines would favour forces using such weapons, and switching them on would favour ground forces defending against them.[78]

Whilst laws or treaties may prevent the manipulation of the climate as a weapon of war,[79] it could be argued that geoengineering is itself a manipulation, and thus destroying or disabling the geoengineering structures is not prohibited. A new legal framework may be necessary in the event that large-scale geoengineering becomes established.[original research?]

Carnegie’s Ken Caldeira said, "It will make it harder to achieve broad consensus on developing and governing these technologies if there is suspicion that gaining military advantage is an underlying motivation for its development..."[80]

Effect on sunlight, sky and clouds

Managing solar radiation using aerosols or cloud cover will change the ratio between direct and indirect solar radiation. This may affect plant life[81] and solar energy.[82] There will be a significant effect on the appearance of the sky from aerosol projects, notably a hazing of blue skies and a change in the appearance of sunsets.[83] Aerosols may affect the formation of clouds, especially cirrus clouds.[84]

Moral hazard

The existence of such techniques may reduce the political and social impetus to reduce carbon emissions.[85] The problem of moral hazard in relation to geoengineering by academics, such as David W. Keith[86] and Martin Bunzl[87]. This issue has been researched in an in-depth study by Ipsos MORI for NERC[88] The issue of moral hazard means that many environmental groups and campaigners are reluctant to advocate geoengineering for fear of reducing the imperative to cut greenhouse gas emissions.[89]

Other criticism comes from those who see geoengineering projects as reacting to the symptoms of global warming rather than addressing the real causes of climate change. Because geoengineering is a form of controlling the risks associated with global warming, it leads to a moral hazard problem. The problem is that knowledge that geoengineering is possible could lead to climate impacts seeming less fearsome, which could in turn lead to an even weaker commitment to reducing greenhouse gas emissions.[90]

Lack of global control

Geoengineering opens up various political and economic issues. David Keith argues that the cost of geoengineering the Earth is within the realm of small countries, large corporations, or even very wealthy individuals.[91] Steve Rayner agrees that not all geoengineering possibilities are expensive, and that some, such as ocean iron fertilisation, are within the reach of very wealthy individuals, calling them a "Greenfinger" (after the fictional Goldfinger).[92][93] David Victor suggests that geoengineering is within the reach of any individual who has a small fraction of the bank account of Bill Gates, who takes it upon him or her self to be the "self-appointed protector of the planet".[94]

This effectively eliminates any control over who gets to decide when to cool the Earth and how often this should be done.[91] The resulting power would be enormous, and could not necessarily be readily controlled by legal, political or regulatory systems.[92] These legal and regulatory systems may themselves be far less powerful than the geoengineers controlling the climate become.

It is quite feasible for carbon offsetting firms to set up unregulated, unsupervised and dangerous geoengineering projects. This may be done in order to sell carbon credits to individuals and firms.

Geoengineering schemes have the potential to cause significant environmental damage, and may even end up releasing further greenhouse gases into the atmosphere.[95] Opposition to some early schemes has been intense, with respected environmental groups campaigning against them.[96]

Termination shock

If solar radiation management were to abruptly stop, the climate would rapidly warm.[97] This would cause a sudden rise in global temperatures towards levels which would have existed without the use of the geoengineering technique. The rapid rise in temperature may lead to more severe consequences than a gradual rise of the same magnitude.[97]

Implementation issues

There is no general consensus that geoengineering is safe, appropriate or effective, for the reasons listed above. Other environmentalists see calls for geoengineering as part of an explicit strategy to delay emissions reductions on the part of those with connections to coal and oil industries.[98][improper synthesis?]

All proposed geoengineering techniques require implementation on a relatively large scale, in order to make a significant difference to the Earth's climate. The least costly schemes are budgeted at a cost of millions,[99] with many more complex schemes such as space sunshade costing far more.

Many techniques, again such as space sunshade, require a complex technical development process before they are ready to be implemented. There is no clear institutional mechanism for handling this research and development process. As a result, many promising techniques do not have the engineering development or experimental evidence to determine their feasibility or efficacy at present.

Once a technique has been developed and tested, its implementation is still likely to be difficult. Climate change is by nature a global problem, and therefore no one institution, company or government is responsible for it. The substantial costs of most geoengineering techniques therefore cannot currently be apportioned. Roll-out of such technologies is therefore likely to be delayed until these issues can be resolved. A notable exception is the use of small albedo manipulation projects, known as cool roof, in which the colour of roofing or paving surfaces can be manipulated to reflect solar radiation back into space. These can be, and are, implemented by individuals, companies and governments without controversy.[100]

Due to the radical changes caused by geoengineering interventions, legal issues are also an impediment to implementation. The changes resulting from geoengineering necessarily benefit some people and disadvantage others. There may therefore be legal challenges to the implementation of geoengineering techniques by those adversely affected by them.[101]

Evaluation of geoengineering

Most of what is known about the suggested techniques is based on laboratory experiments, observations of natural phenomena and on computer modelling techniques. Some geoengineering schemes employ methods that have analogues in natural phenomena such as stratospheric sulfur aerosols and cloud condensation nuclei. As such, studies about the efficacy of these schemes can draw on information already available from other research, such as that following the 1991 eruption of Mount Pinatubo. However, comparative evaluation of the relative merits of each technology is complicated, especially given modelling uncertainties and the early stage of engineering development of many geoengineering schemes.[102]

Reports into geoengineering have also been published in the United Kingdom by the Institution of Mechanical Engineers[15] and the Royal Society.[16] The IMechE report examined a small subset of proposed schemes (air capture, urban albedo and algal-based CO2 capture schemes), and its main conclusions were that geoengineering should be researched and trialled at the small scale alongside a wider decarbonisation of the economy.[15]

The Royal Society review examined a wide range of geoengineering schemes and evaluated them in terms of effectiveness, affordability, timeliness and safety (assigning qualitative estimates in each assessment). Similarly to Lenton and Vaughan,[14] the report divided schemes into "carbon dioxide removal" (CDR) and "solar radiation management" (SRM) approaches that respectively address longwave and shortwave radiation. The key recommendations of the report were that "Parties to the UNFCCC should make increased efforts towards mitigating and adapting to climate change, and in particular to agreeing to global emissions reductions", and that "[nothing] now known about geoengineering options gives any reason to diminish these efforts".[16] Nonetheless, the report also recommended that "research and development of geoengineering options should be undertaken to investigate whether low risk methods can be made available if it becomes necessary to reduce the rate of warming this century".[16]

In a 2009 review study, Lenton and Vaughan evaluated a range of geoengineering schemes from those that sequester CO2 from the atmosphere and decrease longwave radiation trapping, to those that decrease the Earth's receipt of shortwave radiation.[14] In order to permit a comparison of disparate techniques, they used a common evaluation for each scheme based on its effect on net radiative forcing. As such, the review examined the scientific plausibility of schemes rather than the practical considerations such as engineering feasibility or economic cost. Lenton and Vaughan found that "[air] capture and storage shows the greatest potential, combined with afforestation, reforestation and bio-char production", and noted that "other suggestions that have received considerable media attention, in particular “ocean pipes” appear to be ineffective".[14] They concluded that "[climate] geoengineering is best considered as a potential complement to the mitigation of CO2 emissions, rather than as an alternative to it".[14]

See also

References

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