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Climate engineering GudangMovies21 Rebahinxxi LK21
Climate engineering (or geoengineering, climate intervention) is the intentional large-scale alteration of the planetary environment to counteract anthropogenic climate change. The term has been used as an umbrella term for carbon dioxide removal, weather as a weapon, reduction of pole ice and solar radiation modification when applied at a planetary scale.: 168 However, these two processes have very different characteristics, and are now often discussed separately.: 168 Carbon dioxide removal techniques remove carbon dioxide from the atmosphere, and are part of climate change mitigation. Solar radiation modification is the reflection of some sunlight (solar radiation) back to space to cool the earth. Some publications include passive radiative cooling as a climate engineering technology. The media tends to also use climate engineering for other technologies such as glacier stabilization, ocean liming, and iron fertilization of oceans. The latter would modify carbon sequestration processes that take place in oceans.
Some types of climate engineering are highly controversial due to the large uncertainties around effectiveness, side effects and unforeseen consequences. Interventions at large scale run a greater risk of unintended disruptions of natural systems, resulting in a dilemma that such disruptions might be more damaging than the climate damage that they offset. However, the risks of such interventions must be seen in the context of the trajectory of climate change without them.
Terminology
Climate engineering (or geoengineering) has been used as an umbrella term for both carbon dioxide removal and solar radiation management, when applied at a planetary scale.: 168 However, these two methods have very different geophysical characteristics, which is why the Intergovernmental Panel on Climate Change no longer uses this term.: 168 This decision was communicated in around 2018, see for example the Special Report on Global Warming of 1.5 °C.: 550
According to climate economist Gernot Wagner the term geoengineering is "largely an artefact and a result of the term's frequent use in popular discourse" and "so vague and all-encompassing as to have lost much meaning".: 14
Specific technologies that fall into the climate engineering umbrella term include:: 30
Carbon dioxide removal
Biochar: Biochar is a high-carbon, fine-grained residue that is produced via pyrolysis
Bioenergy with carbon capture and storage (BECCS): the process of extracting bioenergy from biomass and capturing and storing the carbon, thereby removing it from the atmosphere.
Direct air capture and carbon storage: a process of capturing carbon dioxide directly from the ambient air (as opposed to capturing from point sources, such as a cement factory or biomass power plant) and generating a concentrated stream of CO2 for sequestration or utilization or production of carbon-neutral fuel and windgas.
Enhanced weathering: a process that aims to accelerate the natural weathering by spreading finely ground silicate rock, such as basalt, onto surfaces which speeds up chemical reactions between rocks, water, and air. It also removes carbon dioxide (CO2) from the atmosphere, permanently storing it in solid carbonate minerals or ocean alkalinity. The latter also slows ocean acidification.
Solar Radiation Management
Marine cloud brightening: a proposed technique that would make clouds brighter, reflecting a small fraction of incoming sunlight back into space in order to offset anthropogenic global warming.
Mirrors in space (MIS): satellites that are designed to change the amount of solar radiation that impacts the Earth as a form of climate engineering. Since the conception of the idea in 1923, 1929, 1957 and 1978 (Hermann Oberth) and also in the 1980s, space mirrors have mainly been theorized as a way to deflect sunlight to counter global warming and were seriously considered in the 2000s.
Stratospheric aerosol injection (SAI): a proposed method to introduce aerosols into the stratosphere to create a cooling effect via global dimming and increased albedo, which occurs naturally from volcanic eruptions.
The following methods are not termed climate engineering in the latest IPCC assessment report in 2022: 6–11 but are included under this umbrella term by other publications on this topic:
Passive daytime radiative cooling: technology that increases the Earth's solar reflectance and thermal emittance in the atmospheric window.
Ground-level albedo modification: increasing Earth's albedo by modifying objects on the Earth's surface. Examples include planting light-colored plants to help with reflecting sunlight back into space.
Glacier stabilization: interventions to slow down or prevent sea level rise caused by the collapse of notable marine-terminating glaciers, such as Jakobshavn Glacier in Greenland or Thwaites Glacier and Pine Island Glacier in Antarctica. It may be possible to bolster some glaciers directly, but blocking the flow of ever-warming ocean water at a distance, allowing it more time to mix with the cooler water around the glacier, is likely to be far more effective.
Ocean geoengineering (adding material such as lime or iron to the ocean to affect its ability to sequester carbon dioxide).
Technologies
= Carbon dioxide removal
=
= Solar radiation modification
=
= Passive daytime radiative cooling
=
Enhancing the solar reflectance and thermal emissivity of Earth in the atmospheric window through passive daytime radiative cooling has been proposed as an alternative or "third approach" to climate engineering that is "less intrusive" and more predictable or reversible than stratospheric aerosol injection.
= Ocean geoengineering
=
Ocean geoengineering involves modifying the ocean to reduce the impacts of rising temperature. One approach is to add material such as lime or iron to the ocean to increase its ability to support marine life and/or sequester CO2. In 2021 the US National Academies of Sciences, Engineering, and Medicine (NASEM) requested $2.5 billion funds for research in the following decade, specifically including field tests.
Another idea is to reduce sea level rise by installing underwater "curtains" to protect Antarctic glaciers from warming waters, or by drilling holes in ice to pump out water and heat.
Ocean liming
Enriching seawater with calcium hydroxide (lime) has been reported to lower ocean acidity, which reduces pressure on marine life such as oysters and absorbs CO2. The added lime raised the water's pH, capturing CO2 in the form of calcium bicarbonate or as carbonate deposited in mollusk shells. Lime is produced in volume for the cement industry. This was assessed in 2022 in an experiment in Apalachicola, Florida in an attempt to halt declining oyster populations. pH levels increased modestly, as CO2 was reduced by 70 ppm.
A 2014 experiment added sodium hydroxide (lye) to part of Australia's Great Barrier Reef. It raised pH levels to nearly preindustrial levels.
However, producing alkaline materials typically releases large amounts of CO2, partially offsetting the sequestration. Alkaline additives become diluted and dispersed in one month, without durable effects, such that if necessary, the program could be ended without leaving long-term effects.
Ocean sulfur cycle enhancement
Enhancing 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. Such fertilization, especially in the Southern Ocean, would enhance dimethyl sulfide production and consequently cloud reflectivity. This could potentially be used as regional SRM, to slow Antarctic ice from melting. Such techniques also tend to sequester carbon, but the enhancement of cloud albedo also appears to be a likely effect.
Iron fertilization
Submarine forest
Another 2022 experiment attempted to sequester carbon using giant kelp planted off the Namibian coast. Whilst this approach has been called ocean geoengineering by the researchers it is just another form of carbon dioxide removal via sequestration. Another term that is used to describe this process is blue carbon management and also marine geoengineering.
= Glacier stabilization
=
Problems and risks
Interventions at large scale run a greater risk of unintended disruptions of natural systems, alongside a greater potential for reducing the risks of warming. This raises a question of whether climate interventions might be more or less damaging than the climate damage that they offset.
Matthew Watson, of the University of Bristol, led a £5m research study into the potential adverse effects of climate engineering and said in 2014, "We are sleepwalking to a disaster with climate change. Cutting emissions is undoubtedly the thing we should be focusing on but it seems to be failing. Although geoengineering is terrifying to many people, and I include myself in this, [its feasibility and safety] are questions that have to be answered". University of Oxford Professor Steve Rayner is also worried about the adverse effects of climate engineering, especially the potential for people to be too positive about the effects and stop trying to slow the actual problem of climate change. Though, he says there is a potential reason to doing climate engineering: "People decry doing [climate engineering] as a band aid, but band aids are useful when you are healing".
Climate engineering may reduce the urgency of reducing carbon emissions, a form of moral hazard. Also, some approaches would have only temporary effects, which implies rapid rebound if they are not sustained. The Union of Concerned Scientists points to the concern that the use of climate engineering technology might become an excuse not to address the root causes of climate change. However, several public opinion surveys and focus groups reported either a desire to increase emission cuts in the presence of climate engineering, or no effect. Other modelling work suggests that the prospect of climate engineering may in fact increase the likelihood of emissions reduction.
Climate engineering also raises moral questions about the relationship between humans and their environment, and under what conditions humans have the right to deliberately change the climate. Some religious traditions express views on the relationship between humans and their surroundings that either encourage or discourage explicit actions to affect climate, depending on the objective. For example, using climate engineering to stabilize temperatures may be seen as an example of stewardship and therefore encouraged. Conversely, climate engineering may be discouraged if is perceived as human overconfidence and hubris.
Governance issues
Governance issues relating to carbon dioxide removal are distinct from those surrounding CE. The key governance problem for carbon dioxide removal (as with emissions reductions) is making sure actors do enough of it (minimizing "free riders"), whereas the key governance issue for CE is making sure actors do not do it too much (managing "free drivers").
No universally agreed framework for the regulation of CE activity or research has been established. Scholars at the Oxford Martin School at Oxford University proposed a set of principles to guide climate engineering research and use. The short version is:
Regulate as a public good.
Public participation in decision-making
Disclose research and open publication of results
Independent assessment of impacts
Governance before deployment
These principles were endorsed by the House of Commons of the United Kingdom Science and Technology Select Committee on "The Regulation of Geoengineering".
The Asilomar International Conference on Climate Intervention Technologies was convened to identify and develop risk reduction guidelines for climate intervention experimentation.
The Parties to the Convention on Biological Diversity made three decisions on what they termed "climate-related geo-engineering." A decision in 2010 called on countries to refrain from "climate-related geo-engineering activities that may affect biodiversity" until they are governed, are scientifically justified, and associated risks have been considered. Some critics describe this as a "de facto moratorium," but the Secretariat of the Convention on Biological Diversity calls it a “non-binding normative framework.” Legal scholars Scott and Reynolds separately reject this characterization. The 2016 decision called for "more transdisciplinary research and sharing of knowledge among appropriate institutions is needed in order to better understand the impacts."
Society and culture
= Public perception
=
A large 2018 study used an online survey to investigate public perceptions of six climate engineering methods in the United States, United Kingdom, Australia, and New Zealand. Public awareness of climate engineering was low; less than a fifth of respondents reported prior knowledge. Perceptions of the six climate engineering methods proposed (three from the carbon dioxide removal group and three from the solar radiation modification group) were largely negative and frequently associated with attributes like 'risky', 'artificial' and 'unknown effects'. Carbon dioxide removal methods were preferred over solar radiation modification. Public perceptions were remarkably stable with only minor differences between the different countries in the surveys.
Some environmental organizations (such as Friends of the Earth and Greenpeace) have been reluctant to endorse or oppose solar radiation modification, but are often more supportive of nature-based carbon dioxide removal projects, such as afforestation and peatland restoration.
Research and projects
Several organizations have investigated climate engineering with a view to evaluating its potential, including the US Congress, the US National Academy of Sciences, Engineering, and Medicine, the Royal Society, the UK Parliament, the Institution of Mechanical Engineers, and the Intergovernmental Panel on Climate Change.
In 2009, the Royal Society in the UK reviewed a wide range of proposed climate engineering methods and evaluated them in terms of effectiveness, affordability, timeliness, and safety (assigning qualitative estimates in each assessment). The key recommendations reports 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". Nonetheless, the report also recommended that "research and development of climate engineering 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".
In 2009, a review examined the scientific plausibility of proposed methods rather than the practical considerations such as engineering feasibility or economic cost. The authors 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". 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".
The IMechE report examined a small subset of proposed methods (air capture, urban albedo and algal-based CO2 capture techniques), and its main conclusions in 2011 were that climate engineering should be researched and trialed at the small scale alongside a wider decarbonization of the economy.
In 2015, the US National Academy of Sciences, Engineering, and Medicine concluded a 21-month project to study the potential impacts, benefits, and costs of climate engineering. The differences between these two classes of climate engineering "led the committee to evaluate the two types of approaches separately in companion reports, a distinction it hopes carries over to future scientific and policy discussions." The resulting study titled Climate Intervention was released in February 2015 and consists of two volumes: Reflecting Sunlight to Cool Earth and Carbon Dioxide Removal and Reliable Sequestration.
In June 2023 the US government released a report that recommended conducting research on stratospheric aerosol injection and marine cloud brightening.
As of 2024 the Coastal Atmospheric Aerosol Research and Engagement (CAARE) project was launching sea salt into the marine sky in an effort to increase cloud "brightness" (reflective capacity). The sea salt is launched from the USS Hornet Sea, Air & Space Museum (based on the project's regulatory filings).
See also
References
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Climate Engineering: Research: Kravitz Research Group: Indiana ...
Climate Engineering: Research: Kravitz Research Group: Indiana ...
Opinion | The Risks of Climate Engineering - The New York Times
Opinion | The Risks of Climate Engineering - The New York Times
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Climate engineering – IAAC BLOG
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Daftar Isi
Climate engineering - Wikipedia
Climate engineering (or geoengineering, climate intervention [1]) is the intentional large-scale alteration of the planetary environment to counteract anthropogenic climate change.
What is Climate Engineering? - Union of Concerned Scientists
Nov 6, 2017 · Climate engineering is the intentional large-scale intervention in the Earth’s climate system to counter climate change. It includes techniques to remove carbon dioxide from the atmosphere , and technologies to rapidly cool the Earth by reflecting solar energy back to space .
A new UN report lays out an ethical framework for climate engineering
Dec 1, 2023 · The new report proposes ethical frameworks for both the study and the later deployment of climate engineering strategies.
Climate Engineering
Our research is focused on climate engineering (also called solar geoengineering and solar radiation management), bringing a system-engineering perspective to this challenge, and with the ultimate goal of informing policy and societal decisions.
Climate engineering: exploring nuances and consequences of …
The objective of Climate Engineering (hereafter CE, but also referred to as ‘Geoengineering’, and sometimes as ‘Solar Radiation Management’) is to offset the warming and some other climate consequences that would otherwise result from increasing greenhouse gas concentrations by reducing the amount of sunlight reaching the Earth's ...
What is geoengineering and how could it help tackle climate …
May 3, 2018 · Geoengineering, also known as climate engineering, describes a range of ways to intervene on a large scale in the Earth’s natural systems – the oceans, soils and atmosphere – to directly combat climate change.
Mapping the landscape of climate engineering - PMC
Defining the boundaries of climate engineering presents particular challenges for a number of reasons: it includes a highly diverse set of proposals using old and new technologies, bound together only by the intention to use them to counteract climate change.
Who might try climate engineering and how? - The Conversation
Apr 4, 2024 · The big question: Would climate engineering like sending reflective particles into the stratosphere or brightening clouds help reduce the national security risks of climate change or make them...
Climate Engineering: Indiana University
Climate engineering (or geoengineering) describes a set of ideas to deliberately modify the climate by reflecting sunlight and cooling the planet while other, more permanent methods of addressing climate change are ramped up.
A Brief Introduction to Climate Engineering - Markkula Center for ...
Climate engineering, according to Harvard’s Solar Geoengineering Program, is a broad category of technologies meant to alter the climate in order to reduce climate change. There are two main types of climate engineering: carbon dioxide removal and solar radiation management [1].
