A Carbon Market for Aviation could Spur the Growth of NETs

There is an increasing need to curtail emissions from airlines. Traditional air travel generates some of the most damaging greenhouse gases but if carbon markets were used by the aviation industry it could provide a massive and much needed boost to negative emission technologies (NETs). Air travel currently accounts for about 2 percent of global carbon emissions but they are expected to quadruple by 2050.

A program knows as the "Carbon Offsetting and Reduction Scheme for International Aviation" (CORSIA) could curtail emissions and maximize airline efficiency while advancing research and development in NETs. This program leverages a global carbon credit program to impose caps on CO2 emissions from international flights at 2020 levels.

CORSIA would not only drive investment in NETs it would also provide incentives for the development of low-carbon fuels. It is estimated that in the first decade and a half CORSIA, would generate between 2.5 billion and 3 billion tons worth of carbon offsets. This is a powerful inducement for companies looking to capitalize. It could even drive the growth of emissions free airships and generate investments that could address some of the limitations of electric aviation.

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Examples of Carbon Capture Technology

The need for negative emission technologies (NETs) is becoming increasingly apparent in the wake of our failure to draw-down atmospheric greenhouse gases. Plants can harvest the CO2 from the air and sequester it or sell it for agricultural or industrial applications. It can also be recycled and used to make synthetic fuel. This means that the same CO2 molecules could be used over and over again. Here are four examples of carbon capture technologies that may prove to be critical to our efforts to keep global temperatures from rising above the upper threshold limits. The first two suck carbon out of the air or water and the other two are used at source to capture carbon emissions.

Land based

Direct air capture plants could involve banks of fans blowing air through a carbon dioxide (CO2) capturing solution. It works using using high-tech sponge like filters and fans. In one such application fans pull in the surrounding air and chemically coated filters absorb the CO2, filters are heated up to 100C and very pure carbon dioxide gas is then collected. This approach is fully carbon negative (smokestack removal is carbon neutral) and in theory it could remove more greenhouse gas from the atmosphere than trees.

Marine based

Other related applications take the form of giant floating islands that are clustered together in a marine environment to remove CO2 from the water and turn it into fuel. These so called solar methanol islands use renewable energy (solar) to recycle atmospheric CO2 into synthetic fuels. They produce no net CO2 emission because they use photovoltaic cells to convert solar energy into electricity to power hydrogen production and CO2 extraction from seawater. Although technical challenges remain, the researchers estimate that 3.2 million floating islands that are one kilometer squared (0.4 square miles) would exceed the total global emissions from fossil fuels. However, researchers will need to develop a large scale device to extract CO2 from seawater as well as find a way to protect solar panels from degradation in an ocean environment.

Polymer membranes

Other approaches involve membranes. One such approach employs a wet polymer "nanostructured" membrane that filters fossil fuel emissions to separate out the carbon. A polymer is a substance composed of long-chain molecules. Many plastics are polymers, but they are also found in nature as proteins, cellulose and glass. The polymer used in this application is called poly[tert-butylstyrene-b-(ethylene-alt-propylene)-b-(styrene-r-styrenesulfonate)-b-(ethylene-alt-propylene)-b–tert-butylstyrene]. It has been nicknamed TESET. The material is already in commercial use and is therefore readily available.

Graphene membranes

One of the most promising polymer membranes for CO2 filtration are made of graphene oxide. Graphene is the world’s thinnest and strongest material. It consists of one layer of carbon atoms organized in a hexagonal pattern.

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Negative Emission Technologies are Our Last Hope

Negative emission technologies (NETs) are a necessary technological innovation. Such technologies reduce atmospheric emissions by removing CO2 from the point at which they are generated or from the ambient air. Rising emissions and dwindling carbon budgets make it abundantly clear that we need to find a way to drastically reduce atmospheric carbon.


Some NET technologies can be costly, controversial and many are still in the early phase of testing. However, other NETs are ready to be deployed at scale, this includes land management practices that store more carbon in agricultural soils and forests. However, there’s no way those methods alone could ever capture enough carbon to keep Earth’s temperature from rising another degree.

Other technological solutions need more research. This includes technologies that mimic natural rock weathering practices on a vastly accelerated time scale. Although there are prototypes of air capture machines that suck carbon out of the atmosphere and store it underground, the technology is unproven at scale.

Even under the most optimistic scenarios the transition from fossil fuels to clean sources of energy like renewables will take time and if we are to have a shot at keeping global temperatures below the upper threshold limit GHG emissions will need to be prevented from reaching the atmosphere. According to the IPCC and almost all climate models, cutting CO2 emissions over the next few decades won't be enough to stop climate change.

"It's not a question of 'Maybe we'll need negative emissions technologies or maybe we can prevent more CO2 from going into the air,’" Erin Burns, a senior policy advisor at the think tank Third Way, told Business Insider. "We are at a point where we need all of those things," Burns said. As explained by Kate Gordon, a fellow at Columbia University’s Center on Global Energy Policy, "We need to be committed to it today, because we know from all the modeling that's happening that this is not an if question, it's a when question."

A study from the National Academies of Sciences, Engineering, and Medicine recently estimated that to meet climate targets, the world will need to remove as much as 10 gigatons of CO2 from the atmosphere each year by mid-century. The study suggests NETs have an unlimited capacity for reducing carbon levels in the atmosphere. The study supports investments in materials that naturally attract and bind with carbon. That carbon would then get concentrated and stored, perhaps by injecting it into pores in deep underground rock.

As reported by the Guardian,  Bill Hare of Climate Analytics, a science and policy institute thinks NETs are essential despite the concerns raised by Corinne Le Quéré, director of the Tyndall Centre for Climate Change Research at the University of East Anglia.  Efforts to store captured carbon underground are "showing no progress … and even backwards steps in some cases", said Le Quéré.

"[I]f you’re really concerned about coral reefs, biodiversity [and] food production in very poor regions, we’re going to have to deploy negative emission technology at scale," said Hare, adding, "I don’t think we can have confidence that anything else can do this...we will need geoengineering by the mid-2030s to have a chance at the [1.5C] goal". 

The costs of such technologies are sometimes put forward as a constraint, however there is reason to believe that technological advancements can reduce costs. As we research and scale these technologies the price can be expected to decline substantially and as we ebb ever closer to tipping points the costs may become secondary to survival.

"[T]he world no longer has the luxury of waiting for emission reduction strategies to do the job alone. Far from being a Plan B, NETs must be a critical part of Plan A, and embracing them sooner rather than later makes economic sense," said Nat Keohane the Senior Vice President of EDF's Climate program. "Because the marginal costs of emission reductions rise as more emissions are cut, it will be cheaper to deploy NETs at the same time as emission reduction technologies rather than waiting to exhaust those options first."

There is justifiable concern that investments in NETs will diminish the pressure to quickly cut emissions. We cannot afford to ignore proven approaches, such as improving energy efficiency, promoting cleaner transport, eating less meat and scaling up renewable energies. While emissions reduction must remain a dedicated focus of international attention, we will also need to invest billions to develop and scale NET technologies.

The University of Tasmania professor Pete Strutton indicated that NETs are critical. "There is no way for Earth to stay below 3 C without large-scale emissions capture and storage, in addition to massive emissions reduction," he said. Strutton warned that governments and individuals will need to act quickly if we are to scale these technologies in time.

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