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Also known as: geo-engineering

The carbon-removal approach would extract CO2 from other gases in the atmosphere by changing it into other forms of carbon (such as carbonate) through photosynthesis or artificial “scrubbing.” This separated carbon then would be either sequestered in biomass at the surface or transported away for storage in the ocean or underground. Several carbon-removal geoengineering schemes have been considered. These include carbon burial, ocean fertilization, biochar production, and scrubbing towers or “artificial trees.”

Carbon burial

Carbon burial, more commonly known as carbon capture, utilization, and storage (CCUS), involves the pumping of pressurized CO2 into suitable geological structures (that is, with gas-tight upper layers to cap the buried carbon) deep underground or in the deep ocean (see carbon sequestration). The premise is that CO2 generated from the combustion of fossil fuels could be separated from other industrial emissions before these emissions were released into the atmosphere. Carbon dioxide could then be pumped through pipes into geological formations and stored for extended periods of time. The process of carbon burial requires the identification of many suitable sites followed by stringent leak-testing of individual sites. So far, injections of compressed CO2 have been used to aid in the extraction of natural gas, such as in the Sleipner Vest field in the North Sea, and the United States Department of Energy has funded the construction of several carbon-storage sites. In 2019 some 49.3 million metric tons (54.3 million tons) of carbon dioxide were injected underground in the United States. Although the majority of existing CCUS facilities occur in the United States and Europe, CCUS investment has expanded worldwide since 2017, with several governments, such as those of China, Australia, and New Zealand, announcing plans to expand their capacity. The carbon-burial process could also make use of carbon dioxide captured from the atmosphere using scrubbers (see below Scrubbers and artificial trees).

Ocean fertilization

Ocean fertilization would increase the uptake of CO2 from the air by phytoplankton, microscopic plants that reside at or near the surface of the ocean. The premise is that the phytoplankton, after blooming, would die and sink to the ocean floor, taking with them the CO2 that they had photosynthesized into new tissues. Although some of the material that sank would be returned to the surface through the process of upwelling, it is thought that a small but significant proportion of the carbon would remain on the ocean floor and become stored as sedimentary rock.

Ocean fertilization, which some scientists refer to as bio-geoengineering, would involve dissolving iron or nitrates into the surface waters of specific ocean regions to promote the growth of phytoplankton where primary productivity is low. For the scheme to be effective, it is thought that a sustained effort would be required from a fleet of vessels covering most of the ocean. Many authorities maintain that this scheme would take decades to unfold.

Biochar production

The production of biochar, a type of charcoal made from animal wastes and plant residues (such as wood chips, leaves, and husks), can sequester carbon by circumventing the normal decomposition process or acting as a fertilizer to enhance the sequestration rate of growing biomass. Normally, as organic material decomposes, the microbes breaking it down use oxygen and release CO2. If, however, the material were “cooked” in the absence of oxygen, it would decompose rapidly through pyrolysis. Little or no CO2 would be released, and the bulk of the organic material would harden into a kind of porous charcoal, essentially sequestering the carbon as a solid. Biochar mixed with soils might serve as a fertilizer, thus further increasing the carbon sequestration potential of plants growing in the soil. Some environmentalists see biochar as a breakthrough in carbon-sequestration technology, but its ability to reduce CO2 concentrations at global scales is a matter of some debate. In addition, some scientists see problems in ramping up the biochar production process to global scales, since farmers would have to decide between making charcoal for fertilizer or burning plant residue in cooking fires.

Direct air capture

Another form of carbon capture, called direct air capture (DAC), would involve the use of scrubbing towers and so-called artificial trees. In the scrubbing tower method, air would be funneled into a large confined space within the towers by wind-driven turbines. As the air is taken in, it would be sprayed with one of several chemical compounds, such as sodium hydroxide, potassium hydroxide, or calcium hydroxide. These chemicals would react with the CO2 in the air to precipitate carbonate salts or react with water to form weak acids. These by-products could then be piped to permanent safe storage locations, such as gaps between layers of rock. Since these acids react easily with basalt rocks to mineralize into carbonate rocks in only a few years, chemists and climate scientists note that basalt formations, which occur in volcanic landscapes, could be useful storage locations. Since the world’s oceans absorb about 31 percent of carbon dioxide emissions from the atmosphere, similar methods designed to extract carbon dioxide from seawater have been proposed.

In contrast, artificial trees essentially would be a series of sticky, resin-covered filters that would convert captured CO2 to a carbonate called soda ash. Periodically, the soda ash would be washed off the filters and collected for storage.

So far, several prototypes of each method have been built. Most scientists argue that thousands of scrubbing towers would be needed to counteract rising atmospheric carbon dioxide concentrations at global scales. Reports estimate that even with drastic cuts in carbon dioxide emissions, more than 10 billion metric tons (11 billion tons) of carbon dioxide would need to be removed from the atmosphere per year to hold the average temperature increases from global warming to 1.5 °C (2.7 °F).

Philip Boyd The Editors of Encyclopaedia Britannica