Scientists Are Engineering Carbon-Storing Plants to Fight Climate Change
One of the biggest environmental challenges we face is the amount of carbon dioxide in the atmosphere. Now, scientists have established a method of engineering plants to address this issue.
For decades, plant biologist Joanne Chory has been investigating the adaptable and diverse nature of plant life, and using these findings to make changes to their growth. Now, her lab at the Salk Institute for Biological Studies is using these findings to create carbon-storing plants that could help ameliorate the effects of climate change.
A group of researchers working under Chory are attempting to create varieties of plants that can remove carbon dioxide from the atmosphere, reducing its heat-trapping effect. The idea revolves around a material called suberin, a waxy substance naturally found in cork.
Suberin is largely composed of carbon and will not biodegrade, meaning that it can last as long as a few thousand years, according to a report from Popular Mechanics. These factors mean that it’s particularly well-suited to storing carbon from the atmosphere.
The majority of suberin is produced by cork trees, but it can also be sourced from the roots of certain plants. Chory’s lab is using cross-breeding to secure a high yield of the substance, working with chickpea plants and other harvest plants to determine the most efficient process. According to Popular Mechanics, Chory anticipates that it will eventually be possible to engineer carbon-storing plants that can produce 20 times the suberin it would typically make.
In a typical growing season, plants can pull as much as 100 gigatons of carbon from the atmosphere as they photosynthesize. Under normal circumstances, much of this is eventually released back into the atmosphere – but by engineering the plants, it can instead be trapped underground as part of the roots.
Suberin is among the most stable forms that carbon can take in soil. Given its long lifespan, this could provide a reliable method of trapping carbon in a way that ensures it won’t seep back into the atmosphere.
Much has been said about the potential for carbon capture techniques to help us address climate change. However, the technique being investigated by Chory’s lab is particularly promising, because it’s based upon processes that are found in nature — albeit with some modification.
The researchers have already looked into just how widespread this practice would have to be in order to have a tangible effect on the environment. According to Chory, if we were to use about five percent of the world’s farmland to grow crops with a high output of suberin, we could store half of the carbon dioxide released into the atmosphere.
Of course, there are some caveats to this proposal. The added suberin output may result in the carbon-storing plants having a smaller yield as food crops. Moreover, five percent of the world’s farmland may be a relatively small proportion, but it’s still an enormous amount of land and, as a result, labor.
Still, this could be a rather cheap way to enact a positive effect on the environment. Chory and her team expect to produce seeds that can be produced on grazing land within the next five years.