In a groundbreaking discovery, a team of scientists in the United Kingdom have developed a porous material that could potentially store large quantities of greenhouse gases, offering a new tool in the fight against climate change. The material, which resembles a cage made up of smaller molecules, is an organic supermolecule composed of oxygen, nitrogen, and fluorine.
The researchers used computational models to develop this material, which was detailed in a paper published in Nature Synthesis. They believe that certain features of the structure make it an excellent storage option for carbon dioxide and sulphur hexafluoride, both potent greenhouse gases.
Engineering professor Marc Little from Edinburgh’s Heriot-Watt University expressed excitement about the discovery, noting that new porous materials are needed to address major societal challenges. He explained that while planting trees can absorb carbon, it is a slow process, so there is a need for human-made molecules to capture greenhouse gases more efficiently.
This new material could be one solution to this problem. However, there are other options being developed as well. Two-dimensional structures made from boron, with a large surface area, could potentially absorb greenhouse gases from power plants. Researchers are also exploring the use of concrete, a significant emitter of carbon dioxide, in absorbing greenhouse gases.
However, one challenge is transitioning these lab experiments into practical solutions that can be implemented on a larger scale. Scaling up these new materials and technologies to have a meaningful impact on climate change remains a complex challenge. Scientists like Marc Little are working to bridge the gap between laboratory discoveries and real-world applications by addressing these challenges. By doing so, new materials and strategies could play a critical role in combating climate change in the future.