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![]() by Yael Vodovotz | Professor - Ohio State University Columbus OH (SPX) May 31, 2022
To better understand why plastics don't biodegrade, let's start with how plastics are made and how biodegradation works. Oil, also known as petroleum, is a fossil fuel. That means it's made from the remains of very old living organisms, such as algae, bacteria and plants. These organisms were buried deep underground for millions of years. There, heat and pressure turned them into fossil fuels. Petroleum contains a lot of a chemical called propylene. To make plastic, refiners heat the propylene together with a catalyst - a substance that speeds up chemical reactions. This causes individual molecules of propylene to hook together like beads on a string. The chain is called a polymer - a large molecule made of many small molecules strung together. Its name, polypropylene, literally means "many propylenes." And the bonds between these molecules are super strong. When something that is biodegradeable, like a cardboard box, breaks down, microorganisms that are present in nature break down and digest the polymers in it. They do this using enzymes - proteins that help speed up the breakdown of compounds such as lignin, a natural polymer found in plant tissues. If oxygen is present, which usually means the microbes and the thing they are breaking down are exposed to air, the polymers will biodegrade completely. Eventually, all that's left will be carbon dioxide, water and other biological material. Oxygen is essential because it helps the microorganisms that degrade the material live longer. Biodegradation is usually fastest in hot, wet environments where there are enough microorganisms - for example, damp leaves on the ground in a warm tropical forest. But polymers like polypropylene are not abundant in nature. The enzymes in the microorganisms that break down biodegradeable materials don't recognize the bonds that hold polymers together. Eventually, the polymers in plastic waste may break down, perhaps after hundreds of thousands of years. But when it takes such a long time, the damage is already done to the environment. Plastic trash can release harmful chemicals into soil and water, or break into tiny bits that animals, fish and birds eat. In my laboratory, we're developing what we hope will be the plastics of the future - materials that work like regular plastic, but don't spoil the environment because they can degrade when people are done with them. We work with bioplastics - materials that are made by tiny living bacteria. The bacteria make these substances for uses such as storing energy or protecting themselves from their surroundings. They can do this over and over, so we have lots of bioplastic to work with. We blend these polymers with natural rubber, an abundant resource that comes from rubber plants, and with oil removed from waste grounds that are left over from making coffee. The rubber makes our bioplastic flexible, and we chemically modify the coffee ground oil to help make the material flow in the industrial machines that we use to shape it. Making bioplastics isn't cheap, because there is not enough of the different ingredients right now that go into making these materials, and it costs a lot of money to set up the equipment to make them. But when enough people want them, the price will come down. I hope that one day these new biodegradable materials will replace plastics made from fossil fuels.
![]() ![]() Researchers from Goethe University Frankfurt develop new biobattery for hydrogen storage Frankfurt, Germany (SPX) May 27, 2022 The fight against climate change is making the search for carbon-neutral energy sources increasingly urgent. Green hydrogen, which is produced from water with the help of renewable energies such as wind or solar power, is one of the solutions on which hopes are pinned. However, transporting and storing the highly explosive gas is difficult, and researchers worldwide are looking for chemical and biological solutions. A team of microbiologists from Goethe University Frankfurt has found an enzyme in ... read more
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