A year after China upended global materials markets by banning imports of much solid waste, the effects are still rippling around the globe. Many U.S. recyclers are awash in materials they formerly sent to China for processing. Some cities with few options are burning recyclables in incinerators.
What would it take to reduce U.S. waste management headaches? These five essential reads offer some insights.
1. Embrace the circular economy
Waste is inevitable when products are designed to be used and then thrown away. Clyde Eiríkur Hull, professor of management at Rochester Institute of Technology, offers an alternative: a circular economy in which products are used, then recycled and remanufactured into new products.
Major U.S. companies, including GM, Caterpillar and Staples, are saving money through recycling and remanufacturing. But Hull says this could be greatly scaled up if the federal government required products to be designed with future reuse in mind and taxed goods that did not comply.
“In an entirely circular economy, the U.S. would most likely still import stuff from abroad, such as steel from China. But that steel would wind up being reused in American factories, employing tax-paying American workers to manufacture new goods,” he writes.
2. Get serious about recycling plastic
Of all materials in the waste stream, plastics pose the biggest challenge. They are used in a myriad of consumer goods, including many single-use items such as straws and cutlery, and can take centuries to break down. Kate O’Neill, professor of global environmental policy at the University of California, Berkeley, compares plastic waste to J.R.R. Tolkien’s One Ring, which “can be permanently destroyed only through incineration at extremely high temperatures.”
O’Neill identifies a number of steps to boost plastic recycling in the United States. They include better consumer education about sorting and disposal; less reliance on single-stream collection, which mixes plastics with other materials; more investment in scrap processing facilities; and steps to manage specific plastic products that are hard to recycle, such as 3D printer waste.
3. Pursue plant-based plastics – and composting
Conventional plastics are derived from fossil fuel, but they can also be made from renewable biological compounds that break down more easily, such as plant sugars. A key challenge with these products is making items that are strong enough to hold up during use but still biodegradable.
“A straw and cup that disintegrate halfway through your road trip are not much use at all,” observes Michigan State University biochemist Danny Ducat, whose lab is using photosynthetic bacteria to synthesize bioplastic feedstocks.
Bioplastics also require investments at the end of their life cycles, Ducat notes. Like other plant-based materials, such as food scraps, they will only degrade readily in composting facilities, where microbes break them down in the presence of oxygen. Buried in landfills, they will persist for decades or centuries, much like conventional plastics. They also are likely to persist if they end up in other cold places with little oxygen, such as the Arctic or deep ocean waters.