by ETH Zurich
Plastics are useful, cheap, and extremely popular. Global demand for them has quadrupled in the last forty years and is expected to continue to rise, with negative consequences for the environment and human health.
The public is aware of the environmental harm caused by plastics, particularly at the end of their life cycle, such as when they release greenhouse gases and air pollutants when burned, or pollute water and soil in the form of microplastics.
Research into the global environmental impact of plastics has also focused primarily on the disposal phase. There are few studies about the production of plastics, which also affects the climate and air quality. However, such an in-depth analysis requires detailed information about supply chains and processes in order to trace the relevant material and energy flows.
“So far, the simplistic assumption has been that the production of plastics requires roughly the same amount of fossil resources as the amount of raw materials contained in plastics—particularly petroleum,” says Livia Cabernard, a doctoral student at the Institute of Science, Technology and Policy (ISTP) at ETH Zurich. The problem here is that the relative significance of production versus disposal has been significantly underestimated.
Through painstaking detective work, the researchers analyzed the climate and health impact of the global plastics supply chain over a 20-year period.
In a study recently published in Nature Sustainability, the researchers reveal that the global carbon footprint of plastics has doubled since 1995, reaching 2.2 billion tons of CO2 equivalent (CO2e) in 2015. This represents 4.5% of global greenhouse gas emissions, and is more than previously thought. Over the same period, the global health footprint of plastics from fine particulate air pollution has increased by 70%, causing approximately 2.2 million disability-adjusted life years (DALYs) in 2015.
For their study, the team determined the greenhouse gas emissions generated across the life cycle of plastics—from fossil resource extraction, to processing into product classes and use, through to end of life, including recycling, incineration, and landfill.
The researchers identify booming plastics production in coal-based, newly industrialized countries such as China, India, Indonesia, and South Africa as the main cause of the growing carbon footprint of plastics. The energy and process heat needed for the production of plastics in these countries comes primarily from the combustion of coal. A small amount of coal is also used as a raw material for plastics.
“The plastics-related carbon footprint of China’s transport sector, Indonesia’s electronics industry and India’s construction industry has increased more than 50-fold since 1995,” explains Cabernard. Globally, coal-based emissions from plastics production have quadrupled since 1995 and now account for nearly half of the global carbon footprint of plastics.
When coal is burned, it produces extremely fine particles that accumulate in the air. Such particulate matter is very harmful to health and can cause asthma, bronchitis, and cardiovascular disease. As more and more coal is used for process heat and electricity, and as a raw material in plastics production, the negative consequences for health are also increasing.
In contrast to earlier estimates, which assumed the use of equal amounts of fuel and raw materials in the production of plastics, the researchers have now proven that twice as much fossil energy is burned for plastics production as is contained as a raw material in plastics.
This affects the assessment of the environmental consequences. “Even in a worst-case scenario in which all plastics are incinerated, their production accounts for the lion’s share of total greenhouse gas and particulate matter emissions,” says Cabernard. The overall production phase of plastics is responsible for the vast majority (96%) of the carbon footprint of plastics.
There had previously only been one publication that examined the global carbon footprint of plastics production. “This study underestimated greenhouse gas emissions, however, because it did not take into account the increasing dependence on coal due to the outsourcing of production processes to coal-based countries,” Cabernard explains.
The researchers used a new method for their study that Cabernard had previously developed in her doctoral thesis under the supervision of Stephan Pfister, senior scientist at the ISTP, and Stefanie Hellweg, professor of ecological systems design at the Institute of Environmental Engineering. This approach involves a multi-regional, input-output analysis that accurately maps global value chains from production to consumption across industries, countries and regions.
*first published in: www.weforum.org