Waste to energy, indispensable cornerstone or circular economy: A mini-review
This mini-review aims at proving that waste-to-energy (WtE) is an essential cornerstone for circular economy (CE). Based on literature, the history of thermal waste treatment over the last 150 years is investigated, from open burning to WtE with resource recovery and final sink function.
by Paul H Brunner and Leo S Morf
Abstract
This mini-review aims at proving that waste-to-energy (WtE) is an essential cornerstone for circular economy (CE). Based on
literature, the history of thermal waste treatment over the last 150 years is investigated, from open burning to WtE with resource recovery and final sink function. The results show that in the past incineration solved the issues it was designed for but often created new and sometimes even worse problems: The introduction of incineration in the 19th century improved urban sanitation, decreased waste volume and prolonged operational life of landfills. But it also polluted the environment, triggering an unprecedented scientific and engineering effort of all stakeholders. Today, WtE is one of the best investigated and optimized technologies in waste management. It enables the recovery of energy as heat and electric power and facilitates the ‘cleaning’ of cycles by the destruction of hazardous organic substances. Recent developments in resource recovery from WtE residues allow to recycle metals and, in the case of sewage sludge, even phosphorus by thermal recycling. Combined with carbon capture and storage technology, WtE stands for a quantifiable contribution to greenhouse gas reduction. Today, WtE is indispensable to reach the goals of CE, namely recycling of energy and materials, supplying safe final sinks for persistent organic substances and minimizing the need for sinks for hazardous inorganic substances.Keywords
Sustainable waste management, circular economy, waste to energy, thermal recycling, safe final sink, energy recovery, resource recovery, carbon capture
Get full article here [external link]published: Waste Management & Research, 12|2023
Keywords: Energy Recovery, Pollution Control, Sustainability, Climate, Resource management, Mixed Waste
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