Waste Valorization in a Sustainable Bio-Based Economy: The Road to Carbon Neutrality.
Roger A SheldonPublished in: Chemistry (Weinheim an der Bergstrasse, Germany) (2024)
The development of sustainable chemistry underlying the quest to minimize and/or valorize waste in the carbon-neutral manufacture of chemicals is followed over the last four to five decades. Both chemo- and biocatalysis have played an indispensable role in this odyssey. in particular developments in protein engineering, metagenomics and bioinformatics over the preceding three decades have played a crucial supporting role in facilitating the widespread application of both whole cell and cell-free biocatalysis. The pressing need, driven by climate change mitigation, for a drastic reduction in greenhouse gas (GHG) emissions, has precipitated an energy transition based on decarbonization of energy and defossilization of organic chemicals production. The latter involves waste biomass and/or waste CO 2 as the feedstock and green electricity generated using solar, wind, hydroelectric or nuclear energy. The use of waste polysaccharides as feedstocks will underpin a renaissance in carbohydrate chemistry with pentoses and hexoses as base chemicals and bio-based solvents and polymers as environmentally friendly downstream products. The widespread availability of inexpensive electricity and solar energy has led to increasing attention for electro(bio)catalysis and photo(bio)catalysis which in turn is leading to myriad innovations in these fields.
Keyphrases
- climate change
- municipal solid waste
- heavy metals
- life cycle
- sewage sludge
- cell free
- working memory
- anaerobic digestion
- single cell
- radiation therapy
- wastewater treatment
- squamous cell carcinoma
- high resolution
- drug discovery
- rectal cancer
- small molecule
- combination therapy
- visible light
- cancer therapy
- living cells
- high speed
- locally advanced
- water soluble
- protein protein
- low cost