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61,005 resultsShowing papers similar to Upcycling Polystyrene
ClearUpcycling of waste plastics: strategies, status-quo, and prospects
This review examines strategies for upcycling waste plastics into valuable products as an alternative to landfilling and incineration, which generate microplastics and carbon emissions respectively. Researchers survey chemical recycling methods including pyrolysis, gasification, and catalytic processes that can convert common plastics like PET, polyethylene, and polystyrene into fuels, chemicals, and new materials. The study highlights the urgent need for more effective recycling technologies to address the growing gap between plastic production and waste management capacity.
Integration with biotechnological approaches for upcycling waste plastics
This review examines the limitations of mechanical, chemical, and thermal plastic recycling approaches — including restricted reprocessing cycles, high energy costs, and toxic emissions — and evaluates biotechnological strategies such as enzymatic and microbial degradation as complementary routes for waste plastic upcycling. The authors argue that integrating biological and chemical processes offers the most promising pathway for effective upcycling while reducing carbon emissions and advancing circular economy goals.
Plastic Waste to Value-Added Products via Recycling and Upcycling
This review examined pathways for converting plastic waste into value-added products through recycling and upcycling, framing solutions within a circular economy approach. The paper surveyed mechanical, chemical, and biological conversion technologies and assessed their potential to reduce plastic waste while generating economically useful outputs.
A mini-review on expanded polystyrene waste recycling and its applications
This mini-review summarizes recycling technologies and emerging applications for expanded polystyrene waste, examining mechanical, chemical, and dissolution recycling methods and their practical feasibility for diverting EPS from landfill in both developed and developing countries.
Polyurethane Foam Waste Upcycling into an Efficient and Low Pollutant Gasification Syngas
Researchers modeled the gasification of polyurethane foam waste under various conditions, finding that optimized thermochemical treatment can convert this common polymer waste into hydrogen-rich syngas with low pollutant output, offering a viable energy recovery pathway for difficult-to-recycle plastic foam materials.
Are Reliable and Emerging Technologies Available for Plastic Recycling in a Circular Economy?
This review examines the current landscape of plastic recycling technologies -- including mechanical, thermal, chemical, and biological depolymerization methods such as pyrolysis -- evaluating their readiness for circular economy integration. It concludes that while recycling rates remain below 10% globally, emerging technologies offer pathways toward closed-loop plastic supply chains, though full-scale implementation requires further development and performance assessment.
Polymer‐Based Recycling Strategies for Plastic Waste: A Comprehensive Review
This comprehensive review evaluates mechanical and chemical recycling strategies for plastic waste, noting that mechanical recycling is widely used but limited by polymer degradation, while chemical recycling offers higher quality recovery but at greater energy and financial cost. The study highlights emerging technologies including AI-assisted sorting, nanotechnology, and biodegradable polymer development as promising approaches for building a more circular plastics economy.
Cutting-edge developments in plastic biodegradation and upcycling via engineering approaches
This review examines how engineering approaches from synthetic biology and metabolic engineering can improve both the breakdown and upcycling of plastic waste. Researchers found that various microorganisms and their enzymes can degrade plastics and convert the resulting monomers into valuable products like biosurfactants, bioplastics, and biochemicals. The study suggests that optimizing microbial pathways and using hybrid chemo-biological approaches could help build a more sustainable circular plastic economy.
Plastics Recycling
This review examines the full landscape of plastic recycling, covering mechanical and chemical recycling processes for major resin types including PE, HDPE, LDPE, PET, polyurethanes, polystyrene, and polypropylene, alongside chemical upcycling of waste plastics into higher-value products. The chapter also addresses the environmental and economic benefits of recycling, plastic resin labelling systems, and the persistent challenges limiting recycling rates globally.
Evaluation of the Viability of 3D Printing in Recycling Polymers
This systematic review explores whether 3D printing technology can help recycle plastic waste, particularly from agriculture. Finding better ways to reuse plastics matters because unrecycled plastic breaks down into microplastics that contaminate soil, water, and eventually the food chain.
Plastic Waste Upcycling: A Sustainable Solution for Waste Management, Product Development, and Circular Economy
This review examined plastic waste upcycling as a sustainable alternative to conventional recycling, covering methods that transform plastic waste into value-added products and support circular economy goals while addressing environmental pollution.
Novel and Accessible Physical Recycling for Expanded Polystyrene Waste with the Use of Acetone as a Solvent and Additive Manufacturing (Direct Ink-Write 3D Printing)
Researchers developed a low-cost method to recycle expanded polystyrene (EPS) waste by dissolving it in acetone and reforming it, offering an accessible alternative to conventional recycling. Keeping polystyrene out of landfills and the environment is relevant to microplastic reduction, since EPS readily breaks down into persistent polystyrene microparticles.
Polymers Recycling: Upcycling Techniques. an Overview
This paper is not about microplastics in a research sense; it is an overview of polymer recycling and upcycling techniques, mentioning microplastic accumulation briefly as motivation but not investigating microplastics directly.
Application of Different Chemical Recycling for Plastics
This review examines chemical recycling methods for plastic waste as alternatives to mechanical recycling, focusing on depolymerization via solvolysis, pyrolysis, and purification processes applicable to PET, polyurethane, and polystyrene. The authors discuss how these approaches convert polymer waste back into feedstock monomers that can be repolymerized, addressing value degradation and sorting limitations inherent to mechanical recycling.
Perspectives on sustainable plastic treatment: A shift from linear to circular economy
This review examines emerging technologies for converting plastic waste into useful chemicals and fuels, including methods like pyrolysis, photocatalysis, and electrocatalysis. Researchers highlight how these approaches could shift plastic management from a throw-away model to a circular economy where waste becomes a resource. The study identifies remaining knowledge gaps and proposes future research directions for sustainable plastic treatment.
Recent Progress in Polyolefin Plastic: Polyethylene and Polypropylene Transformation and Depolymerization Techniques
This review covers new methods for breaking down polyethylene and polypropylene, the two most common types of plastic, into reusable materials. Since mechanical recycling only handles a small fraction of plastic waste, chemical approaches like pyrolysis and hydrogenolysis offer more promising solutions. These techniques are important because the breakdown of these same plastics into microplastics is a major source of environmental and health contamination.
On technological solutions for recycling of recycling of polymer waste: A review
This paper is not directly about microplastics; it reviews technological approaches to recycling polymer waste — mechanical, chemical, and energy-based methods — and analyzes their economic and environmental trade-offs. Better plastic recycling technology is relevant to microplastic prevention insofar as it reduces the amount of plastic that degrades into environmental microplastic particles.
Current Developments in the Chemical Upcycling of Waste Plastics Using Alternative Energy Sources
This review covers chemical upcycling approaches for waste plastics using alternative energy sources such as microwave, ultrasound, and photocatalysis, highlighting their potential to convert mixed plastic waste into valuable chemical feedstocks more efficiently than conventional pyrolysis.
Emerging Technologies for Converting Mixed Plastic Waste into Biodegradable Polymers
Scientists are developing new ways to turn mixed plastic waste (like food containers and shopping bags) into biodegradable materials that naturally break down instead of polluting the environment. This research review summarizes promising techniques that could help reduce the microplastics that end up in our food and water. If these methods can be made affordable and used widely, they could significantly cut plastic pollution and the health risks it poses to humans.
Sustainable Petrochemical Alternatives From Plastic Upcycling
This review examined pathways for upcycling plastic waste into sustainable petrochemical alternatives, addressing the poor end-of-life recovery prospects that allow carbon-rich plastics to degrade into microplastics in landfills and oceans. The paper assessed chemical and thermochemical conversion technologies that could turn plastic waste into feedstocks for the chemical industry.
ПЕРСПЕКТИВИ НИЗЬКОТЕМПЕРАТУРНОГО КАТАЛІТИЧНОГО КРЕКІНГУ ПОЛІСТИРОЛУ ЗА АТМОСФЕРНОГО ТИСКУ
Researchers reviewed low-temperature catalytic cracking of polystyrene at atmospheric pressure as a chemical recycling strategy, emphasizing how it avoids toxic emissions and produces liquid oils and fuel additives. The approach is presented as more energy-efficient than mechanical or thermal recycling methods.
Photocatalytic Upcycling of Plastic Waste: Mechanism, Integrating Modus, and Selectivity
This review examines how photocatalysis, a process that uses light energy to drive chemical reactions, can transform plastic waste into useful products under mild and environmentally friendly conditions. Researchers compared photocatalytic approaches with other methods like heat-based and electrical catalysis, and explored how different experimental setups influence what end products are created. The study suggests that photocatalytic upcycling of plastics is a promising green technology, though challenges remain in improving efficiency and selectivity.
Back cover
Researchers developed a scalable continuous low-pressure hydrothermal processing method to convert polystyrene plastic waste into valuable monomers, operating without catalysts, producing less char than pyrolysis, and requiring substantially lower pressures than supercritical methods.
Plastic Waste Recycling, Applications, and Future Prospects for a Sustainable Environment
This review examines emerging plastic waste recycling strategies including microwave, plasma, and supercritical water conversion, highlighting applications in construction, fuel production, and nanomaterials for a circular economy.