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61,005 resultsShowing papers similar to Photocatalytic upcycling of PET into methane, hydrogen and high-value liquid products
ClearPhotoreforming of PET and PLA microplastics for sustainable hydrogen production using TiO2 and g-C3N4 photocatalysts
Researchers used photoreforming—a light-driven process—to break down PET and PLA microplastics while simultaneously generating hydrogen gas, demonstrating a dual-benefit approach that addresses plastic pollution while producing clean energy from waste plastic.
H2 Production from Real Wastes of Polyethylene Terephthalate and Polylactic Acid using CNx/Ni2P Nanocatalyst
Researchers developed a photocatalytic process using a novel nanocatalyst to convert real plastic waste from PET bottles and PLA bioplastics into hydrogen gas. The process achieved maximum hydrogen yields of 124 and 267 micromol per gram for PET and PLA respectively, offering a dual benefit of plastic waste valorization and clean energy production.
Pollutants to Products: A Tailored Multicomponent Photocatalyst for Simultaneous CO 2 and Plastic Waste Conversion
Researchers developed a photocatalyst that simultaneously converts CO2 and PET plastic waste into useful chemicals (CO, methane, ethylene glycol) using only light, with CO2 reduced at over 95% selectivity. The dual-use design eliminates the need for chemical sacrificial agents by using plastic as the electron donor for CO2 reduction. Beyond plastic recycling, the system also suggests a pathway for degrading microplastics, offering a single solar-driven process that tackles two major pollution problems at once.
Electrocatalytic upcycling of polyethylene terephthalate to commodity chemicals and H2 fuel
Researchers developed an electrocatalytic process that breaks down waste PET plastic (the kind used in water bottles) into valuable chemicals and clean hydrogen fuel using a specially designed nickel-cobalt catalyst. The process achieved high efficiency at industrial-scale current densities, offering a potentially profitable way to recycle plastic waste into useful products.
Electro-upcycling of PET plastic coupled with hydrogen production using the NiCe@NiTe electrocatalyst
Researchers coupled electrochemical PET plastic degradation with hydrogen production using a nickel-cerium telluride electrocatalyst, demonstrating that PET microplastics can be simultaneously upcycled into value-added chemicals while generating clean hydrogen fuel.
Photoreforming of Nonrecyclable Plastic Waste over a Carbon Nitride/Nickel Phosphide Catalyst
A carbon nitride/nickel phosphide photocatalyst was used to photoreform non-recyclable PET and PLA plastic waste at ambient temperature, producing clean hydrogen fuel and organic chemicals without precious metals or toxic components. The study demonstrates a low-energy, scalable approach to converting plastic waste into valuable chemical feedstocks using sunlight.
From photocatalysis to photon–phonon co-driven catalysis for methanol reforming to hydrogen and valuable by-products
This review covers hydrogen production from methanol using light-driven chemical reactions, examining new photocatalytic materials and methods. While not about microplastics directly, the clean energy technologies discussed could help reduce fossil fuel dependence and the plastic production that drives microplastic pollution.
Brookite TiO2 as an active photocatalyst for photoconversion of plastic wastes to acetic acid and simultaneous hydrogen production: Comparison with anatase and rutile
Researchers found that a specific form of titanium dioxide called brookite can use sunlight to simultaneously break down PET plastic waste and produce hydrogen fuel. The process converts microplastics in water into acetic acid (vinegar), offering a way to both clean up plastic pollution and generate clean energy. This technology could eventually help address microplastic contamination in water while producing a useful byproduct.
From waste to energy - Photocatalytic anaerobic degradation of microplastics to generate hydrogen
Researchers demonstrated that microplastic particles can serve as solid hydrogen sources in anaerobic photocatalytic reactions using titanium dioxide as a catalyst. This proof-of-concept converts plastic waste into clean hydrogen fuel while potentially reducing environmental microplastic loads.
Exploration of operating conditions in the direct aqueous-phase reforming of plastics
This study explored direct aqueous-phase reforming of polyethylene terephthalate plastic as a way to produce hydrogen and alkanes, testing the effects of temperature, pH, and catalyst type. Platinum catalysts at 220 degrees Celsius produced up to 10 mmol of hydrogen per gram of plastic in 8-hour reactions.
Comprehensive Insights into Photoreforming of Waste Plastics for Hydrogen Production
This review examines photocatalytic "photoreforming" — a solar-powered process that breaks down waste plastics while simultaneously generating hydrogen fuel and useful chemical byproducts. Recent advances in catalyst design, including semiconductor materials and metal-organic frameworks, are analyzed alongside factors like light intensity and pH that affect hydrogen output. This dual-purpose approach could help address both the global plastic waste crisis and the need for clean energy simultaneously.
Chemoenzymatic Photoreforming: A Sustainable Approach for Solar-fuel Generation from Plastic Feedstocks
Researchers developed a hybrid process combining enzyme pretreatment with solar-driven photoreforming to convert polyester plastic waste into clean hydrogen fuel and valuable chemicals under mild conditions. This approach offers a way to clean up plastic pollution while generating renewable energy simultaneously.
Building a bridge from solid wastes to solar fuels and chemicals via artificial photosynthesis
This review examined photoreforming (PR) as a process that converts solid plastic and other waste materials into hydrogen fuel and value-added chemicals using solar energy, combining waste remediation with clean fuel production. The authors assessed photocatalyst design strategies that enable efficient PR of diverse waste streams including polyethylene and polypropylene.
Visible Light Photocatalysis: Green Hydrogen Production
Not relevant to microplastics — this paper describes strategies for using visible-light photocatalysis to generate green hydrogen fuel from organic compounds and cellulose waste, an energy research topic unrelated to microplastic pollution.
Recovering hydrogen from PS, LDPE and HDPE microplastics via UV-driven photolysis and TiO2-based photocatalysis
Scientists used UV light — both direct photolysis and titanium dioxide photocatalysis — to break down polystyrene, LDPE, and HDPE microplastics and capture the released hydrogen gas as a potential clean fuel. The dataset documents hydrogen yields and conditions across the different plastic types and treatment methods. This approach could offer a dual benefit: destroying plastic waste while generating renewable hydrogen energy.
Bimetallic defect-engineered CoMoMOF modulates CdZnS for efficient hydrogen production from water/microplastic waste
Researchers created a novel photocatalyst combining metal-defect-engineered materials to simultaneously generate hydrogen fuel and break down PET plastic waste using light energy. The system produced significantly more hydrogen using PET microplastics as a feedstock compared to water alone, suggesting plastic waste could serve as a raw material for clean energy production. This "waste to fuel" approach could address both the plastic pollution crisis and the energy transition, though it remains at an early laboratory stage.
Systemically Understanding Aqueous Photocatalytic Upgrading of Microplastic to Fuels
This review examines photocatalytic methods for converting microplastic waste into renewable fuels using solar energy. These approaches could transform plastic pollutants into useful energy sources rather than allowing them to accumulate in the environment and food chain.
From waste to energy - Photocatalytic anaerobic degradation of microplastics to generate hydrogen
Researchers demonstrated that microplastics can serve as a hydrogen source in photocatalytic reactions under anaerobic conditions. Using titanium dioxide as a catalyst and UV light, microplastic particles generated hydrogen gas, providing a potential route for converting plastic waste into clean energy. This proof-of-concept opens new possibilities for treating microplastic waste while producing renewable fuel.
Hydrogen Generation from PS and PE Microplastics via UV Photocatalysis
Scientists explored whether UV light—with and without a titanium dioxide photocatalyst—could break down polystyrene and polyethylene microplastics while simultaneously generating hydrogen gas, effectively converting plastic pollution into a clean fuel. Overall degradation rates remain low and practical barriers (particle settling, light penetration) are significant, but the study maps the thermodynamic and chemical conditions that favor reactivity. This dual-purpose approach—pollution remediation plus energy recovery—is an intriguing direction for future research if efficiency can be improved.
Chemoenzymatic Photoreforming: A Sustainable Approach for Solar Fuel Generation from Plastic Feedstocks
Researchers developed a process combining enzyme treatment with solar-powered chemistry to break down polyester plastics into clean hydrogen fuel and valuable chemicals. The enzymatic step first breaks the plastic into smaller molecules under mild conditions, and then sunlight drives the conversion into useful products. The study demonstrates a sustainable way to upcycle plastic waste, including nanoplastics, using renewable energy rather than harsh industrial processes.
Carbon-based Composite Materials as Photocatalyst for Photo-Reforming of Organics to Obtain H2
Researchers investigated carbon-based composite photocatalysts — including Nb2O5 and TiO2 combined with graphene or graphene oxide — for photo-reforming of plastics (PET and PLA) and organic compounds into hydrogen under both UV and natural solar light, finding that composite materials produced significantly more hydrogen than bare semiconductors.
Low Environmental Impact Remediation of Microplastics: Visible-Light Photocatalytic Degradation of PET Microplastics Using Bio-Inspired C,N-TiO2/SiO2 Photocatalysts
Researchers developed bio-inspired carbon and nitrogen co-doped TiO2/SiO2 photocatalysts capable of degrading PET microplastics under visible light, offering a low-energy alternative to UV-based photocatalysis for remediating microplastic contamination in aquatic environments.
Systemically Understanding Aqueous Photocatalytic Upgrading of Microplastic to Fuels
This review examined photocatalytic methods for converting microplastics into valuable fuels in water, summarizing advances in reactants, pretreatments, catalysts, and reactor design while highlighting the need for improved pretreatment processes to enhance efficiency and selectivity.
Facile H2PdCl4-induced photoreforming of insoluble PET waste for C1-C3 compound production
Researchers developed a facile H2PdCl4-induced photoreforming method to convert insoluble PET waste fragments into C1-C3 chemical compounds, addressing a key gap in plastic photoreforming that previously only worked with water-soluble oligomers. The study demonstrated that palladium-mediated photoreforming can handle insoluble PET polymer fractions, expanding the potential scope of light-driven plastic upcycling.