We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Acoustic and thermal characterization of a novel sustainable material incorporating recycled microplastic waste
Summary
Researchers created a new eco-friendly foam material by embedding recovered marine microplastics into a bio-based matrix, producing an open-cell insulating material with strong acoustic and thermal properties. The innovation offers a potential path to upcycle hard-to-recycle mixed marine plastic waste into useful building and industrial insulation products.
Worldwide, high plastic consumption leads to huge waste production. Macro and microplastic litter affects habitats everywhere, but especially marine environments. Unfortunately, plastic is particularly difficult to retrieve from the sea, since it tends to break up into smaller pieces due to wind, water movement and solar irradiation. Hence, its end-of-life handling and management has become a major issue. Most of the time recovered plastic waste is landfilled or burnt, since it is composed of an assortment of different polymers and/or has been polluted by salt or other marine substances. For these reasons, new recycling methods for marine litter, pursuing cleaner production criteria, are urgently required. This article presents a brand-new sustainable material, an eco-friendly foam made of waste microplastics incorporated into a bio-matrix. This novel open-cell material can be used as acoustic and thermal insulation for industrial, civil and maritime applications. Thus, an in-depth characterization is depicted, providing evidence of very good insulation properties and revealing how microplastics can be used to customize final acoustic and thermal performances.
Sign in to start a discussion.
More Papers Like This
A sustainable acoustic customization of open porous materials using recycled plastics
Researchers developed a sustainable foamy acoustic material by incorporating recycled marine microplastic waste — polyethylene terephthalate (PET) and polystyrene (PS) — into a bio-based matrix, characterizing samples of different compositions for sound absorption and thermal insulation properties.
Primary study of plastic micro fibre waste for sound absorption applications
Researchers evaluated plastic microfiber waste as a sound absorption material, finding it shows some acoustic performance potential. While focused on acoustic engineering, the study explores a possible end use for recycled plastic fiber waste that would otherwise contribute to microplastic pollution.
Hybrid Chitin-Coffee Ground Biochar Foam for Microplastic Adsorption
Researchers developed a sustainable hybrid foam made from waste seafood chitin and used coffee ground biochar for filtering microplastics from water. The study found that the foam achieved consistently high adsorption efficiency across seawater, river water, and deionized water, particularly for polystyrene microspheres larger than 1 micrometer, offering an eco-friendly approach to microplastic removal.
Development of a Non-Structural Prefabricated Panel Based on Construction and Demolition Waste for Sustainable Construction
This study developed a prefabricated non-structural building panel by combining recycled microplastics with construction and demolition waste in mortar, finding that a 20% construction waste blend achieved compressive strength above 31 MPa and that panels with recycled materials showed up to 39 dB sound reduction and 21°C thermal improvement. The research demonstrates a practical pathway for diverting microplastic waste from the environment by incorporating it into building materials. Using microplastics as a construction input could help reduce both plastic pollution and the environmental footprint of the construction industry.
Performance Characterization and Evaluation of Innovative Cement Mortars and Concretes Made with Recycled EPS
Not relevant to microplastics — this study evaluates the mechanical strength and thermal insulation performance of cement mortars and concretes that incorporate recycled expanded polystyrene (EPS) beads as aggregate, focused on construction materials.