Provided is a polymer blend composition comprising linear low density polyethylene, a propylene polymer generally having rubber dispersed therein, and a combination of a propylene copolymer and an ethylene copolymer. In one embodiment, there is provided a polymer blend composition comprising 15 to 75 weight percent of a propylene polymer having from 10-60% crystallinity, 30-50 weight percent of a linear low density polyethylene, and a combination of the propylene copolymer and the ethylene copolymer comprising the remainder of the composition.

A system and method for creating and collecting magnetic microplastics effectively combines magnetic material with plastics during their manufacture, thereby producing microplastics that can be easily collected via removal devices equipped with magnetic components. Magnetic particles are mixed with plastic/rubber resins during manufacturing of tires, roofing materials, and other plastic items. The magnetic particles can be made from natural or artificial magnets. After mixing, the partially-magnetic rubber/plastic result can be applied to areas of the manufactured plastic item that have the highest propensity to degrade into microplastic pollutants. For example, the thread of a tire, where friction with the road causes most of the wear, is an optimal location for integration of magnetic particles. When the plastics break down into microplastics, the microplastics can then be collected with magnets. The collected microplastics can then be removed from the magnetic collectors during routine maintenance and subsequently recycled safely.

A system and method for creating and collecting magnetic microplastics effectively combines magnetic material with plastics during their manufacture, thereby producing microplastics that can be easily collected via removal devices equipped with magnetic components. Magnetic particles are mixed with plastic/rubber resins during manufacturing of tires, roofing materials, and other plastic items. The magnetic particles can be made from natural or artificial magnets. After mixing, the partially-magnetic rubber/plastic result can be applied to areas of the manufactured plastic item that have the highest propensity to degrade into microplastic pollutants. For example, the thread of a tire, where friction with the road causes most of the wear, is an optimal location for integration of magnetic particles. When the plastics break down into microplastics, the microplastics can then be collected with magnets. The collected microplastics can then be removed from the magnetic collectors during routine maintenance and subsequently recycled safely.

A multi-layered membrane comprising a first thermoplastic first layer and a second thermoplastic layer, where the second layer includes expandable graphite.

A multi-layered membrane comprising a first thermoplastic first layer and a second thermoplastic layer, where the second layer includes expandable graphite.

A composite roofing membrane is disclosed having upper and lower surfaces. The composite roofing membrane contains, in order, a first membrane, a second membrane, and a nonwoven fleece. The first membrane has a first side and a second side, where the first side of the first membrane forms the upper surface of the composite roofing membrane, and where the first membrane comprises a thermoplastic polymer. The second membrane has a first side and a second side, where the first side of the second membrane is adjacent to and in direct and intimate contact with the second side of the first membrane, and where the second membrane comprises a thermoplastic polymer. There are no fibers or yarns between the first and second membranes. The nonwoven fleece contains a plurality of yarns, has a tensile strength of between 100 and 1000 lb.sub.f, and a tear strength of between 20 and 200 lb.sub.f.

A composite roofing membrane is disclosed having upper and lower surfaces. The composite roofing membrane contains, in order, a first membrane, a second membrane, and a nonwoven fleece. The first membrane has a first side and a second side, where the first side of the first membrane forms the upper surface of the composite roofing membrane, and where the first membrane comprises a thermoplastic polymer. The second membrane has a first side and a second side, where the first side of the second membrane is adjacent to and in direct and intimate contact with the second side of the first membrane, and where the second membrane comprises a thermoplastic polymer. There are no fibers or yarns between the first and second membranes. The nonwoven fleece contains a plurality of yarns, has a tensile strength of between 100 and 1000 lb.sub.f, and a tear strength of between 20 and 200 lb.sub.f.

A multi-layered membrane comprising a first thermoplastic first layer and a second thermoplastic layer, where the second layer includes expandable graphite.

A multi-layered membrane comprising a first thermoplastic first layer and a second thermoplastic layer, where the second layer includes expandable graphite.

A roofing membrane comprising at least one layer of a cured rubber and expandable graphite dispersed within the cured rubber.