Fact-checked by Grok 2 weeks ago

Polypropylene

Polypropylene (PP), also known as polypropene, is a derived from the of () , with the repeating (C₃H₆)ₙ. It is a linear characterized by s attached to alternate carbon atoms in the chain, existing in three primary stereoisomeric forms: isotactic (highly ordered methyl groups on one side, most common for commercial use), syndiotactic (alternating methyl groups), and atactic (random methyl group placement, typically amorphous and less crystalline). This structure contributes to its semi-rigid, lightweight nature, making it one of the most versatile and widely produced plastics globally. Global production was approximately 91 million metric tons in 2025, second only to . Discovered in 1954 by Italian chemist , building on Ziegler's earlier work with organometallic catalysts, polypropylene was first commercialized in 1957. The typically employs Ziegler-Natta or metallocene catalysts to achieve high isotacticity (90–95%), resulting in a crystalline homopolymer or copolymers blended with for enhanced properties. Polypropylene exhibits a of 0.898–0.908 g/cm³, a of 160–165°C for homopolymers (lower for copolymers at 135–159°C), and a temperature around 0°C. It demonstrates strong resistance to dilute acids, alkalis, alcohols, and bases, while showing poor tolerance to hydrocarbons, chlorinated solvents, and aromatics; it is also water-repellent and electrically insulating. These attributes, along with excellent mechanical properties such as tensile strength of 25–33 and elongation at break of 150–300%, enable its widespread use in packaging, automotive components, consumer goods, textiles, and medical devices. Additionally, its recyclability and low cost further enhance its role in sustainable manufacturing and diverse industrial sectors.

History

Discovery

Early attempts to polymerize propylene date back to the 1930s, when researchers achieved limited success in forming low-molecular-weight products or amorphous materials under high-pressure conditions similar to those used for polyethylene synthesis. These early experiments, often conducted in industrial laboratories, yielded polymers with poor mechanical properties, such as low strength and elasticity, rendering them unsuitable for practical applications. A significant breakthrough occurred in 1951 at , where chemists J. Paul Hogan and Robert L. Banks, while investigating catalysts for converting to , unexpectedly produced a solid, crystalline . Using a modified catalyst on a silica-alumina support, they obtained high-molecular-weight polypropylene that exhibited crystallinity, marking the first instance of a viable stereoregular form. This discovery highlighted the potential of as a feedstock, though initial samples still required refinement. In 1954, Italian chemist at Montecatini (now part of Versalis) achieved the first laboratory synthesis of high-molecular-weight isotactic polypropylene using Ziegler-Natta catalysts, consisting of and aluminum alkyls. Natta's team polymerized at moderate pressures and temperatures, yielding a highly crystalline material with superior rigidity and thermal stability compared to earlier amorphous variants. Initial challenges centered on the distinction between atactic and isotactic forms: atactic polypropylene, produced in uncontrolled polymerizations, was amorphous, rubbery, and lacked structural integrity due to random orientations along the chain, limiting its utility. In contrast, isotactic polypropylene featured regular, identical stereochemical configurations, enabling and desirable properties, but early syntheses often resulted in heterogeneous mixtures requiring to isolate the crystalline fraction. These differences underscored the need for stereospecific catalysts to achieve commercial viability.

Commercial Development

The commercialization of polypropylene followed closely after its laboratory synthesis, propelled by strategic patent filings that protected the underlying polymerization technologies. In 1953, chemists at filed a U.S. for propylene , predating similar efforts elsewhere. Independently, submitted a German on August 3, 1954, describing the use of organoaluminum-titanium catalysts for olefin . Giulio Natta, building on Ziegler's work, filed an Italian patent on June 8, 1954, specifically for the production of isotactic polypropylene, which exhibited superior crystallinity and mechanical properties suitable for industrial applications. These patents, amid legal disputes over priority, enabled licensing and scaled production, culminating in the 1963 awarded jointly to Ziegler and Natta for their pioneering contributions to and technology. The transition to industrial production occurred swiftly, with Montecatini—the Italian firm collaborating with Natta—inaugurating the world's first commercial polypropylene plant in , , in 1957. This facility, utilizing the Ziegler-Natta catalyst system, had an initial annual capacity of around 6,000 tons, focusing on isotactic grades for fibers and injection-molded products. The plant's success validated the process economics, overcoming early challenges in catalyst efficiency and polymer purification, and set the stage for broader adoption. The 1960s witnessed explosive global expansion as polypropylene's low density, chemical resistance, and processability attracted investment from major chemical companies. Hercules Incorporated in the United States launched commercial production in 1957 alongside Montecatini, licensing Natta's technology to produce fibers and resins. Phillips Petroleum, leveraging its earlier patent claims, entered the market with its own high-activity catalyst variant, establishing plants that emphasized slurry-phase for broader applications. Hoechst AG in also scaled up operations during this decade, contributing to a proliferation of facilities across and . By the mid-1960s, these efforts had transformed polypropylene from a novelty into a , with production capacities multiplying through technology transfers and plant constructions. Sustained demand in —for films, bottles, and containers—and automotive components—for bumpers, interiors, and under-hood parts—drove remarkable growth in global production capacity. From modest beginnings in the thousands of tons annually during the late , capacity expanded to exceed 97 million tons per year by 2022, reflecting advancements in productivity, process efficiencies, and regional manufacturing hubs in and the . This scale underscores polypropylene's role as one of the most versatile and widely used plastics, with annual output surpassing that of many traditional materials.

Chemical Structure

Monomer and Polymerization

Polypropylene is synthesized from the monomer , which has the CH₂=CHCH₃ and features a carbon-carbon that facilitates addition . This unsaturated structure allows propylene to undergo chain-growth reactions, where the double bond is broken to form extended chains. The general polymerization reaction involves the addition of multiple propylene units, represented by the equation n \ce{CH2=CH-CH3} \to [-\ce{CH2-CH(CH3)}-]_n, where n denotes the . This process yields a linear polymer backbone with pendant methyl groups attached to every other carbon atom. Polypropylene formation proceeds via mechanisms using Ziegler-Natta catalysts or . Coordination approaches, such as Ziegler-Natta, employ catalysts (e.g., titanium-based) to coordinate with the and insert it into the growing chain with controlled . Metallocene catalysts, often single-site systems like complexes, enable precise control over chain length and uniformity. In these methods, the catalyst is essential for activating the , initiating chain propagation by forming a , and enabling the stepwise addition of monomers to build the carbon-carbon backbone.

Tacticity and Isotactic Forms

in polypropylene refers to the stereochemical of the methyl side groups along the backbone, which arises from the stereospecific of monomers. This arrangement significantly influences the material's properties, with three primary forms distinguished by the regularity of methyl group placement: isotactic, syndiotactic, and atactic. In isotactic polypropylene, the methyl groups are regularly positioned on the same side of the chain, creating a highly ordered structure. Syndiotactic polypropylene features alternating methyl group orientations along the backbone, while atactic polypropylene exhibits a random distribution of these groups, leading to a disordered chain. Isotactic polypropylene is the predominant commercial form, typically exhibiting 95-99% isotacticity, owing to its enhanced crystallinity and mechanical strength compared to the other variants; in contrast, atactic polypropylene remains amorphous and tacky, limiting its utility to niche applications such as adhesives. Tacticity is determined primarily through (NMR) , particularly 13C NMR, which quantifies the distribution of stereosequences such as pentads (e.g., mmmm for isotactic segments) by analyzing peak intensities in spectra obtained from solutions at elevated temperatures. X-ray diffraction complements this by revealing tacticity distributions through patterns of crystalline reflections, allowing differentiation between highly isotactic and more atactic fractions in samples. These methods enable precise characterization essential for in commercial production.

Crystal Structure

Polypropylene, particularly its isotactic form, exhibits polymorphism, with three primary crystal structures that determine its semi-crystalline morphology and influence material performance. The most prevalent is the α-form, characterized by a monoclinic with C2/c, featuring chains in a conformation packed in a parallel arrangement; this form is thermodynamically the most stable and predominates under standard conditions from the melt. The β-form adopts a hexagonal (trigonal) with C2, where chains form a three-fold and exhibit a more open packing; it is metastable and typically forms under , rapid cooling, or with specific nucleating agents like aromatic amides or quinacridones, often leading to sheaf-like spherulites. The γ-form, with an orthorhombic ( F2mm), arises in copolymers with or under high pressure, displaying parallel chain packing similar to the α-form but with shifted layers; it is less common and coexists with other polymorphs in modified polypropylenes. The degree of crystallinity in isotactic polypropylene typically ranges from 30% to 70%, varying with , molecular weight, and processing conditions such as cooling rate and ; higher isotacticity promotes greater crystallinity by enabling ordered chain folding into lamellae. This crystallinity directly impacts the material's , which falls between 0.90 and 0.91 g/cm³ for semi-crystalline samples, lower than fully crystalline values due to amorphous interlamellar regions. In the disordered amorphous or interfacial regions, a smectic-like mesophase can develop, particularly in rapidly quenched samples, where chains adopt a locally ordered, layered without full three-dimensional ; this enhances optical by reducing from large spherulites. X-ray diffraction (XRD) is the primary technique for identifying these polymorphs, with wide-angle XRD patterns revealing distinct reflections: the α-form shows strong peaks at 2θ ≈ 14.1° (110), 16.9° (040), and 18.6° (130); the β-form is distinguished by a peak at 2θ ≈ 16.1° (300), often overlapping with α reflections; and the γ-form exhibits peaks around 2θ ≈ 20° (117/008). These patterns allow quantification of phase content through peak deconvolution, confirming the relative proportions in mixed polymorph samples.

Physical and Chemical Properties

Mechanical Properties

Polypropylene exhibits a range of mechanical properties that make it suitable for applications requiring a balance of strength, flexibility, and durability, particularly in its homopolymer form. The material's tensile strength typically ranges from 30 to 40 for homopolymer grades, providing adequate resistance to pulling forces in structural components. This yield strength value is derived from standard ASTM D638 testing on injection-molded samples, reflecting the polymer's semi-crystalline which contributes to its load-bearing capacity. The tensile modulus, or , for polypropylene homopolymers is generally 1 to 1.5 GPa, indicating moderate that allows deformation under stress without permanent damage. This enables the material to recover from bending or stretching, a key factor in its use for flexible and automotive parts. Elongation at break varies significantly by grade, reaching 400 to 600% in more flexible variants, which highlights its and ability to absorb energy before failure. Impact resistance, measured by notched tests, falls between 2 and 10 kJ/m² for standard homopolymers, offering good toughness against sudden loads without . Polypropylene demonstrates notable fatigue , enduring repeated cyclic loading without rapid crack propagation, which supports its application in living hinges and synthetic fibers that undergo flexing over time. Its creep behavior involves gradual, time-dependent deformation under sustained , with increasing linearly in typical operating conditions, though this can be mitigated by optimizing processing parameters. Higher molecular weight distributions enhance strength and overall toughness by promoting better chain entanglement, while reducing processability. The addition of fillers, such as or fibers, increases tensile and strength—often raising to over 5 GPa in filled composites—but can lower and unless compatibilizers are used. Crystallinity levels, as influenced by , further elevate and tensile strength by up to 20-30% in highly crystalline forms.

Thermal Properties

Polypropylene exhibits distinct thermal behavior influenced by its semicrystalline structure, particularly in its isotactic form, which is the most common commercial variant. The temperature (Tg) for isotactic polypropylene typically ranges from -10°C to 0°C, marking the point where the amorphous regions shift from a glassy to a rubbery state, allowing flexibility at low temperatures but potential below this range. The of isotactic polypropylene is between 160°C and 170°C, varying slightly with crystallinity and molecular weight; this transition involves the disruption of crystalline domains, with higher crystallinity leading to sharper and higher melting peaks. forms, such as the alpha and phases, can modestly affect the melting behavior by altering packing efficiency, though the overall range remains consistent for commercial grades. Key indicators of thermal stability include the , approximately 150°C for homopolymer grades, which measures the temperature at which a specified load causes a defined penetration under controlled heating. The (HDT) under load, such as at 1.8 , is around 50–70°C for unfilled isotactic polypropylene, indicating the point of deformation under combined thermal and mechanical stress. These values highlight polypropylene's suitability for applications requiring moderate heat resistance, though it softens significantly above 140°C. Thermal transport properties are characteristic of an insulating polymer: the thermal conductivity of solid isotactic polypropylene is 0.1–0.2 /m·, enabling effective thermal barrier functions in and . The is approximately 1.9 J/g· at , reflecting the energy required to raise its temperature, which is relevant for processing energy calculations. Additionally, the coefficient of linear is 80–100 × 10^{-6}/, indicating moderate dimensional changes with temperature fluctuations, which must be considered in molded parts to avoid warping.

Chemical Resistance and Degradation

Polypropylene demonstrates strong chemical resistance to many substances, particularly non-oxidizing acids and bases at ambient and moderately elevated temperatures. It remains inert to dilute acids such as 10% and 37% up to 60°C, with minimal weight change or observed during immersion tests. For bases, it exhibits excellent compatibility with solutions like 10-50% , showing no significant attack even at 60°C. This inertness stems from polypropylene's non-polar, hydrophobic structure, which limits penetration by aqueous reagents. However, resistance diminishes with concentrated or oxidizing acids, where polypropylene can suffer surface etching or dissolution; for instance, 98% causes moderate attack at 20°C and severe degradation at 100°C, while fuming leads to poor performance even at . With solvents, polypropylene tolerates polar types like and acetone well at 20-60°C, but non-polar hydrocarbons pose risks at higher temperatures, causing swelling and partial dissolution—xylene, for example, induces noticeable swelling above 60°C due to increased chain mobility. Strong oxidants, such as 30% , also compromise integrity, accelerating oxidative breakdown. These behaviors are assessed via standardized tests like ASTM D543, emphasizing temperature's role in shifting resistance from good to limited or poor. Degradation of polypropylene proceeds mainly through abiotic pathways, including thermal oxidation and photodegradation, with hydrolysis affecting certain copolymers. Thermal oxidation initiates via free-radical reactions with oxygen, forming hydroperoxides that decompose into carbonyl compounds and cause chain scission, particularly above 100°C where rates accelerate. Photodegradation, driven by UV radiation, involves Norrish Type I and II cleavages in amorphous regions, yielding ketones, carboxylic acids, and vinyl groups that embrittle the material. In copolymers like ethylene-propylene variants with ester groups, hydrolysis can occur under prolonged aqueous exposure, breaking ester linkages and reducing molecular weight, though this is less pronounced in homopolymer polypropylene. To mitigate these processes, additives such as primary antioxidants (e.g., hindered phenols) are blended into polypropylene formulations to scavenge free radicals and halt auto-oxidation propagation. The extent of is quantified using the carbonyl index, derived from by measuring absorbance at 1715-1735 cm⁻¹ relative to a reference peak, where values rising above 0.5 indicate significant oxidation after UV exposure. Without such stabilizers, outdoor exposure reduces polypropylene's lifespan, leading to embrittlement and up to 70% loss in mechanical strength within 1-2 years under natural , as UV initiates rapid chain scission. Stabilized variants extend durability by neutralizing radicals and blocking UV absorption, preserving properties for years in applications like .

Optical Properties

Polypropylene exhibits a of approximately 1.49, which governs its light bending characteristics in various applications. In oriented films, such as biaxially oriented polypropylene (BOPP), this property leads to significant , where the varies with the direction of light due to molecular during processing. The optical transparency of polypropylene is highly dependent on its and form. In its crystalline state, polypropylene appears opaque because light scatters at the interfaces between amorphous and crystalline regions, where differences in cause . However, in thin films or grades with low crystallinity, it can achieve translucency, allowing partial light transmission while maintaining some . Standard polypropylene typically shows high values of 80-90%, indicating substantial light scattering that reduces clarity, though clarifying additives can lower this for improved visual appeal. Polypropylene demonstrates UV absorption primarily in the near-ultraviolet range, often exacerbated by impurities such as catalytic residues that act as chromophores and promote photo-oxidative . This absorption can lead to yellowing over time, as conjugated double bonds form and alter the material's color. In BOPP films, these optical traits contribute to high gloss, enhancing surface sheen and printability for uses.

Production

Industrial Synthesis

Polypropylene is produced on an industrial scale through several processes, with the gas-phase method being the most prevalent, accounting for approximately 69% of the polypropylene catalyst market revenue as of 2023. This process utilizes a where gaseous is polymerized in the presence of , which acts as a agent to regulate molecular weight and prevent excessive chain growth. In contrast, slurry processes employ a medium to suspend the growing polymer particles, while bulk liquid processes, also known as liquid polymerization, occur directly in liquid without additional solvents, often in loop reactors for efficient mixing and heat removal. These methods collectively enable high-volume output, with global polypropylene capacity exceeding 100 million metric tons annually as of 2023. Typical reactor conditions for gas-phase include temperatures of 60–80°C and pressures of 20–40 to maintain optimal reaction kinetics and product quality. concentration, typically around 1–2 %, is adjusted to control the polymer's molecular weight distribution, yielding resins with tailored properties for diverse applications. and processes operate under similar temperature ranges but may require additional solvent recovery steps in systems, whereas methods leverage as both and for simplified downstream separation. The resulting polypropylene resins exhibit a range of melt indices (MFI) from 0.5 to 100 g/10 min, determined by the extent of chain termination during ; lower MFI values indicate higher molecular weight for structural applications, while higher values suit flow-intensive processes like thin films. for the polymerization stage is approximately 15–19 MJ/kg for process fuel.

Catalysts and Processes

The synthesis of polypropylene relies on catalytic systems that enable precise control over microstructure, particularly , to achieve desired mechanical properties. Ziegler-Natta catalysts, developed in the mid-20th century, form the cornerstone of industrial polypropylene production. These heterogeneous catalysts typically consist of (TiCl₄) supported on (MgCl₂), activated by an aluminum alkyl co-catalyst such as triethylaluminum (AlEt₃). The MgCl₂ support provides a crystalline lattice that mimics the coordination environment for monomers, facilitating stereospecific insertion and favoring the formation of isotactic polypropylene through 1,2-insertion mechanisms. To enhance isotactic control and suppress atactic byproducts, internal electron donors like ethyl benzoate or external donors such as alkoxysilanes are incorporated, which selectively poison non-stereospecific active sites on the catalyst surface. Metallocene catalysts represent a significant advancement over traditional Ziegler-Natta systems, offering single-site homogeneity for superior uniformity. These organometallic complexes, often based on zirconocene or hafnocene frameworks bridged by ligands like cyclopentadienyl () or indenyl groups, are activated by methylaluminoxane (MAO) to generate cationic active . The constrained geometry of the metallocene ligands enforces specific approach angles, enabling the production of not only isotactic but also syndiotactic polypropylene, which became commercially viable in the through tailored catalyst designs. Unlike multi-site Ziegler-Natta catalysts, metallocenes yield polymers with narrow molecular weight distributions and uniform defect placement, resulting in enhanced clarity and elasticity in the final material. Process variations in polypropylene distinguish between supported heterogeneous systems and homogeneous alternatives, each suited to different production scales and requirements. Supported catalysts, such as MgCl₂- or silica-immobilized Ziegler-Natta and metallocene variants, dominate industrial applications due to their ability to control particle and prevent , which is a common issue with soluble homogeneous catalysts. Homogeneous metallocene systems, while offering precise comonomer incorporation for copolymers, are typically adapted to supported forms for or gas-phase processes to achieve high throughput and consistent bead-like granules. This shift to supported metallocenes has improved or incorporation uniformity, leading to copolymers with better impact resistance compared to those from heterogeneous Ziegler-Natta catalysts. Recent advances in have focused on high-activity formulations to boost and . High-yield Ziegler-Natta catalysts, incorporating advanced internal donors like diesters, have been optimized using data-driven modeling and high-throughput experimentation, achieving up to twofold increases in rates while maintaining high isotacticity. These developments, including prealkylation strategies, reduce the required aluminum-to- by optimizing density, effectively lowering usage in catalyst formulations by approximately 50% relative to earlier generations as of 2023. In metallocene systems, supports like metal-organic frameworks (e.g., ) have doubled catalytic activity and enhanced molecular weight control, further advancing the synthesis of specialty polypropylenes.

Copolymers and Modified Polypropylenes

Polypropylene copolymers are produced by incorporating or other comonomers during the process, resulting in materials with altered chain structures compared to homopolymer polypropylene. These variants include random and block copolymers, which distribute the comonomer units differently to achieve specific microstructural features. Random copolymers consist of and units randomly distributed along the chain, typically with an ethylene content of 1-7 %, which disrupts the regularity of the isotactic polypropylene backbone. This random incorporation is achieved through copolymerization using metallocene or Ziegler-Natta catalysts, leading to a more uniform comonomer distribution than in block variants. Block copolymers feature distinct alternating segments of polypropylene and ethylene-rich sequences, often containing 5-15 wt% ethylene overall, where the ethylene blocks form polyethylene-like domains within the structure. These are synthesized via sequential steps or chain shuttling techniques to create the blocky , enabling phase-separated morphologies. PP-RCT, or polypropylene random with controlled , represents an advanced random variant developed in the early , featuring a tailored distribution through specialized metallocene catalysis to enhance crystallinity control. This results in a higher of 140-150°C compared to standard random copolymers. Beyond copolymerization, polypropylene is modified post-polymerization or during compounding to introduce specific enhancements. Nucleated polypropylenes incorporate nucleating agents, such as β-nucleators like N,N'-dicyclohexyl-2,6-naphthalenedicarboxamide, to promote the formation of metastable β-crystals alongside α-crystals. Filled variants, exemplified by talc-reinforced polypropylene, blend 5-40 wt% talc particles into the polymer matrix to modify the composite structure. Long-chain branched polypropylenes are generated by introducing branches via reactive extrusion or irradiation, creating a branched topology that differs from the linear homopolymer chain. Recent developments include bio-circular polypropylenes, such as those launched by Braskem in 2024, produced from renewable or recycled feedstocks to improve sustainability.

Processing and Manufacturing

Injection Molding and Extrusion

Injection molding is a primary processing technique for polypropylene, involving the melting of resin pellets in a heated barrel, followed by injection into a under high pressure to form precise parts such as containers, housings, and automotive components like bumpers and interior trim. Key process parameters include barrel temperatures ranging from 200–280°C, with the feed section typically 15–30°C cooler than the to ensure uniform melting without degradation, and mold temperatures of 40–60°C to facilitate rapid cooling and part ejection. Injection pressures are generally set at 7–10 , comprising about 50–75% of the machine's capacity, while is maintained low at 0.3–0.7 to minimize shear heating. These parameters are influenced by polypropylene's thermal properties, such as its of 160–170°C, which allows for efficient flow in the molten state. Extrusion processes for typically involve forcing molten resin through a die to produce continuous profiles, sheets, pipes, or , with applications in packaging , drainage pipes, and textile yarns. Barrel temperatures are controlled between 200–250°C across zones, with the die at 230–260°C to achieve optimal melt and prevent thermal degradation. In blown or sheet , the draw —the of the die opening to the final product thickness—ranges from 5:1 to 15:1, influencing molecular and enhancing tensile strength in the final product. For production, higher draw ratios up to 18:1 are applied post- to align chains and improve mechanical properties. Shrinkage in molded polypropylene parts typically occurs at rates of 1–2.5%, varying with wall thickness, cooling rate, and filler content, which can lead to dimensional inaccuracies if not managed. Warpage is controlled through uniform cooling, often achieved by maintaining mold temperatures at the lower end of the range and extending cooling times to ensure even contraction, reducing internal stresses. Recent developments in energy-efficient screw designs, such as optimized barrier and mixing sections, have improved throughput and energy efficiency in polymer extrusion lines.

Films and Biaxially Oriented PP (BOPP)

Biaxially oriented polypropylene (BOPP) films are produced through a specialized extrusion and orientation process that enhances the material's mechanical and barrier properties for applications primarily in flexible packaging. The process begins with the extrusion of polypropylene resin into a thick cast sheet at temperatures around 200-230°C, which is then rapidly quenched to form an amorphous or semi-crystalline structure. This sheet is subsequently heated to its softening point and subjected to biaxial stretching, either sequentially in a tenter frame (first in the machine direction [MD], then transverse direction [TD]) or simultaneously via a bubble inflation method, to align the polymer chains and induce crystallinity. In the sequential stretching method, which is the most common for BOPP, the film is stretched 4-5 times in the MD using heated rollers, followed by 8-10 times in the TD within a tenter frame at temperatures typically between 150-160°C to prevent tearing while allowing controlled deformation. Simultaneous stretching, used for certain high-clarity films, inflates the extruded tube into a and expands it evenly in both directions under similar thermal conditions. These stretch ratios result in a significant increase in film area (up to 40-50 times the original) and impart anisotropic properties, with the orientation process occurring above the temperature but below the of polypropylene (around 160-170°C). Post-stretching, the film is annealed at 100-130°C to stabilize dimensions and relieve internal stresses, followed by cooling and winding. BOPP films are typically manufactured in thicknesses ranging from 10 to 60 μm, with thinner gauges (e.g., 15-30 μm) favored for due to their lightweight nature and cost efficiency. To improve barrier properties against moisture, oxygen, and light, films often undergo metallization via of aluminum, creating a thin metallic layer (optical 2.0-2.5) that reduces oxygen rates to below 1 cm³/m²/day/. Additionally, coatings such as or (PVDC) are applied inline or offline, while multilayer coextrusion incorporates (EVOH) layers for superior oxygen barrier performance, achieving permeability as low as 0.1-0.5 cm³/m²/day/ in composite structures. These modifications make BOPP suitable for , where they extend by minimizing oxidation and aroma loss. The process significantly boosts mechanical properties, such as tensile strength to 150-200 in the TD and 100-150 in the , providing the and clarity detailed in the mechanical properties section. Globally, BOPP reached approximately 9.7 million tons in 2024, with steady driven by demand, though volumes were approximately 8.5 million tons in 2022, projected to exceed 10 million tons by 2025. Bio-based BOPP variants, derived from renewable feedstocks like , began emerging commercially in 2023 to address concerns, representing a small but expanding segment valued at about USD 0.85 billion in 2024.

Applications

Packaging and Consumer Goods

Polypropylene plays a pivotal role in packaging applications, particularly for containers, bottles, and caps, which constitute a major share of its global consumption. These items leverage the material's inherent chemical resistance, enabling safe contact with acidic or oily without leaching harmful substances. According to the U.S. Food and Drug Administration (FDA), polypropylene is approved for direct contact under 21 CFR 177.1520, as it does not migrate significant levels of monomers or additives into foodstuffs under normal conditions. This resistance, combined with its lightweight and durable nature, makes it ideal for items like cups, bottles, and bottle closures, where it accounts for a substantial portion of rigid production. A key advantage of polypropylene in is its microwave safety, allowing containers to withstand temperatures up to 100°C without softening or releasing chemicals, which supports convenient reheating of prepared meals. Technical assessments confirm that polypropylene's high softening point, around 130-160°C, and transparency to prevent absorption of that could cause deformation during typical use. represents one of the largest markets for polypropylene, with analyses indicating it consumes over 40% of total production, driven by demand for cost-effective, versatile solutions in the consumer sector. Beyond rigid forms, polypropylene films are extensively used for flexible such as wraps, labels, and overwraps, valued for their clarity, gloss, and barrier properties against moisture and oxygen. These films, often biaxially oriented for enhanced strength, are applied in products like wrappers and product labeling, where high print quality and sealability are essential. Reusable polypropylene bags, commonly made from non-woven or woven variants, offer durability for multiple uses and support efforts, with post-consumer recovery rates reaching up to 10-20% in advanced systems, though overall recycling remains low at around 5-9% globally. In consumer goods, polypropylene's low production cost—typically ranging from $1.00 to $1.50 per in North American markets—facilitates its use in everyday items like luggage shells, children's toys, and furniture components such as chair bases or storage bins. This affordability, coupled with impact resistance and ease of molding, positions it as a preferred for high-volume, non-specialized products that prioritize functionality and . Recent innovations include variants of polypropylene for food-contact surfaces, incorporating FDA-approved additives like silver ions or organic acids to inhibit , enhancing in reusable containers and wraps without compromising .

Textiles and Fibers

Polypropylene is extensively utilized in the production of melt-spun fibers, which are created by extruding molten through spinnerets and drawing it into continuous . These fibers typically range from 2 to 25 denier per filament, enabling versatile applications in durable such as carpets, ropes, and geotextiles. The and chemical of polypropylene make it ideal for these uses, where it provides strength and longevity in high-wear environments like indoor and systems. Fibers account for a significant share of polypropylene consumption in the textile sector, supporting and consumer demands for cost-effective, robust materials. Nonwoven fabrics derived from polypropylene, produced via spunbond and meltblown techniques, play a crucial role in hygiene and protective products. In spunbond processes, continuous filaments are laid down and bonded, while meltblown methods create finer fibers for enhanced filtration. These fabrics are prominently featured in disposable diapers, where they form absorbent cores and leak-proof barriers, and in face masks, providing outer layers that block . The inherent hydrophobicity of polypropylene, which repels and prevents wetting, is a primary advantage, ensuring breathability while maintaining dryness in moisture-exposed applications. This property enhances product performance in personal care items without compromising comfort or efficiency. In apparel, polypropylene fibers are valued for and due to their minimal absorption, typically under 0.1%, which allows sweat to evaporate quickly while retaining body heat. This low hygroscopicity—far below that of natural fibers like —makes it suitable for base layers in activewear, where it wicks away from and dries rapidly, reducing the risk of chill or during . Its lightweight nature and further contribute to comfort in outdoor and performance clothing. Recent advancements include the integration of recycled polypropylene fibers into , driven by initiatives. These recycled materials, often derived from , are melt-spun into yarns for eco-friendly garments, reducing reliance on virgin polymers. The recycled fibers market has shown robust growth, with projections indicating a of approximately 7.6% from onward, reflecting increasing adoption in apparel to meet environmental regulations and consumer demand for green textiles.

Automotive and Industrial Uses

Polypropylene is extensively utilized in the automotive sector for structural and functional components such as bumpers, dashboards, and under-hood parts, where its lightweight nature and versatility are highly valued. These applications frequently incorporate 30% glass-filled polypropylene to enhance rigidity and mechanical strength, enabling manufacturers to replace heavier materials like metal. Such substitutions contribute to lightweighting efforts that enable overall vehicle weight reductions of approximately 10%, improving and reducing emissions. A primary of polypropylene in automotive engines and under-hood environments is its superior chemical resistance to oils, fuels, and coolants, ensuring long-term durability under harsh conditions. Additionally, polypropylene provides effective vibration damping, which mitigates (NVH) in engine compartments and interior assemblies, enhancing passenger comfort. In industrial applications, polypropylene serves as a reliable material for cases, offering impact resistance, electrical insulation, and dimensional stability essential for housing lead-acid and lithium-ion batteries. It is also widely used in labware, such as beakers and containers, due to its chemical inertness and non-reactivity with acids and bases. For systems, polypropylene random (PP-R) is employed in hot water distribution, capable of withstanding temperatures up to 95°C while resisting and . Emerging trends in polypropylene usage include the integration of bio-based variants in electric vehicles (EVs) to promote and reduce reliance on fossil fuels, driven by lightweighting needs for improved range. The bio-based polypropylene market is projected to expand rapidly, from approximately USD 358 million in 2025 to over USD 6.9 billion by 2034, reflecting increasing adoption in automotive applications.

Medical and Pharmaceutical Applications

Polypropylene (PP) is widely utilized in medical and pharmaceutical applications due to its , chemical inertness, and ability to maintain sterility, making it suitable for devices that contact human tissues or drugs. Medical-grade PP resins comply with Class VI standards, which assess biological reactivity and ensure minimal risk of adverse effects in prolonged contact with body fluids or tissues. These properties allow PP to be autoclaved at 121°C without degradation, supporting steam sterilization processes essential for infection control. In disposable medical devices, is commonly employed for syringes, vials, and intravenous () bags, where its non-reactive nature prevents leaching of contaminants into solutions. For instance, multilayer bags meet USP Class VI and requirements, offering excellent chemical resistance and low interaction with parenteral drugs, enabling safe fluid administration. Similarly, syringes and vials provide durability and clarity, facilitating precise dosing while withstanding repeated autoclaving cycles up to 121°C for up to 20 minutes. These applications leverage 's lightweight and impact-resistant structure to ensure reliability in clinical settings. For surgical applications, porous PP meshes serve as implants for and reconstruction, promoting tissue integration through their open structure that allows infiltration and deposition. Studies demonstrate that PP evokes a moderate to low inflammatory response , comparable to or less than other synthetic meshes, supporting long-term . The porosity facilitates vascularization and reduces reactions, though lightweight variants show improved outcomes in minimizing and erosion compared to heavyweight PP. In pharmaceutical packaging, PP forms blister packs that protect solid oral with minimal extractables, ensuring drug stability and compliance with pharmacopeial standards for leachables. Healthcare-grade PP, such as Bormed™ resins, exhibits low extractable levels, reducing potential interactions with sensitive pharmaceuticals during storage and transport. These packs also support recyclability, aligning with goals in systems. Recent advancements include 3D-printed PP components for customized medical devices, such as prosthetics and scaffolds, enabled by PP's printability and for patient-specific solutions. Antimicrobial-modified PP variants are under investigation for enhanced infection resistance in implants, with in vitro trials demonstrating efficacy against common pathogens as of 2024.

Recycling and Environmental Impact

Recycling Methods

Polypropylene waste is primarily recovered through mechanical recycling, which involves collecting and sorting the material based on its #5, allowing for separation from other plastics using automated systems like . Once sorted, the polypropylene is shredded into flakes, washed to remove contaminants, and then melted in an extruder at temperatures typically ranging from 200°C to 250°C to form pellets suitable for reuse. This process requires high material purity, generally exceeding 95%, to ensure the recycled polypropylene maintains mechanical properties comparable to virgin material and avoids degradation from impurities. Chemical recycling methods offer an alternative for polypropylene that cannot be mechanically processed due to contamination or degradation, with being a prominent that thermally decomposes the polymer at 400–600°C in an oxygen-free environment to produce liquid hydrocarbons and gases, including recoverable like , with overall yields of 70–80% for valuable products. processes, which break polypropylene back into its units more selectively, are emerging, with pilot-scale demonstrations reported in 2023 using advanced catalytic or pulsed heating methods to achieve rates up to 36% without catalysts. These approaches complement by handling mixed or low-quality feedstocks, though they require significant input and development. As of 2025, international efforts like the UN plastics aim to end by 2040, potentially boosting PP . A key challenge in polypropylene recycling is contamination from multilayer packaging, where polypropylene is often laminated with materials like aluminum or , complicating separation and reducing recyclate quality. spectroscopy addresses this by identifying types based on molecular vibrations, enabling precise sorting at high speeds, though limitations persist with thin layers or additives that alter spectral signatures. Globally, polypropylene rates remain low at approximately 1–8%, reflecting inadequate collection infrastructure and market demand for recycled material. In the , under the Packaging and Packaging Waste Regulation (PPWR), which entered into force in 2025, there is a binding target of at least 30% recycled content in by 2030, driving investments to increase recovery and processing capacities.

Biodegradation and Sustainability

Polypropylene exhibits high resistance to due to its stable carbon-carbon backbone, which is minimally susceptible to microbial attack under environmental conditions. In landfills, where conditions prevail, polypropylene persists for extended periods, with studies indicating only initial surface deterioration after five years of exposure and viable microbial colonization but no significant mass loss. Estimated half-lives for polypropylene in environments range from 50 to 58 years, suggesting even longer persistence in oxygen-limited landfill settings. Recent research has focused on microorganisms to enhance , addressing the polymer's inherent recalcitrance. For instance, studies from 2022 to 2024 have identified bacterial consortia, including strains of and , capable of limited in laboratory settings, with degradation rates of approximately 0.1-1% per month under optimized conditions such as pre-treatment and enrichment cultures. These efforts often involve metagenomic analysis of environmental samples, like sediments, to isolate enzymes that initiate oxidation of the polymer chain, though scalability remains a challenge due to slow and the need for abiotic pre-treatments. To improve sustainability, bio-based polypropylene derived from renewable feedstocks like has emerged as a viable alternative to petroleum-derived variants. Produced via of sugarcane-derived bioethanol into monomers, this material currently holds a very small , approximately 0.05% of total polypropylene production as of 2025. assessments indicate that bio-based polypropylene can achieve at least 50-81% lower compared to conventional polypropylene, primarily due to the sequestration of biogenic carbon during growth and reduced reliance on fuels. Polypropylene contributes substantially to global microplastic pollution, as its widespread use in packaging and textiles leads to fragmentation during use and disposal. While exact figures for polypropylene-specific releases vary, it accounts for a significant portion of the estimated 2.7 million tons of entering ecosystems annually as of 2020, with projections to double by 2040, exacerbating contamination in soils, waterways, and marine environments. Efforts to mitigate this include the incorporation of oxo-degradable additives, which promote abiotic oxidation and fragmentation to accelerate breakdown; however, these pro-oxidants often result in smaller microplastic particles rather than complete mineralization, potentially worsening persistent . As a result, regulatory bodies and researchers emphasize that such additives are not a reliable and may interfere with recycling streams.

Safety and Health Considerations

Health Concerns

Polypropylene (PP) is generally regarded as safe for contact applications due to its and low of substances into foodstuffs under normal conditions. The sets an overall migration limit of 10 mg/dm² for plastics like PP in contact with , which encompasses additives and oligomers; studies confirm that PP complies with this threshold, exhibiting minimal leaching of antioxidants and stabilizers. However, under hot contact scenarios, such as heating or storage above 100°C, small amounts of polypropylene oligomers—short polymer chains—can migrate into , though levels remain below regulatory limits and do not pose acute risks. Unlike , PP does not typically incorporate as plasticizers, resulting in negligible leaching of these endocrine-disrupting additives. In manufacturing settings, exposure to polypropylene fibers or respirable poses risks, primarily causing upon prolonged contact. The (OSHA) establishes a (PEL) of 5 mg/m³ for the respirable fraction of not otherwise regulated, including PP , to mitigate and potential effects like . Safety data sheets for PP emphasize and to prevent accumulation, as fine particles can act as mechanical irritants without evidence of deeper lung penetration in typical exposures. Regarding long-term health effects, the International Agency for Research on Cancer (IARC) classifies polypropylene as Group 3, not classifiable as to its carcinogenicity to , based on insufficient evidence from and . Debates persist over potential endocrine disruption from trace impurities or leached additives in PP; while some studies indicate weak antiandrogenic activity in extracts of certain PP products, assays show no significant effects, and no definitive causal links to health outcomes have been established. Recent 2024 research has detected trace amounts of polypropylene nanoplastics in samples, though concentrations were below quantifiable levels and their health implications remain under investigation. As of 2025, a has highlighted concerns regarding of PP in surgical meshes, where particles may accumulate in surrounding tissues, potentially causing and complications in medical implants.

Combustibility and Fire Safety

Polypropylene is a flammable thermoplastic polymer with a UL 94 HB flammability rating in its unmodified form, indicating it burns slowly in a horizontal orientation but does not self-extinguish readily under vertical flame exposure. Its autoignition temperature is approximately 390°C, above which it can ignite spontaneously in air without an external flame source. In fire tests such as the cone calorimeter, unmodified polypropylene exhibits a high peak heat release rate, typically ranging from 700 to 1700 kW/m² under a 50 kW/m² external heat flux, contributing significantly to fire growth and intensity. During combustion, polypropylene primarily produces (CO₂) and (CO) as gaseous products, along with and a variety of toxic hydrocarbons such as oxygenated and aromatic compounds formed from incomplete oxidation. The smoke density generated is notably high due to the formation of particulate and volatile organics, which can obscure visibility and exacerbate fire hazards in enclosed spaces. To mitigate these risks, halogen-free flame retardants such as ammonium polyphosphate () are commonly incorporated into polypropylene formulations, promoting intumescence by forming a protective layer that reduces availability to the . These additives enable polypropylene composites to achieve a V-0 rating, where samples self-extinguish within 10 seconds without dripping flaming particles, even at loadings of 20-25 wt%. For building applications, polypropylene materials must comply with standards like ASTM E84, which measures flame spread index and to assess surface burning characteristics; unmodified polypropylene typically shows high flame spread (over 200), but flame-retardant variants can achieve Class B or better ratings for interior use. Recent advancements include low-smoke, halogen-free polypropylene formulations developed in 2023 specifically for components, such as battery enclosures, offering UL 94 V-0 performance while minimizing toxic smoke emission during potential events.

References

  1. [1]
    Polypropylene (PP)
    Polypropylene (PP) is a linear hydrocarbon polymer, expressed as CnH2n. PP, like polyethylene (see HDPE, L/LLDPE) and polybutene (PB), is a polyolefin or ...Missing: authoritative | Show results with:authoritative
  2. [2]
    Polypropylene (PP) - Structure, types, and key applications
    Oct 30, 2025 · It finds application in packaging, automotive, consumer goods, medical, cast films, etc. Its chemical formula is (C3H6)n. Polypropylene ...Missing: authoritative | Show results with:authoritative
  3. [3]
    All About Polypropylene: How it's Made and Used - Xometry
    May 24, 2022 · Polypropylene is a semi-rigid, cost-effective, and tough thermoplastic linear hydrocarbon polymer resin that offers excellent chemical, electrical, and fatigue ...Missing: authoritative | Show results with:authoritative
  4. [4]
    Chemists and engineers in the history and development of plastics
    The polymerisation of propylene was known from the early 1930's but it was not until 1954 that the work of Italian chemists led to the ability to manipulate the ...
  5. [5]
    Poylpropylene and High-Density Polyethylene - National Historic ...
    In 1951, while attempting to convert propylene into gasoline, J. Paul Hogan and Robert L. Banks of Phillips Petroleum Company discovered polypropylene, a high- ...
  6. [6]
    [PDF] Giulio Natta - Nobel Lecture
    At the beginning of 1954 we succeded in polymerizing propylene, other α-olefins, and styrene; thus we obtained polymers having very different properties from ...
  7. [7]
    A Most Invented Invention | Invention & Technology Magazine
    ... Natta's patent and Ziegler's discovery of the plastic. And Hercules also discovered polypropylene. In early 1955 a team of scientists headed by Edwin J ...
  8. [8]
    992 F.2d 1197 - Public Resource
    This case concerns polypropylene, a polymer of propylene molecules.2 On August 3, 1954, Ziegler filed in Germany a patent application, Z 4348 IVc/39c (the ...Missing: 1953 | Show results with:1953
  9. [9]
    Patent solution in a canning jar - Max-Planck-Gesellschaft
    Aug 11, 2014 · ... Natta produced polymers composed of propylene, 1-butene and styrene. In the Italian patent from June 8, 1954, Montecatini and Giulio Natta ...
  10. [10]
    The Nobel Prize in Chemistry 1963 - NobelPrize.org
    The Nobel Prize in Chemistry 1963 was awarded jointly to Karl Ziegler and Giulio Natta "for their discoveries in the field of the chemistry and technology ...
  11. [11]
    Polypropylene raw material K8303 - DAZI Chem
    In 1957, Montecatini company of Italy and Hecules company of the United States established polypropylene production units of 6000T /a and 9000T /a respectively.
  12. [12]
    No. 2 - Polypropylene | Plastics Technology
    Oct 1, 2005 · Ziegler's discovery to the development of isotactic PP, which Montecatini was the first to produce on an industrial scale in 1957 in its Ferrara ...
  13. [13]
    Polypropylene - The Plastics Historical Society
    Dec 6, 2016 · Commercial production of polypropylene began in 1957 with Hercules Incorporated, Montecatini and Farbwerke Hoechst AG. ICI produced ...Missing: plant | Show results with:plant
  14. [14]
    [PDF] discovery-of-polypropylene-and-development-of-high-density ...
    Nov 12, 1999 · Ziegler and Italian scien- tist Giulio Natta were responsible for the discov- ery, because they had been the first to publish their findings ...
  15. [15]
    Industrial polymerization processes
    Montecatini started the production in 1957 based on a very compli- cated process in a small scale of only a few thousand tons per year. Since then the ...
  16. [16]
    Asia to dominate global polypropylene capacity additions by 2027
    Global polypropylene capacity is poised to grow in the next five years, potentially increasing from 97.65mtpa in 2022 to 159.35mtpa in 2027.
  17. [17]
    Polypropylene Market Size, Share & Growth Report, 2030
    The global polypropylene market size was estimated to be USD 123.46 billion in 2022 and is expected to reach USD 177.73 billion in 2030, growing at a CAGR ...
  18. [18]
    Propylene | CH2CHCH3 | CID 8252 - PubChem - NIH
    Propylene | CH2CHCH3 or C3H6 | CID 8252 - structure, chemical names, physical and chemical properties, classification, patents, literature, ...
  19. [19]
    Introductory Chapter: Polypropylene - Synthesis and Functionalization
    May 6, 2020 · Polypropylene (PP) is polymerized from propylene out of crude oil and is the most widely used commodity thermoplastic by volume.
  20. [20]
    [PDF] Review on Development of Polypropylene Manufacturing Process
    The polymer- ization reaction occurs at the active points of the catalyst particles, and the PP that is formed precipitates out, and the catalyst splits into ...
  21. [21]
    POLYPROPYLENE - Ataman Kimya
    Commercially available polypropylenes usually have an isotactic index between 85 and 95%. The tacticity effects the polymers physical properties. As the methyl ...<|control11|><|separator|>
  22. [22]
    Tacticity Changes during Controlled Degradation of Polypropylene
    Sep 21, 2021 · The controlled reactive degradation of polypropylene (CPP) in a twin-screw extruder has been investigated from the perspective of tacticity.Missing: challenges | Show results with:challenges
  23. [23]
    Tacticity distribution of polypropylene prepared by MgCl2-supported ...
    ... X-ray diffraction. PP was shown to have a broad and continuous distribution of tacticity, ranging from nearly atactic to highly isotactic structures in the ...
  24. [24]
    https://www.sciencedirect.com/science/article/pii/0032386194905142
  25. [25]
    https://doi.org/10.1021/ma00087a034
  26. [26]
    https://doi.org/10.1002/macp.1964.020750113
  27. [27]
    [PDF] Plastics Data File – PP | Tangram Technology
    Polypropylene is a largely non-polar, partially crystalline thermoplastic with a crystallinity of 60 to 70%. PP has a density of 0.90 to 0.91 g/cm3 which is ...
  28. [28]
    PP (isotactic): Polypropylene - NETZSCH Analyzing & Testing
    It has an approx. 20% share in plastic production worldwide and is therefore the second most important polymer after PE. Its tacticity (isotactic, syndiotactic ...
  29. [29]
    Structure–Property Relationship in Isotactic Polypropylene Under ...
    The mechanical properties of PP, such as softening point, rigidity, Young's modulus, strength, and toughness, are improved by increasing isotacticity [9,10,11]; ...
  30. [30]
    β-Nucleated Polypropylene - PubMed Central - NIH
    The crystalline structure of PP mainly includes α [1], β [2,3], γ [4], δ [5], and the quasi-hexagonal state [6]. α- and β-crystals have been widely studied ...
  31. [31]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC10383444/
  32. [32]
    Polypropylene - PP Homopolymer - AZoM
    Sep 6, 2001 · Typical Properties ; Tensile Strength (MPa). 33 ; Flexural Modulus (GPa). 1.5 ; Notched Izod (kJ/m). 0.07 ; Linear Expansion (/°C x 10-5). 10.
  33. [33]
    [PDF] TYPICAL PROPERTIES OF POLYPROPYLENE (PP)
    Tensile strength (psi). 4,500-6,000. 4,000-5,500. 2,500-10,000. D638. Elongation ... Impact strength, Izod (ft-lb/in of notch). 0.4-1.4. 1.1-14. 0.6-4.0. D785.
  34. [34]
    Overview of materials for Polypropylene, Molded - MatWeb
    Tensile Strength, Yield, 4.00 - 369 MPa, 580 - 53500 psi ; Film Elongation at Break, MD, 93.0 - 530 %, 93.0 - 530 % ; Elongation at Break, 2.40 - 900 %, 2.40 - ...
  35. [35]
    Polypropylene - an overview | ScienceDirect Topics
    Polypropylene is manufactured by polymerizing propylene monomer with a titanium based catalyst; a co-catalyst (triethylaluminum) is added to initiate the ...
  36. [36]
    [PDF] Investigating the Creep Behaviour of Polypropylene - Theseus
    Apr 20, 2021 · Creep is a gradual deformation of a material. For polypropylene, creep varies linearly over time, and is time-dependent.
  37. [37]
    (PDF) Effect of molecular weight distribution on the rheological and ...
    Aug 7, 2025 · Abstract. The effect of molecular weight distribution on the Theological and mechanical properties of a series of polypropylenes is evaluated.
  38. [38]
    Physical and mechanical properties of polypropylene fractions
    A high impact strength requires a high molecular weight and a narrow molecular weight distribution. A correlation was found between tensile impact strength and ...
  39. [39]
    [PDF] IV. Polypropylene - Standard Reference Data
    The data between the glass transition and melting temperatures for isotactic and syndiotactic polypropyl- ene samples are given in tables A2 and A3, ...Missing: conductivity vicat softening<|control11|><|separator|>
  40. [40]
    [PDF] Typical Engineering Properties of Polypropylene
    Polypropylene. General Properties. English Units. SI Units. CAS Number ... 0.904 – 0.908 g/cm3. 0.898 – 0.900 g/cm3. 0.875 – 0.880 g/cm3. Melt Density. 9.5 ...Missing: degree crystallinity 0.90-0.91
  41. [41]
    Polypropylene PP - Properties - Swicofil
    THERMAL PROPERTIES. Polypropylene fibers have a softening point in the region of 150°C and a melting point at 160-170°C. At low temperatures of -70°C or ...
  42. [42]
    PP Polypropylene - Chemical Resistance - The Engineering ToolBox
    Chemical resistance of Polypropylene - PP - to acids, bases, organic substances and solvents ... resistance to aggressive fluids like acids, bases and more.
  43. [43]
    [PDF] Polypropylene Chemical Resistance Guide
    HMC PP resins are appreciably affected by chlorosulfonic acid and oleum at room temperature, 98% sulfuric acid, 30% hydrochloric acid, and 30% hydrogen peroxide.
  44. [44]
    Degradation Rates of Plastics in the Environment - ACS Publications
    Feb 3, 2020 · This Perspective summarizes the existing literature on environmental degradation rates and pathways for the major types of thermoplastic polymers.
  45. [45]
    Fourier Transform Infrared Spectroscopy to Assess the Degree of ...
    Feb 11, 2023 · For example, the Carbonyl index has been used as the essential indicator of carbonyl group formation during PP and PE photo or thermo-oxidation ...<|separator|>
  46. [46]
    Effects of UV Stabilizers on Polypropylene Outdoors - PMC - NIH
    Apr 1, 2020 · For pure PP samples, their internal structure would have been destroyed after 4.5 weeks' UV exposure; however, HALSs and UV stabilizers prevent ...Missing: lifespan | Show results with:lifespan
  47. [47]
    Quantitative measurement of birefringence in transparent films ...
    Aug 1, 2022 · Both true cellophane and biaxially oriented polypropylene (BOPP) film are highly birefringent. Traditional cellophane gift-basket film is ...
  48. [48]
    Optical Properties of Polypropylene upon Recycling - PMC - NIH
    Sep 14, 2013 · ... PP are much larger than the wavelength of visible light (0.4–0.7 μm), and the refractive index of crystalline regions is higher than that of ...
  49. [49]
    Improve The Clarity Of Molded PP-Based Products With High ...
    Clarifier 4000266-E is a high-performance additive that outperforms clarified polypropylene and can reduce the haze of molded PP plastics to below 20%.<|separator|>
  50. [50]
    [PDF] UV PROPERTIES OF PLASTICS: TRANSMISSION AND RESISTANCE
    Fortunately, many pure plastics cannot absorb UV radiation, but the presence of catalytic residues and other impurities can act as receptors to cause.
  51. [51]
    Causes & Prevention of Yellowed Plastics - SpecialChem
    Aug 5, 2022 · Impurities in the plastics may themselves absorb light and give a yellowish aspect. They can also accelerate the degradation process ...
  52. [52]
    Biaxially Oriented Polypropylene - an overview | ScienceDirect Topics
    BOPP films are used in food packaging and are replacing cellophane in applications such as snack and tobacco packaging due to favorable properties and low cost ...Polypropylene Films · Material Surface Preparation... · 6.7. 4.2 Corona Treatment...
  53. [53]
    Polypropylene Catalyst Market Size And Share Report, 2030
    Gas phase dominated the market and accounted for a revenue share of approximately 68.6% in 2023. In this process, the polymerization reaction occurs in the ...
  54. [54]
    [PDF] Energy Inputs on the Production of Plastic Products - jeeng.net
    Aug 1, 2022 · requirements for the production of polymers, the energy consumption increases to about 94 MJ/kg. ... cycle assessment of polypropylene production ...
  55. [55]
    The Influence of Ziegler-Natta and Metallocene Catalysts on ...
    50 years ago, Karl Ziegler and Giulio Natta were awarded the Nobel Prize for their discovery of the catalytic polymerization of ethylene and propylene using ...
  56. [56]
    Direct Synthesis of High-Melt-Strength Polypropylene Using the ...
    Apr 13, 2020 · This MgCl2-supported Ziegler–Natta catalyst, exhibiting better stereo- and regioselectivity (with 1,2-insertion) of propylene than metallocene ...
  57. [57]
    Metallocene Catalysis Polymerization
    Knowing why this catalyst gives isotactic polypropylene, what kind of catalyst would give syndiotactic polypropylene? Have you figured it out yet? It's a ...
  58. [58]
    Polypropylene obtained through zeolite supported catalysts - SciELO
    Major disadvantages of the homogeneous catalysts are both the lack of morphology control and reactor fouling. Supported catalysts allow the control of polymer ...<|control11|><|separator|>
  59. [59]
    Polypropylene reactor mixture obtained with homogeneous and ...
    Nov 30, 2004 · Propylene polymerizations were performed with homogeneous ϕ2C(Flu)(Cp)ZrCl2 and SiMe2(Ind)2ZrCl2 catalyst mixtures and with mixtures ...
  60. [60]
    Influence of supported metallocene catalysts on polymer tacticity
    Metallocene catalysts in dissolved form are in most cases unsuitable for the production of polyethylene or polypropylene on an industrial scale.
  61. [61]
    Data Driven Modeling of Ziegler–Natta Polypropylene Catalysts
    Mar 24, 2025 · Data Science Meets Ziegler–Natta Catalysis to Design High-Performance Lewis Bases for Isotactic Polypropylene Production. ACS Catalysis 2025 ...Introduction · Experimental Section · Results and Discussion · Conclusions
  62. [62]
    (PDF) A New Generation of High‐Efficiency Ziegler–Natta Catalyst ...
    Sep 26, 2025 · We adopted a prealkylation strategy for the catalysts preparation, reducing the optimal aluminium titanium ratio for propylene polymerisation ...
  63. [63]
    Influence of MIL-53 on the catalytic performance of metallocene in ...
    Jan 15, 2025 · MIL-53 yields more than twice the catalytic activity of silica, facilitates higher molecular weight polypropylene, and has higher comonomer ...
  64. [64]
    [PDF] Morphological Partitioning of Ethylene Defects in Random ...
    A series of metallocene-catalyzed propylene/ethylene random copolymers with ethylene contents ranging from mole fractions of 0.8-7.5% and melt crystallization.
  65. [65]
    Quantifying the content of various types of polypropylene in high ...
    Random-PP contains less than 6 % ethylene as a comonomer, disrupting crystallinity and lowering the crystallization temperature compared to Homo-PP, and is used ...
  66. [66]
    Semicrystalline thermoplastic elastomeric polyolefins - PNAS
    Oct 17, 2006 · We report the design, synthesis, morphology, phase behavior, and mechanical properties of semicrystalline, polyolefin-based block copolymers.
  67. [67]
    PP-R & PP-RCT Pipe - Plastics Pipe Institute
    Two types of PP are used for pressure piping systems: PP-R (polypropylene random copolymer) and PP-RCT (polypropylene random copolymer with modified ...Missing: controlled tacticity
  68. [68]
    [PDF] DYNATHERM - UPG Pipe Systems
    Pressure Ratings (Bar/ Temp). Solid Wall SDR11: 18.4 - 20°C. 8.1 - 70°C. Flexural modulus 900 MPA. Melting point 140-150 °C. Solid Wall SDR7.4: 29.2 - 20°C.
  69. [69]
    β-Nucleated Polypropylene: Preparation, Nucleating Efficiency ...
    The β-crystals of polypropylene have a metastable crystal form. The formation of β-crystals can improve the toughness and heat resistance of a material.
  70. [70]
    Talc Filled Polypropylene - Gema Polimer
    The Gemapilen BKT series consists of polypropylene compounds filled with 5% to 40% talc. They can be manufactured using homopolymer, copolymer, or impact- ...Missing: nucleated long- chain branched
  71. [71]
    Long chain branching as an innovative up-cycling process of ...
    Long chain branching (LCB) was used the first time as an innovative tool for value adding to PP from household post-consumer waste.Missing: filled | Show results with:filled
  72. [72]
    [PDF] Polypropylene Processing Guide - INEOS Group
    Cylinder temperature and injection pressure are the two most important variables available to the molder. These two closely related variables are discussed in ...
  73. [73]
    Polypropylene Blends for Highly Drawn Tapes with Improved ... - NIH
    Jun 15, 2023 · In the case of PP tapes, usually a draw ratio between λ = 12 and λ = 15 is applied in industrial production to achieve the most beneficial ...
  74. [74]
    [PDF] Why Screws are Designed the Way They Are - Glycon Corp.
    There are documented applications where customers have improved production rates or reduced cycle times by 30 or 40% simply.
  75. [75]
    BOPP Film: How It's Made - POLYPVC
    Jun 4, 2024 · The BOPP film raw materials are melted and heated to 200–230°C within the extruders before being fed into the extrusion head, where they are ...
  76. [76]
    [PDF] Stretchability and Properties of Biaxially Oriented Polypropylene Film
    This means the stretched film at the high stretching stress is produced at the low stretch- ing temperature and has high strain at the low temperature. In order ...
  77. [77]
    https://www.mdpi.com/2073-4360/17/2/215
  78. [78]
    Characterization studies of aluminum oxide barrier coatings on ...
    Apr 27, 2012 · The barrier properties of aluminum oxide coated BOPP greatly depend on the plain film surface and the growth conditions for the depositing ...
  79. [79]
    EVOH Barrier: Guide to Properties, Applications & Selection
    Sep 15, 2025 · Film Thickness: A 10μm EVOH layer provides 90% of the barrier efficiency of a 20μm layer, making thin-gauge EVOH ideal for cost-sensitive ...Missing: strength | Show results with:strength
  80. [80]
    BOPP vs. PET Film - Synponh
    Jun 12, 2025 · Physical Properties ; Tensile Strength (MPa), 130-180, 180-250 ; Elongation at Break (%), 50-200, 70-130 ; Melting Point (°C), 160-170, 250-260.
  81. [81]
    BOPP Film - ultraplusfilm
    Technical Data ; Tensile Strength (MD), ≥120 MPa ; Tensile Strength (TD), ≥200 MPa ; Elongation (MD), ≤180% ; Elongation (TD), ≤65% ; COF (Inner), ≤0.8%.
  82. [82]
    BOPP Films Market Size, Growth, Analysis and Forecast 2035
    The global market size of BOPP Film has grown significantly in the historic period of 2015-2023 and reached approximately 9671 thousand tonnes in 2024. Q2.
  83. [83]
    https://www.synponh.com/bopp-vs-pet-film/
  84. [84]
    Food Packaging & Other Substances that Come in Contact with Food
    Jul 24, 2024 · Under federal law, a food contact substance that is a food additive must be authorized for that use before it is marketed in the U.S. Such ...Packaging & Food Contact... · Understanding How the FDA...
  85. [85]
    [PDF] Microwavability of Polypropylene - INEOS Group
    The chemical structure of polypropylene makes it transparent to microwaves and because it does not absorb microwave energy and has a relatively high softening ...
  86. [86]
    [PDF] The Case for Polypropylene - Winpak
    association with the Montecatini Company (now Montedison SpA). ... Flowing from these discoveries, commercial production of polypropylene began in 1957; however,.
  87. [87]
    Polypropylene Films For Any Application - Profol Americas
    All are PVC-free and recyclable. Other packaging films include twist wrap, overwrap, and form-fill-seal applications, as well as for die-cut tags, printable ...
  88. [88]
    [PDF] Life Cycle Assessment of Reusable and Single-use Plastic Bags in ...
    ... recycling rate of single-use plastic bags is approximately. 5% on average. Reusable polyethylene plastic bags could expect the same recycling rate of 5%.
  89. [89]
    Polypropylene Bags: The Ultimate Guide - Gentle Packing
    Nov 19, 2024 · ... recycling rate by 5 percentage points by the end of 2026. Currently, the rate is about 8%. It is a greener option than single-use plastic bags.
  90. [90]
    Polypropylene price index - BusinessAnalytiq
    Polypropylene price October 2025 and outlook (see chart below). North America:US$1.11/KG, -2.6% down; Europe:US$1.5/KG, -0.7% down ...
  91. [91]
    Efficacy of Antimicrobial Agents for Food Contact Applications ...
    Jul 1, 2018 · This article reviews the different types of antimicrobial agents used for active food packaging materials, the main incorporation techniques, and the ...Reviews · Antimicrobial Agents For... · Antimicrobial Active...
  92. [92]
    Packaging & Food Contact Substances (FCS) - FDA
    Mar 21, 2024 · Links to industry guidance, forms and inventories for food packaging and food contact substances.
  93. [93]
    [PDF] Melt Spinning of Polypropylene Fiber - Austin Publishing Group
    May 12, 2023 · Yarns with individual filament deniers from around 2 to 25 and total de- niers from 75 to several thousand are produced by the tong air- quench ...
  94. [94]
    Polypropylene fibers - ScienceDirect.com
    The difference from these three fibers is that PP fiber is hardly ever used as apparel, and its major use is for industrial applications: carpets, geotextiles, ...
  95. [95]
    Understanding Non-Woven Fabrics: Spunbond, PP, And Meltblown
    Oct 15, 2024 · - Lightweight and Durable: PP non-woven fabrics are durable, tear-resistant, and have good tensile strength. - Hydrophobic and Breathable: They ...
  96. [96]
    Advancement of Nonwoven Fabrics in Personal Protective Equipment
    Masks typically consist of an outer layer of hydrophobic spunbond fabric, an innermost layer of soft absorbent spunbond fabric, and a middle, sandwich layer of ...
  97. [97]
    https://austinpublishinggroup.com/textile-engineering/fulltext/arte-v8-id1079.pdf
  98. [98]
    Water Absorption in Plastics - Kashima Bearings, Inc.
    Water Absorption Rate: below 0.1%. Teflon (PTFE); Polyethylene (PE); Polypropylene (PP); Polyphenylene sulfide (PPS); Polyvinylidene chloride (PVDC). (Note ...
  99. [99]
    The New Role of Polypropylene Fabric in Sportswear
    Jul 22, 2025 · Polypropylene fabric is lightweight, strong, water-resistant, wicks sweat, provides thermal insulation, is sustainable, and versatile for ...Missing: 0.1%
  100. [100]
    Recycled Fibers Market Size & Share | Industry Report, 2030
    The global recycled fibers market size was estimated at USD 26.31 billion in 2024 and is projected to reach USD 40.82 billion by 2030, growing at a CAGR of 7.6 ...
  101. [101]
    The Application Of Polypropylene in The Automotive Industry - News
    Sep 30, 2024 · Components such as bumpers, interior trim, door panels, dashboards, and under-the-hood parts are often made from polypropylene. Its use in ...Missing: filled | Show results with:filled
  102. [102]
    North America Glass Filled Polypropylene Market Growth by 2030
    Aug 24, 2020 · ... glass filled polypropylene helps lower the weight of automotive structures by nearly 30%. Manufacturers such as Mitsui Chemicals Inc. are ...
  103. [103]
    Lightweight and strong glass fiber reinforced polypropylene ...
    For instance, 10% of weight reduction for a car can save up to 8% of fuel [5]. Moreover, lightweight plastic products can play an important role in increasing ...
  104. [104]
    Polypropylene (PP): Understand the Key Benefits and Applications
    Polypropylene is a lightweight versatile material commonly used for diverse applications like packaging, automotive parts, and electrical components.Missing: authoritative | Show results with:authoritative
  105. [105]
    Damping analysis of nonwoven natural fibre-reinforced ...
    This paper proposes a systematical analysis of the damping properties of nonwoven flax, hemp, kenaf and glass fibre-reinforced polypropylene composites, using ...Missing: engines | Show results with:engines
  106. [106]
    Battery cases - LyondellBasell
    Moplen, Pro-fax & Hostacom resins create reliable battery cases with dimensional stability, impact resistance & excellent weldability.Missing: labware | Show results with:labware
  107. [107]
    PP-R pipe for hot water - Polymelt
    Thermal Resistance: POLYMELT PP-R pipes are capable of withstanding temperatures up to 95°C continuously, making them ideal for use in hot water systems, ...Missing: polypropylene battery cases labware
  108. [108]
    Bio-Based Polypropylene Market Size and Companies Revenue by ...
    Oct 20, 2025 · The global bio-based polypropylene market size is calculated at USD 357.67 million in 2025 and is expected to reach USD 6,977.54 million by 2034 ...
  109. [109]
    [PDF] Healthcare Solutions - SABIC
    SABIC biocompatible grades have been tested and passed either USP/USP Class VI ... • PP option for enhanced transparency and autoclaving sterilization at 121°C.
  110. [110]
    Sterile IV bags PP and EVA - Technoflex
    Properties. Inerta® polypropylene film; DMF # 19057; USP class 6 and ISO 10993 compliance; Boat port; Excellent chemical inertness; Closed system; Oxygen and ...
  111. [111]
    In vivo response to polypropylene following implantation in animal ...
    The evidence reviewed shows that polypropylene evokes a less inflammatory or similar host response when compared with other materials used in mesh devices.
  112. [112]
    [PDF] Polypropylene: Medical Device Material Safety Summaries - FDA
    Oct 13, 2020 · Retrieval study at 623 human mesh explants made of polypropylene - impact of mesh class and indication for mesh removal on tissue reaction.Missing: syringes vials bags
  113. [113]
    Exploring the Applications of Medical Grade Polypropylene - Resmart
    Aug 22, 2024 · Furthermore, Topilene's low extractable levels help in minimizing potential interactions with pharmaceuticals and biological substances ...
  114. [114]
    https://www.technoflex.net/en/products/sterile-iv-bags/
  115. [115]
    Mechanical Recycling of Thermoplastics: A Review of Key Issues
    Oct 4, 2023 · At lower temperatures (Die Zone: 240 °C), PP is stable in processing even after five extrusions. Beyond five cycles and at high temperatures ...
  116. [116]
    Evaluation of the source material for PP recycling - Sage Journals
    Feb 6, 2024 · To produce high-quality recycled PP, a pure PP waste stream is required. However, not only contaminants but also the mixture of different PP ...
  117. [117]
    Catalytic pyrolysis of waste polypropylene using low-cost ... - Nature
    Jul 20, 2023 · It was found that the maximum oil yield was obtained at 5% and the production decreases by adding more catalyst. Ghodke used 10 wt% of CAT-1 as ...
  118. [118]
    Pulsed pyrolysis offers better way to breakdown plastics into their ...
    Apr 26, 2023 · The overall monomer yield was about 36% from depolymerisation of polypropylene with no need for a catalyst. 'The other 64% will be composed ...
  119. [119]
    Challenges and prospects of multilayer plastic waste management ...
    The study identifies key strategies to manage multilayer plastics effectively, including advanced chemical recycling technologies and policy interventions.
  120. [120]
    Plastic Recycling with NIR Technology: A Complete Guide
    Jan 1, 2025 · Explore how NIR technology is transforming plastic recycling. Learn how it works, its advantages, and the emerging trends.
  121. [121]
    Is Polypropylene Eco-Friendly? Stats & Trends
    Apr 26, 2024 · The demand for polypropylene in 2022 was 86.74 million tons, with a global production capacity of 97.86 million tons. It's expected to reach ...
  122. [122]
    Mandatory recycled content - Plastics Europe
    European plastics producers have called for a mandatory EU recycled content target for plastics packaging of 30% by 2030.
  123. [123]
    Biodegradation of Typical Plastics: From Microbial Diversity ... - MDPI
    PE, PS, PP, and PVC are extremely difficult to degrade because of the C-C backbone compared to PET and PU, which contain hydrolysable bonds [137]. To date, ...
  124. [124]
    Polypropylene structure alterations after 5 years of natural ... - PubMed
    Mar 1, 2021 · Even after five years, polypropylene can undergo deterioration/biodegradation in a waste landfill with viable microbial cells on its surface, possibly involved ...
  125. [125]
    Microbial and Enzymatic Degradation of Synthetic Plastics - Frontiers
    Microplastics comprising PU foams, PE particles, and PP particles, form the major pollutants with a half-life estimated to be ∼50 years in sea water (Plastics ...
  126. [126]
    Exploring untapped bacterial communities and potential ... - Frontiers
    Apr 3, 2024 · This study aimed to investigate the microbial communities involved in the biodegradation of polypropylene (PP).
  127. [127]
    Advancements in polypropylene biodegradation: A comprehensive ...
    This review highlights microbes, including bacteria and fungi, insects and larvae which have found the potential ability for biodegradation of polypropylene.
  128. [128]
    Synthetic and Bio-Based Polypropylene Companies
    Apr 7, 2025 · Bio-based PP is forecasted to hold ~3.7% of total PP market share by volume in 2025, up from 1.4% in 2020.
  129. [129]
    Life cycle assessment of renewable liquid hydrocarbons, propylene ...
    Renewable polypropylene had at least 81% lower carbon footprint and at least 78% lower consumption of fossil fuels when compared to fossil-based polypropylene ...
  130. [130]
    Braskem's biopolymers avoid emissions of over 5 million tons of ...
    Dec 7, 2020 · During ten years of growing sales, the material has avoided the emission of 5.54 million tons* of CO 2 -equivalent to over one year of automotive emissions.
  131. [131]
    Everything you should know about microplastics - UNEP
    Jun 2, 2025 · According to one estimate, 2.7 million tonnes of microplastics seeped into the environment in 2020, an estimate expected to double by 2040. “It ...Missing: 1-2 | Show results with:1-2
  132. [132]
    The distribution of subsurface microplastics in the ocean | Nature
    Apr 30, 2025 · Marine plastic pollution is a global issue, with 9–14 million metric tons of plastics entering the ocean annually. Microplastics (1 µm–5 ...
  133. [133]
    The performance and environmental impact of pro-oxidant additive ...
    May 10, 2023 · Fossil-based polyolefins containing pro-oxidant additives, and more recently as 'biotransformation' additives, are known as 'oxo-degradable' or ...
  134. [134]
    [PDF] Oxo-degradable Plastics Risk Environmental Pollution
    Oxo-degradable plastics fragment, don't biodegrade in the field, accumulate in soil and oceans, absorb toxins, and are not compostable or recyclable.
  135. [135]
    [PDF] Degradable Additives - Association of Plastic Recyclers
    Aug 5, 2024 · CEFLEX - "Oxo-degradable or similar (e.g. enzyme-based) additives are Not Permitted and Not compatible with PE or PP recycling." • Closed Loop ...
  136. [136]
    Cooking food in microwavable plastic containers: in situ formation of ...
    Aug 15, 2023 · Additionally, polypropylene glycol substances have been found to transfer into food through microwave cooking. Identifying these substances ...Missing: hot | Show results with:hot
  137. [137]
    Migration of Polypropylene Oligomers into Ready-to-Eat Vegetable ...
    May 6, 2025 · Packaged products may also be contaminated with polyolefin oligomeric hydrocarbons (POH), which, depending on the packaging, storage condition, ...
  138. [138]
    Is Polypropylene Safe and BPA Free? - Healthline
    Sep 23, 2020 · Can contain toxins such as DEHP, which the EPA says is likely to cause cancer in humans in high concentrations. May also contain dioxins ...
  139. [139]
    [PDF] SAFETY DATA SHEET REV. 06/28/2024 POLYPROPYLENE SHEET
    Inhalation: Inhalation of fine particles may cause respiratory irritation. Fumes produced while thermal processing may cause irritation, pulmonary edema and a ...Missing: fibers | Show results with:fibers
  140. [140]
    [PDF] Safety Data Sheet - Proto3000
    Polypropylene. 9003-07-0 8-Hour TWA-PEL: 10 mg/m³. (Total Dust, Particulates not otherwise regulated). Polypropylene. 9003-07-0 8-Hour TWA: 5 mg/m³. (Respirable ...
  141. [141]
    [PDF] Agents Classified by the IARC Monographs, Volumes 1–123
    Nov 2, 2018 · (NB: There is evidence suggesting lack of carcinogenicity in humans ... 009003-07-0 Polypropylene. 3. 19, Sup 7. 1987. 009003-53-6 ...
  142. [142]
    Uterotrophic and Hershberger assays for endocrine disruption ...
    Uterotrophic and Hershberger assays for endocrine disruption properties of plastic food contact materials polypropylene (PP) and polyethylene terephthalate (PET).Missing: impurities | Show results with:impurities
  143. [143]
    Quantitation of micro and nanoplastics in human blood by pyrolysis ...
    Jun 24, 2024 · This study presents an improved validated method for extracting and quantitatively analysing 6 high-production volume polymers applied in ...
  144. [144]
    POLYPROPYLENE HOMOPOLYMER - Plastics International
    7-day returnsPOLYPROPYLENE COPOLYMER · Dielectric Strength: 575 volts per meter · Flammability Rating (UL94 Rating): Not Rated ; SEABOARD · Dielectric Strength: 0 volts per ...
  145. [145]
    [PDF] SAFETY DATA SHEET Polypropylene (PP) Sheet - Plaskolite.com
    Decomposition Temperature: Not available. Flash Point: > 500°F (> 260°C). Auto-ignition Temperature: 735°F (390°C). Explosion Limits: Not available. Page 3 ...
  146. [146]
    Analysis of the Fire Behavior of Polymers (PP, PA 6 and PE-LD ... - NIH
    Dec 16, 2020 · The fire behavior of polymers is examined primarily with the time-dependent heat release rate (HRR) measured with a cone calorimeter.
  147. [147]
    [PDF] Polyolefins - Borealis
    ... combustion products, e.g. CO and soot, are formed in addition to water vapour and carbon dioxide. The major toxic component in combustion gases in plastic ...
  148. [148]
    [PDF] POLYMER FLAMMABILITY - FAA Fire Safety
    This report overviews polymer flammability, test methods, and relationships between polymer properties, chemical structure, flame resistance, and fire behavior.
  149. [149]
    Ammonium polyphosphate chemically-modified with ethanolamine ...
    Ammonium polyphosphate (APP) is not an efficient flame retardant for polypropylene (PP) when it is used alone. In order to improve its flame-retardant ...
  150. [150]
    Cross-Linking Modification of Ammonium Polyphosphate via Ionic ...
    This all-in-one IFR integrating three functional elements (carbon, acid, and gas source) showed more efficient flame retardancy and excellent smoke suppression.
  151. [151]
    RTP Company Introduces Flame Retardant Plastics for Low Heat ...
    ... Polypropylene, Polyamides, and Polycarbonate. These compounds meet a wide range of standards, including UL2043, ASTM E84, FAR 25.853, ASTM E162, and ASTM E662.
  152. [152]
    Low Smoke Halogen-Free Flame Retardant Polypropylene Market ...
    SABIC launched a new halogen-free flame-retardant polypropylene compound in late 2023, tailored for high-voltage EV applications. · Borealis and Borouge ...