Some aspects of polyethylene photooxidation

The hydroperoxides produced by thermal oxidation of LDPE films were used to study their photolysis. Product analysis, kinetics of hydroperoxide decomposition and product formation as well as experiments with model compounds point to new mechanisms of hydroperoxide photolysis. Intermolecular as well as intramolecular decomposition mechanisms are proposed. In polyethylene, these reactions are essentially non-initiating. In addition, it is confirmed that ketones such as those formed by oxidation of polyethylene do not have a significant initiating effect. Reactions of excited charge-transfer complexes polyethylene-oxygen are proposed to account for initiation of photo-oxidation. One of these reactions yields trans-vinylene groups and hydrogen peroxide whose direct decomposition or subsequent photolysis will generate hydroxyl radicals. It is found that this reaction is quenched very efficiently by small amounts of HALS (Hindered Amine Light Stabilizers) and by amines in general. It is postulated that quenching is due to energy transfer from the charge-tranfer complex polymer-oxygen to a charge-transfer complex HALS-oxygen or amine-oxygen. The data available so far support such a mechanism.     

Findings pertaining to polyethylene photooxidation

The kinetics and mechanisms of photolysis of the hydroperoxides formed on thermal oxidation of polyethylene have been investigated. The difficulties to explain the results by the generally accepted decomposition mechanism based on homolytic splitting of the hydroperoxy bond are discussed. New mechanisms of hydroperoxide photolysis are proposed. The intermolecular reactions considered account for the main products found experimentally, ketones and trans-vinylene groups. They are also in agreement with the kinetics of product formation. The intramolecular photolysis reactions envisaged seem to involve a small amount only of the hydroperoxides present in polyethylene after thermal oxidation. However, they affect directly the mechanical properties of the polymer because they involve main-chain scission.     

Photodegradation of polyethylene film

A structure occurs in radical-polymerized polyethylene which leads to formation of a triene on ultraviolet radiation. An inhibition of oxidative processes is observed while the triene or its precursor are being consumed. Subsequent formation of oxygenated products—hydroxyl, carbonyl, and carboxyl—is well behaved and arises from short wavelenght light. A crosslinking reaction is initiated by light of ～4000 Å wavelength.     

Redrawing of oriented polyethylene film

Drawn and subsequently annealed polyethylene film was restretched along the original draw axis at various temperatures. The internal deformation was analyzed in terms of the structural parameters of a simplified model. The elementary deformations are the rotation of crystals around the b axis and shear at the crystal interface. The rigidity of the crystal plays an important role during extension; and as a result, disorientation of chains in the crystal occurs at high strain. At the same time, crystals deform in such a way that the crystalline chains tilt about the b axis along the (h00) plane. This deformation of the crystal is affected by temperature. The increase in long spacing with extension can be interpreted roughly by the changes in structural parameters. The strain in amorphous region in also discussed in relation to these parameters.     

An ESCA study of the surface ozonation of polystyrene film

Polystyrene film was treated with 0.27 mol % ozone in oxygen at room temperature. Changes in the surface were monitored by ESCA. Reaction occurred uniformly in at least the outermost 60 Å of the film. Reaction was rapid, giving a surface composition that corresponded to C_1.8O after about 8 h, with no apparent yellowing or embrittlement of the polymer. Ether, ketone, and carboxyl groups were formed at uniform, but not equal, rates in the outer 60 Å of the polymer. With short reaction times the less highly oxidized groups were the main oxidation product, but after about 4 h the highly oxidized groups predominated. The aromatic rings underwent reaction as indicated by the rapid disappearance of the C_1s shake-up satellites on ozonation.     

Surface modification of polyethylene with multi-end-functional polyethylene additives

We have prepared and characterized a series of multifluorocarbon end-functional polyethylene additives, which when blended with polyethylene matrices increase surface hydrophobicity and lipophobicity. Water contact angles of >112° were observed on spin-cast blended film surfaces containing less than 1% fluorocarbon in the bulk, compared to ~98° in the absence of any additive. Crystallinity in these films gives rise to surface roughness that is an order of magnitude greater than is typical for amorphous spin-cast films but is too little to give rise to superhydrophobicity. X-ray photoelectron spectroscopy (XPS) confirms the enrichment of the multifluorocarbon additives at the air surface by up to 80 times the bulk concentration. Ion beam analysis was used to quantify the surface excess of the additives as a function of composition, functionality, and molecular weight of either blend component. In some cases, an excess of the additives was also found at the substrate interface, indicating phase separation into self-stratified layers. The combination of neutron reflectometry and ion beam analysis allowed the surface excess to be quantified above and below the melting point of the blended films. In these films, where the melting temperatures of the additive and matrix components are relatively similar (within 15 °C), the surface excess is almost independent of whether the blended film is semicrystalline or molten, suggesting that the additive undergoes cocrystallization with the matrix when the blended films are allowed to cool below the melting point.     

Surface characterization of ion-implanted polyethylene

Polyethylene (PE) film was implanted with 1000-keV Ar⁺ ions to a fluence of 5 × 10¹⁴ ions/cm² under high vacuum conditions (2.5 × 10⁻⁶ torr) and the film surface was investigated by means of microhardness and microwear measurements, and FTIR/ATR, Raman, and XPS techniques. Ion implantation significantly increased the subsurface hardness and also significantly improved the microwear resistance of the polymer. The implanted surface region of the film was found to consist of two distinct layers. One was the outermost carbon layer with a thickness of the order of 10 nm. In this layer, ca. 75% of carbon atoms were combined by graphitic sp² and diamond-like sp³ bonds, and the remaining 25% had chemical links with oxygen atoms. Spectroscopic data suggested that the sp²-bonded carbons segregated in graphite-like clusters containing imbedded oxygen atoms, interconnected by the sp³-bonded carbons. The other was the subsurface layer resulting from PE oxidation after ion-beam treatment. This layer was characterized by high contents of O H and CO groups as well as ester and double bonds. The chemical composition of the layer was uniform and did not vary over the layer thickness of about 1.4 μm. © 1998 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 36: 715–725, 1998     

Surface changes brought about by corona discharge treatment of polyethylene film and the effect on subsequent microbial colonisation

Microbial colonisation of synthetic plastic films is normally slow, which affects the total period of biodegradation. Correlation between the modified surface condition and the ability for microorganisms to colonise low-density polyethylene (LDPE) film was studied. Corona discharge treatment was applied to obtain enriched and activated surface condition of LDPE film. It was found from water contact angle and FTIR spectrum evaluations that surface energy was significantly increased due to production of free radicals. Stabilised oxidised LDPE surface was also obtained by further exposure to the corona which gave more suitable condition for subsequent colonisation. Results were compared with UV irradiated (photo-oxidised) LDPE films. Colonisation of corona discharged and UV treated LDPE films were tested in the laboratory environment using known fungal isolates and in a natural compost environment. More active microbial colonisation was observed in all cases for corona discharged and UV treated LDPE films. Far longer UV exposure was required to have the same physicochemical and biological effect as the corona discharge treatment.     

Determination of radioruthenium using a polyethylene film

A simple method is described for the determination of radioruthenium. A solution containing radioruthenium is placed in a conical flask with small amounts of sulfuric acid, silver nitrate, and potassium periodate. The mouth of the flask is covered with a thin polyethylene film, which is fixed with a soft rubber band, and the flask is heated for 2 hrs on a water bath. Radioruthenium is oxidized to tetroxide, evaporated by steam-distillation, and fixed quantitatively on the inner surface of the polyethylene film as a firm black stain. Contamination ratios of other nuclides are under 2·10^?4.     

Migration phenomena of surfactants in polyethylene film

Migration diffusion coefficients of two surfactants (sorbitan laurate, SPAN‐20 and sorbitan palmitate, SPAN‐40) in polyethylene blend are calculated in the desorption process by means of Fourier transform infrared (FT‐IR) spectroscopy technique at 25°C. They are 2.31 and 2.24 × 10⁻¹¹ cm²/s, respectively, which show no significant dependency of molecular weights of the surfactants on diffusion. The composition of LLDPE (linear low‐density polyethylene) and LDPE (low‐density polyethylene) in LLDPE blend is a 7 : 3 ratio, and ethylene acrylic acid (EAA) copolymer is used to verify its role as a migration controller. The key factor affecting the diffusion of the surfactant is suggested to be the segmental mobility by the semicrystalline LLDPE blend. Incorporation of 20 wt% EAA in the LLDPE blend retards the migration rate of the surfactants by reducing the diffusion coefficients to be 9.6 and 7.7 × 10⁻¹² cm²/s and this is believed to be due to the blocking effect of EAA. Although the diffusion coefficient was varied from system to system, the migration kinetics of the surfactants in short times obeys the Fickian behavior if the experimental error is allowed. © 1999 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 37: 1387–1395, 1999     

Piled-lamellae structure in polyethylene film and its deformation

The fine structure of polyethylene film has been investigated by using a high-resolution scanning electron microscope equipped with a field emission source. The original film surface of a-axis-oriented blown polyethylene film and the surface of a necked region formed by drawing the film in the machine direction were observed. High magnification electron micrographs indicate that the basic unit of internal texture of this film consists of piled-lamellae units, each pile containing three to ten lamellar crystal sheets. The piled-lamellae unit acts as one body and does not separate into single lamellae during deformation. Many tie fibrils are formed between adjacent piled-lamellae units, when the film is drawn in the machine direction. Although little attention has been given to this mechanism, it is important in deformation. This fact seems to be reflected in different shapes of the stress-strain curves of films drawn the machine direction and perpendicular to it.     

Surface conductance and film concentration potential

Summary A simple method for determining the film concentration potential (FCP) is described.The FCP appears when the film specific conductance (k _f ⁰ ) < 10^–7 ohms^–1.The FCP increases with decreasing values of the (k _f ⁰ ), reaching to a maximum at (k _f ⁰ ) k(k _s ⁰ ).

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Zusammenfassung Eine einfache Methode für die Bestimmung des Filmkonzentrations-Potentials (FCP) wird beschrieben. Das FCP tritt auf, wenn die spezifische Leitfähigkeit des Films kleiner als 10^{–7 –1} wird.Das Filmkonzentrationspotential steigt mit abnehmenden Werten der spezifischen Filmleitfähigkeit und erreicht ein Maximum für die Annäherung an gleichgroße Werte für ihre spezifische Oberflächenleitfähigkeit.

     

Thermal and mechanical behavior of polyethylene film obtained by orientational crystallization

The thermal and mechanical behaviour was measured in the U. S.for a polyethylene that had been prepared and highly drawn in the U. S. S. R. The melting point and percent crystallinity were evaluated in this studies as a function of heating rate and recrystallization. The Young's modulus and tensile stress to break in the orientation direction were 4.1 and 0.15 GPa, respectively.The tensile strain to break was about 8%.

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Zusammenfassung Das thermische und mechanische Verhalten eines in der UdssR hergestellten und stark gezogenen Polyäthylens wurde in den U. S. A. gemessen. Schmelzpunkt und Prozentsatz der Kristallinität wurden als Funktion der Aufheizgeschwindigkeit und Rekristallisation in den Untersuchungen ausgewertet. Der Young-sche Modulus und die Zugspannung zum Reissen in der Orientierungsrichtung betrugen 4.1, bzw. 0.15 GPa. Die Dehnung bis zum Bruch betrug etwa 8 %.

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Résumé On a effectué, aux Etats Unis, l'étude du comportement thermique et mécanique d'un polyéthylène préparé et fortement étiré en URSS. Le point de fusion et le pourcentage de cristallinité ont été évalués en fonction de la vitesse de chauffage et de la recristallisation. Lesvaleurs respectives du module d'Young et de la limite de rupture dans la direction d'orientation s'élèvent respectivement à 4.1 et 0.15 GPa. L'allongement à la rupture est d'environ 8%.

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, . . . 4.1 0.15 . 8%.

     

Surface modification of low density polyethylene (LDPE) film by low pressure O2 plasma treatment

In this work, low pressure glow discharge O₂ plasma has been used to increase wettability in a LDPE film in order to improve adhesion properties and make it useful for technical applications. Surface energy values have been estimated using contact angle measurements for different exposure times and different test liquids. In addition, plasma-treated samples have been subjected to an aging process to determine the durability of the plasma treatment. Characterization of the surface changes due to the plasma treatment has been carried out by means of Fourier transformed infrared spectroscopy (FTIR) to determine the presence of polar species such as carbonyl, carboxyl and hydroxyl groups. In addition to this, atomic force microscopy (AFM) analysis has been used to evaluate changes in surface morphology and roughness. Furthermore, and considering the semicrystalline nature of the LDPE film, a calorimetric study using differential scanning calorimetry (DSC) has been carried out to determine changes in crystallinity and degradation temperatures induced by the plasma treatment. The results show that low pressure O₂ plasma improves wettability in LDPE films and no significant changes can be observed at longer exposure times. Nevertheless, we can observe that short exposure times to low pressure O₂ plasma promote the formation of some polar species on the exposed surface and longer exposure times cause slight abrasion on LDPE films as observed by the little increase in surface roughness.     

Synthesis and characterization of polyethylene film grafted with acrylic acid and diethyleneglycol-dimethacrylate

Acrylic acid (AA) and diethyleneglycol-dimethacrylate (DEGDM) are grafted onto 25 μm low-density radio-peroxided polyethylene. Monomer content is determined by exchange capacity measurements. Studies of electrical resistance and zero-current membrane potential allow for the determination of the influence of DEGDM on both the dissociation of grafted AA and the permselectivity of these so-obtained cation-exchange membranes. DEGDM, acting as a crosslinking agent, limits the AA degree of grafting, slightly increases the electrical resistance, but contributes to enhance the permselectivity. For example, when these grafted films are immersed in 3M NaCl aqueous solutions, the addition of DEGDM leads to an increase of the transport number of Na⁺ close to 20%. © 1993 John Wiley & Sons, Inc.     

Effect of surface oxyfluorination on the dyeability of polyethylene film

The effect of surface oxyfluorination on low-density polyethylene (LDPE) film was studied in terms of surface functionality and surface energetics of the film surfaces, which can be attributed to improvement of the dyeability. The growth of functional groups and surface free energy was confirmed by FTIR-ATR, XPS, and contact angle methods. As a result, the total surface free energy was increased with oxyfluorination time, as a progressive increase of the polar component together with a small decrease of the dispersive component of surface free energy. From the dyeability test using the Kubelka-Munk equation, it was found that the oxyfluorination treatment plays an important role in the growth of oxygen-containing functional groups of LDPE film, resulting in improving the dyeability with a basic dyeing agent. A direct linear relationship is shown between the specific component of surface free energy and the K/S value for this work.     

Surface properties of polyethylene after low-temperature plasma treatment

The effect of oxygen and ammonia plasma treatments on changes of the surface properties of linear high-density polyethylene (HDPE) was studied. Surface energies of the polymer substrates were evaluated by contact angle measurements using Lifshitz-van der Waals acid-base approach. The surface energy of untreated HDPE is mainly contributed by Lifshitz-van der Waals interactions. After 5 min of plasma treatment, hydrogen bonds are formed on the surface, which is reflected in predominant acid-base interactions. The SEM results obtained demonstrate considerable changes of the surface roughness due to different types of the plasma gas used. Evolution of oxygen- or amino-containing moieties was detected by XPS and ATR FT IR. The prepared polyethylene surfaces were used as a basic support for further fabrication of novel hybrid biocomposite sandwich structures.