Polyethylene films were stressed in uniaxial tension at room temperature while the infrared (FTIR) or Raman spectra were simultaneously measured. The purpose of these experiments was to gain an understanding of the molecular origins of the stress‐induced vibrational frequency shifts Δν and determine the mechanisms of molecular deformation and fracture of PE molecules with stress σ. The PE samples consisted of ultradrawn, high‐density, ultrahigh‐molecular‐weight, solid‐state‐extruded films and the stress was applied parallel to the nearly perfectly oriented orthorhombic crystal c‐axis direction. The experimental frequency shifting coefficients α = (∂ν/∂σ)σ→0 were compared with calculated α values determined from a vibrational analysis of an isolated PE chain using conformational energy minimization methods in which both harmonic and anharmonic (Morse) potential energy functions were used for the CC stretching modes in the valence force field. The following α values were obtained and are compared with theory (anharmonic case in parentheses, in cm−1/GPa): CC symmetric stretch, α(1127) = −5.9 (−5.3); CC asymmetric stretch, α(1059) = −11.2 to −5.7 (−5.8); CH2 rock, α(730/720) = −2.0 to −3.0 (−2.2); CH2 scissors, α(1472/1462) = −1.0 to −1.2 (−1.1); CH2 twist, α(1295) ≃ 0(0.8); CH2 wag, α(1370) undetermined owing to weak bands (−4.6); CH2 stretch α(3000) ≈ 0. The largest negative frequency shifts were observed for the CC stretching modes, in agreement with the calculations using the Morse potential. The harmonic potential for CC stretching resulted in small positive α values for both the CC stretching and CH2 wagging modes, while the other modes were unaffected by this choice of potential. The relative contribution of CC bond stretching and CĈC valence angle bending to the c‐axis strain was about 1:1, in agreement with experiment. The Young's tensile modulus of a PE chain was calculated as Ec = 267 GPa.
The effect of stress and temperature on infrared frequency shifting and band asymmetry in polymers is investigated. Valence coordinate deformation of individual polypropylene chains accounts for the observed frequency shifting in samples of oriented isotactic polypropylene. Each chain may be modeled as a one-dimensional enharmonic system, whose wave functions and energies are obtained in the quasi-harmonic approximation. The theoretical stress-induced frequency shifting coefficient is related to the Gmneisen parameter and is expressed by ac = -a0 -CTosc, where a0 and C are positive constants and Toer is the temperature of the oscillators in equilibrium with the radiation field. Two mechanisms of band broadening are considered: The first is due to the presence of an average interchain perturbing force. The second is due to the existence of anisotropic crystal field forces. Each description predicts symmetric broadening. Therefore, the development of an observable asymmetry in a stressed infrared band may be associated with a nonuniform molecular stress distribution. Only the crystal field broadening mechanism, however, is consistent with the assumptions required for calculation of the linear ac(T) relation, which agrees well with experiments on oriented polypropylene. The anisotropic broadening mechanism is also investigated for oriented polyethylene.
Chronic progressive nephropathy (CPN) is a spontaneous renal disease of rats which can be a serious confounder in toxicology studies. It is a progressive disease with known physiological factors that modify disease progression, such as high dietary protein. The weight of evidence supports an absence of a renal counterpart in humans. There is extensive evidence that advanced CPN, particularly end-stage kidney, is a risk factor for development of a background incidence of atypical tubule hyperplasia and renal tubule tumors (RTT). The likely cause underlying this association with tubule neoplasia is the long-term increased tubule cell proliferation that occurs throughout CPN progression. As a variety of chemicals are able to exacerbate CPN, there is a potential for those exacerbating the severity up to and including end-stage kidney to cause a marginal increase in RTT and their precursor lesions. Extensive statistical analysis of National Toxicology Program studies shows a strong correlation between high-grade CPN, especially end-stage CPN, and renal tumor development. CPN as a mode of action (MOA) for rat RTT has received attention from regulatory authorities only recently. In the absence of toxic effects elsewhere, this does not constitute a carcinogenic effect of the chemical but can be addressed through a proposed MOA approach for regulatory purposes to reach a decision that RTT, developing as a result of CPN exacerbation in rats, have no relevance for human risk assessment. Guidelines are proposed for evaluation of exacerbation of CPN and RTT as a valid MOA for a given chemical.
Dans le cas de bandes intenses des artefacts dus au processus d'apodisation peuvent apparaître dans les spectres infrarouges obtenus par transformée de Fourier. Ces effets ont déjà été étudiés sur des spectres obtenus par différence pour des fonctions d'apodisation de type boxcar ou triangulaire. Ce travail présente des simulations numériques réalisées avec une fonction d'apodisation de type Happ-Genzel couramment employée dans les instruments modernes. Pour comparer les performances des fonctions d'appareil de type boxcar, triangulaire, ou Happ-Genzel nous avons calculé (i) les artefacts apparaissant dans les spectres obtenus par différence ; (ii) la variation de l'absorbance apparente au sommet d'un pic d'absorption en fonction de l'absorbance vraie ; (iii) une mesure intégrée de l'erreur due à ces artefacts pour une bande d'absorption à profil lorentzien. L'étude est faite pour des valeurs de p (rapport de la largeur totale du pic à mi-hauteur à la résolution) qu'on rencontre couramment en spectroscopie de transmission d'échantillons solides ou translucides.Abstract. -Artifacts may occur in Fourier transform infrared (FTIR) spectra due to the apodization of the interferograms of intense bands. Selected examples of boxcar and triangular apodization effects on difference spectra have been previously reported. This paper reports the first such calculation performed for the Happ-Genzel apodization function, which is often used on modern spectrometers. In order to compare boxcar, triangular, and Happ-Genzel apodization functions we calculate (i) difference-spectrum artifacts, (ii) apparent versus true peak absorbances, and (iii) a measure of integrated artifact area for several true peak intensities of Lorentzian-band shapes. Values of p (ratio of full bandwidth at half height to nominal resolution) are emphasized which commonly occur in the transmission-mode spectroscopy of transparent or translucent solid samples.
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