Structure and Properties of Fatigued Segmented Poly(urethaneurea) I. Segment Orientation Mechanism due to Fatigue

Shibayama, Mitsuhiro; Kawauchi, Toshihito; Kotani, Tetsuo; Nomura, Shunji; Matsuda, Takehisa

doi:10.1295/polymj.18.719

Cited by 55 publications

(31 citation statements)

References 16 publications

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“…Similar critical behavior of SAXS has been reported previously for a number of analog SPUUs in DMAc. 4 These SAXS results, indicate that the microphase separation in SPUU solutions takes place in the vicinity of 25 wt% for the SPUU used in this study. This critical concentration is slightly higher than the concentration 15 wt% observed by fluorescence depolarization of Fl for the same solutions.…”

Section: Rotational Relaxation Of Fluorescein In Spuu Solutions and Tsupporting

confidence: 54%

“…Microphase separation of SPUUs has been studied by a number of experimental techniques including small angle X-ray scattering (SAXS). 4 However, SAXS requires a certain threshold for the contrast in electron density difference to be observable and therefore, it would be interesting to observe these segregation processes by some other alternative methods which are sensitive to the structural transition in solutions of SPUU. Fluorescence depolarization is a promising candidate because transitions in the local structures can be detected through the changes in transport coefficients such as rotational relaxation time.…”

Section: Introductionmentioning

confidence: 99%

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Segregation Processes in Segmented Polyurethaneurea Solutions Observed by Fluorescence Depolarization

Banda

Tran‐Cong‐Miyata

Nomura

1999

Polym J

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ABSTRACT:The onset of a segregation process in segmented polyurethaneurea (SPUU) solutions was studied by fluorescence spectroscopy using free fluorescein as a probe. For SPUUs with a given molecular weight and a constant ratio of the hard to soft segments, the time-resolved fluorescence measurements reveal the environmental inhomogeneity on the excited lifetime of fluorescein. It is shown in this work that the critical concentration for the segregation process detected by fluorescence spectroscopy through the transition of the anisotropy ratio of the fluorescein occurs at a concentration lower than that observed by small angle X-ray scattering (SAXS). These experimental results indicate that fluorescence depolarization can be used as an alternative method to investigate the structural transition in SPUU solutions.KEY WORDS Polyurethaneurea I Lifetime I Depolarization I Microdomain ISegmented polyurethaneurea (SPUU), are thermoplastic block copolymers which have mechanical properties similar to those of conventional elastomers. They belong to a class of (A-B)y type multi-block copolymers composed of two chemically dissimilar chain segments called hard and soft segments. 1 The hard segments act as multifunctional junctions, playing a role of both physical crosslinks and reinforcing fillers. These segments are formed by reacting an aromatic diisocyanate with a low molecular weight diol and/or diamine. On the other hand, the soft segments impart the elastomeric properties which are usually the aliphatic polyethers or polyester macroglycols. At low temperature, the low melting soft segments are incompatible with the hard segments of high melting point, leading to a microphase separation.Similar to multiphase polymeric materials, it is expected that the physical properties of SPUUs critically depend on the phase separation between the hard and soft segment components. In the past decade, a large number of studies were carried out to establish the correlation between the morphology and the mechanical as well as the thermal properties of polyurethanes. 2 • 3 Therefore, understanding of microphase separation processes is important for the control of the physical properties of these materials. Microphase separation of SPUUs has been studied by a number of experimental techniques including small angle X-ray scattering (SAXS). 4 However, SAXS requires a certain threshold for the contrast in electron density difference to be observable and therefore, it would be interesting to observe these segregation processes by some other alternative methods which are sensitive to the structural transition in solutions of SPUU. Fluorescence depolarization is a promising candidate because transitions in the local structures can be detected through the changes in transport coefficients such as rotational relaxation time. This provides an alternative method to observe the microphase separation from the dynamic point of view. Furthermore, the rotational relaxation time is directly t To whom correspondence should be addressed. related to th...

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Section: Rotational Relaxation Of Fluorescein In Spuu Solutions and Tsupporting

confidence: 54%

Section: Introductionmentioning

confidence: 99%

Segregation Processes in Segmented Polyurethaneurea Solutions Observed by Fluorescence Depolarization

Banda

Tran‐Cong‐Miyata

Nomura

1999

Polym J

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“…8 Although no direct correlation to the rate of degradation has yet been demonstrated, phase mixing of hard-and soft-segment domains, as has been observed during uniaxial fatigue of a polyurethane in air, [13][14][15] potentially increases the rate of degradation by increasing the diffusion rate of reactive species. If and how these effects contribute to chemical degradation depends on the specific loading conditions.…”

Section: Chemical Degradationmentioning

confidence: 99%

Effect of strain and strain rate on fatigue‐accelerated biodegradation of polyurethane

Wiggins

Anderson

Hiltner

2003

J Biomedical Materials Res

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A diaphragm-type film specimen was used to study in vitro degradation of poly(etherurethane urea) (PEUU) under conditions of dynamic loading. This geometry allowed both uniaxial and biaxial loading in a single experiment. During testing, the film was exposed to a H(2)O(2)/CoCl(2) solution that simulated in vivo oxidation of PEUU. The combination of dynamic loading and biaxial tensile strain accelerated oxidative degradation. The effects of biaxial strain magnitude and strain rate were examined separately by increasing the frequency of fatigue loading from 0 to 1 Hz with constant maximum biaxial strain and by changing the maximum biaxial strain while maintaining constant strain rate. In the ranges of biaxial strain energy (0.17 to 0.55 MPa) and strain rate (0 to 46% s(-1)) tested, the rate of degradation increased with increasing strain rate whereas strain magnitude had essentially no effect on degradation rate. Although loading conditions affected the rate of oxidative degradation, ATR-FTIR analysis suggested that in all cases the mechanism of degradation did not change. Chemical degradation produced a brittle crosslinked surface layer marked by dimpling and pitting, as observed with scanning electron microscopy. Pits served as stress concentrators and initiated environmental stress cracks under dynamic loading but not under static (creep) loading. Small pits were sufficient to initiate cracks at higher strain rates whereas only large pits initiated cracks at lower strain rates. Consequently, a higher strain rate produced more profuse cracking.

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“…The details of the fatigue test are described in ref 6. The fatigued sample code is designated by attaching the fatigue time in thousand seconds after the as-cast sample code as we employed in ref 6.…”

Section: Fatigue Testmentioning

confidence: 99%

Structure and Properties of Fatigued Segmented Poly(urethaneurea)s II. Structural Analyses of Fatigue Mechanism

Shibayama

Ohki

Kotani

et al. 1987

Polym J

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ABSTRACT:The fatigue mechanism of segmented poly(urethaneurea)s due to a sinusoidal strain was investigated from the structural point of view by means of small angle light scattering (SALS), small angle X-ray scattering (SAXS), and infrared dichroism (IRD) and was compared with the uniaxial deformation mechanism. The SALS patterns of the original sample films indicated the existence of a spherulite texture. There appeared a ring diffraction pattern in the SAXS photograph for the as-cast sample. The diffraction pattern came to have azimuthal angular dependence when stretched or fatigued; which was characterized by a defect in intensity in the stretching direction and a local concentration in intensity at the edge of the defect. Those indicated a selective destruction of the hard segment domain in the equatorial zone of the spherulite. The fatigued mechanism is proposed in order to account for the experimental results based on the spherulite deformation model. It was also found that samples having longer soft segments have higher degree of phase separation at the beginning and that these mechanical properties and orientational behavior are less sensitive to fatigue time.KEY WORDS Poly(urethaneurea) I Fatigue Mechanism I Spherulite Deformation I Infrared Dichroism I Small Angle X-Ray Scattering I Small Angle Light Scattering I Segmented poly(urethaneurea)s (SPUU) and segmented poly(urethane)s (SPU) have been considered for use as high performance elastomeric materials. The unique mechanical properties of SPUU and SPU result from their heterogeneous microdomain structure composed of the hard and the soft segments. Hydrogen bonding also plays an important role in its properties. Structures of SPUU has been extensively studied in terms of DSC, infrared dichroism (IRD), small angle X-ray (SAXS) and neutron scattering (SANS) techniques.1 -? Kimura et a/. 1 · 5 utilized small angle light scattering (SALS), SAXS, and IRD and studied the deformation mechanism of SPUU. They found a spherulitic structure in SPUU and explained the deformation mechanism of SPUU by the analogy of the deformation mechanism of crystalline polymers, e.g., polyethylene. Bonart et a/. 8 • 9 proposed a different model of deformation on segmented poly(urethane) (SPU), which is based on rotation of a particle having an anisotropic shape in a flow field (domain orientation) followed by segment orientation. The deformation mechanism of SPUU and/or of SPU is, however, still an open question. This fact is partially due to the complexity of the microdomain structure of SPUU and SPU. It is clear that ·the deformation mechanism depends on the chemical structure of SPUU or SPU.Desper et a/. 10 proposed three possible models of deformation: a shear model, a tensile model, and a rotation or translation of inde-1067

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Structure and Properties of Fatigued Segmented Poly(urethaneurea) I. Segment Orientation Mechanism due to Fatigue

Cited by 55 publications

References 16 publications

Segregation Processes in Segmented Polyurethaneurea Solutions Observed by Fluorescence Depolarization

Segregation Processes in Segmented Polyurethaneurea Solutions Observed by Fluorescence Depolarization

Effect of strain and strain rate on fatigue‐accelerated biodegradation of polyurethane

Structure and Properties of Fatigued Segmented Poly(urethaneurea)s II. Structural Analyses of Fatigue Mechanism

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