The influence of short branches on the α, β and γ‐relaxation processes of ultra‐high strength polyethylene fibers

Ohta, Yasuo; Yasuda, Hiroshi

doi:10.1002/polb.1994.090321311

Cited by 51 publications

(52 citation statements)

References 24 publications

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“…Fig. 7 demonstrates that the apparent activation energy of HDPE far below the melting temperature is about 78 kJ/mol, which is lower than the values provided in some studies grounded on the standard method of superposition of observations in dynamic tests: E a ¼ 110-140 (Zamfirova et al, 2002), E a ¼ 137 (Pegoretti et al, 2000), E a ¼ 150-170 (Mano et al, 2001), E a ¼ 174 (Djokovic et al, 2000), and E a ¼ 207 kJ/mol (Tajvidi et al, 2005), but agrees well with the activation energies E a ¼ 50-140 (Stadler et al, 2005), E a ¼ 65-80 (Boiko et al, 1995), E a ¼ 79-106 (Matsuo et al, 1988), and E a ¼ 89 kJ/mol (Ohta and Yasuda, 1994). The fact that the apparent activation energy of HDPE in the solid state exceeds that of HDPE melt by twice [in the latter case, the activation energy belongs to the interval between 27 and 32 kJ/mol (Bin Wadud and Baird, 2000)] appears to be natural, whereas rather high values of the activation energies (close to the activation energies for thermal degradation of this polymer [E a ¼ 210-270 (Sinfronio et al, 2005) and E a ¼ 260-290 kJ/mol (Marazzato et al, 2007)] ''shows that the physical significance of E a .…”

Section: Discussionsupporting

confidence: 65%

Thermo-viscoelastic and viscoplastic behavior of high-density polyethylene

Drozdov

Yuan

2008

International Journal of Solids and Structures

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a b s t r a c tObservations are reported on high-density polyethylene in uniaxial tensile tests with constant strain rates and relaxation tests at various temperatures ranging from 25 to 90°C. A constitutive model is derived for the nonlinear viscoelastic and viscoplastic behavior of semi-crystalline polymers at three-dimensional deformations. Adjustable parameters in the stress-strain relations are found by fitting the experimental data. It is demonstrated that (i) the model correctly approximates the observations and (ii) material parameters are independent of strain rate and change consistently with temperature.

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Section: Discussionsupporting

confidence: 65%

Thermo-viscoelastic and viscoplastic behavior of high-density polyethylene

Drozdov

Yuan

2008

International Journal of Solids and Structures

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“…Crystalline structure of LDPE nanofibers were also determined using DSC at a heating rate of 10 °C · min −1 under nitrogen atmosphere and wide angle X‐ray diffractometer (WAXD), as shown in Figure 7 and 11, respectively. Figure 7 shows an endothermic shoulder around 70 °C in all thermograms, which was a result of the α ‐relaxation of PE involving the molecular mobility within the crystalline phase 25, 26. The melting temperatures were almost the same for all samples, with peaks around 111 °C.…”

Section: Resultsmentioning

confidence: 93%

Fabrication of Tunable Submicro‐ or Nano‐Structured Polyethylene Materials from Immiscible Blends with Cellulose Acetate Butyrate

Wang

Sun

Chiou³

2008

Macro Materials & Eng

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Low density polyethylene (LDPE) was prepared into micro‐ or submicro‐spheres or nanofibers via melt blending or extrusion of cellulose acetate butyrate (CAB)/LDPE immiscible blends and subsequent removal of the CAB matrix. The sizes of the PE spheres or fibers can be successfully controlled by varying the composition ratio and modifying the interfacial properties of the blends. The surface structures of LDPE micro‐ or submicro‐spheres and nanofibers were analyzed using SEM and FTIR‐ATR spectroscopy. In addition, the crystalline structures of the LDPE nanofibers were characterized.magnified image

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“…Indeed, for PE with 12.5 methyl branches/1000 methylene units an increase of activation energy of the α c -relaxation was observed from 147 to 227 kJ·mol −1 , which was ascribed to the hindrance of chain-to-chain slippage. 36 To summarize, even though ester groups do not appear to have a significant effect on the crystalline structure, irregular stacking of the ester groups seems to increase the crystal mobility, thereby lowering the yield stress of the associated polymer.…”

Section: ■ Results and Discussionmentioning

confidence: 98%

Influence of the Main-Chain Configuration on the Mechanical Properties of Linear Aliphatic Polyesters

2015

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Linear aliphatic polyesters have been investigated extensively over the last decades. However, the relation between the configuration of the ester groups in the main chain and the mechanical properties is only poorly understood. Therefore, in this work the influence of the composition of these polymers on the morphology, mechanical properties and relaxation processes for a set of random copolymers of ε-caprolactone (CL) and ω-pentadecalactone (PDL) is explored. For these isomorphic copolymers, the crystallinity and lamellar thickness was shown to be independent of the composition over the largest part of the composition range. However, the yield stress does decrease significantly when comonomers were introduced in either of the homopolymer chains. Dynamic mechanical analysis revealed an additional high-temperature relaxation process for the copolymers, which was attributed to mobility of the crystalline phase (α c -mobility) and is responsible for the decrease in yield stress relative to the homopolymers. The origin of this mobility was related to the stacking of the ester groups in the crystal lamellae, which occurs less regular in copolymers and therefore gives rise to lower energy barriers for defect propagation (responsible for α c -mobility). Furthermore, the yield-kinetics of polypentadecalactone and two copolymers were accurately captured using the Ree−Eyring theory, showing the relation between α c -mobility and the contribution of both interlamellar and intralamellar shear to the yield stress. ■ INTRODUCTIONAliphatic long-chain polyesters (ALCPEs) are interesting alternatives for polyethylenes in high-end applications, since their structure can be tuned to include additional functionalities, such as degradability, which is difficult to achieve for polyethylene. 1−3 The "PE-like" character of this class of polymers originates from their long linear methylene backbone dominating the crystallization behavior and crystal structure, as well as the resulting mechanical properties. 4−6 An example is polypentadecalactone, which crystallizes in an orthorhombic unit cell with dimensions very similar as for PE. 7 The ester groups fit well in the orthorhombic unit cell, leading to the inclusion of these groups with only a minor associated expansion of the unit cell dimensions compared to PE. 7 The most profound effect of the inclusion of ester groups is an enthalpic penalty reducing the heat of fusion of the crystal, which simultaneously decreases the melting temperature. 8,9 Nevertheless, the crystallinity remains high (>50%) independent of the amount of ester groups in the backbone of the polymer.Even though there are many reports on the synthesis and thermal properties of ALCPEs, 10−15 a systematic investigation into the influence of the amount and configuration of the ester groups on the mechanical properties has to our knowledge not been performed. Copolymers of ω-pentadecalactone (PDL) and ε-caprolactone (CL) are ideal candidates for such an investigation, since the random copolymers are easily synthesized in ...

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The influence of short branches on the α, β and γ‐relaxation processes of ultra‐high strength polyethylene fibers

Cited by 51 publications

References 24 publications

Thermo-viscoelastic and viscoplastic behavior of high-density polyethylene

Thermo-viscoelastic and viscoplastic behavior of high-density polyethylene

Fabrication of Tunable Submicro‐ or Nano‐Structured Polyethylene Materials from Immiscible Blends with Cellulose Acetate Butyrate

Influence of the Main-Chain Configuration on the Mechanical Properties of Linear Aliphatic Polyesters

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