Mean-Square Radius of Gyration of Oligo- and Poly(α-methylstyrene)s in Dilute Solution

Yoshizaki

et al. 2005

Polym J

Self Cite

ABSTRACT:The power spectrum J À of the excess depolarized component of scattered light was determined from frequency-domain dynamic depolarized light scattering measurements for 10 samples of atactic oligo-and poly(-methylstyrene)s (a-PMS), each with the fraction of racemic diads f r ¼ 0:72, in the range of weight-average degree of polymerization x w from 2 to 67.1 in cyclohexane at 30.5 C (Â). It is found that, as in the cases of atactic polystyrene (a-PS), atactic poly(methyl methacrylate) (a-PMMA), and isotactic (i-) PMMA, J À may be well represented in terms of a single Lorentzian independently of x w , and that the relaxation time À as defined as the reciprocal of the half-width at half-maximum of J À evaluated at infinite dilution increases with increasing x w and levels off to its asymptotic value in the limit of x w ! 1, being consistent with the theoretical prediction on the basis of the helical wormlike (HW) chain model. A comparison is made of the present data for À with the HW theory, and it is shown that the theory may explain satisfactorily the data in the range of x w & 10, although semiquantitatively. For x w . 10, the rigid sphere model having the radius equal to the apparent root-mean-square radius of gyration of the HW chain may give a good explanation of À . From a comparison of the present results for À for a-PMS with previous ones for a-PS and a-and i-PMMAs, it is shown that there is good correlation between static and dynamic chain stiffness, the latter being defined as the ratio of the relaxation time associated with the local motion of the long chain to that of its isolated repeat unit (monomer), as predicted by the HW theory.

mentioning

confidence: 99%

mentioning

confidence: 99%

Dynamic Depolarized Light Scattering by Oligo- and Poly(α-methylstyrene)s in Dilute Solution

Ueda

Yoshizaki

et al. 2005

Polym J

Self Cite

“…14 In Figure 2, the values of n CH T 1 and NOE calculated from eqs 1 and 2, respectively, with eqs 7-9 and with the above values of ! I , !…”

Section: Dependences Of T 1 and Noe On X Wmentioning

confidence: 99%

Nuclear Magnetic Relaxation of Oligo- and Poly(α-methylstyrene)s in Dilute Solution

Ueda

Yoshizaki

et al. 2005

Polym J

Self Cite

ABSTRACT:The spin-lattice relaxation time T 1 and nuclear Overhauser enhancement NOE were determined for three samples of atactic oligo-and poly(-methylstyrene)s (a-PMS) with weight-average degree of polymerization x w ¼ 2, 3, and 67.1 in cyclohexane at 30 C. A comparison is made of the present data for T 1 and NOE with the helical wormlike (HW) chain theory, and it is shown that the theory may explain well the data for large x w (& 10). For smaller x w , the rigid sphere model having the radius equal to the apparent root-mean-square radius of gyration of the HW chain fails to give a quantitative explanation of T 1 in contrast to the case of the relaxation time À determined from dynamic depolarized light scattering measurements, indicating that the nuclear magnetic relaxation and dynamic depolarized light scattering cannot be described in terms of a common single relaxation time. However, it is shown that there is an effective (mean) magnetic relaxation time M approximately equal to 0:6 À . From a comparison of the present results for T 1 for a-PMS with previous ones for typical flexible polymers, it is also shown that the behavior of T 1 for them, including a-PMS, may be consistently explained by the use of M (proportional to À ).[DOI 10.1295/polymj.37.14] KEY WORDS Poly(-methylstyrene) / Nuclear Magnetic Relaxation / Spin-Lattice Relaxation Time / Nuclear Overhauser Enhancement / Helical Wormlike Chain / In the preceding paper, 1 we have examined the behavior of the relaxation time À defined by the reciprocal of the half-width at half-maximum of the spectrum J À of the excess depolarized component of the light scattered by atactic oligo-and poly(-methylstyrene)s (a-PMS) in cyclohexane at 30.5 C (Â). The quantity À represents a mean of relaxation (correlation) times of time-correlation functions of the spherical tensor components of the polarizability tensor affixed to the repeat unit of a polymer chain. In the framework of the dynamic theory for the (unperturbed) helical wormlike (HW) chain, 2,3 those timecorrelation functions are associated with the subspace LðnÞ ¼ 2ð1Þ (of full Hilbert space) spanned by the basis set with the ''total angular momentum quantum number'' L ¼ 2 and the number of ''excited'' subbodies n ¼ 1. The spin-lattice relaxation time T 1 and nuclear Overhauser enhancement NOE determined from nuclear magnetic relaxation measurements may also be written in terms of the time-correlation functions of the same class 2(1), 2,4,5 and therefore have a close relation to À . In the present paper as a continuation of the preceding one, 1 we report results of a nuclear magnetic relaxation study of a-PMS.We have already investigated T 1

“…Fig. 3 shows the ratio hS 2 i=x w (hS 2 i inÅ 2 ) plotted against the weight-average degree of polymerization x w for a-PaMS in cyclohexane at 30.5 1C ðYÞ [3] and for a-PS in cylohexane at 34.5 1C ðYÞ [7][8][9] in a semi-logarithmic manner. The experimental values of hS 2 i have been determined from small-angle X-ray scattering measurements for the samples with x w t10 3 and from static light scattering measurements for those with x w \10 3 .…”

Section: Mean-square Radius Of Gyrationmentioning

confidence: 99%

“…In this paper, we review our recent results of the fine characterizations carried out for two kinds of typical flexible polymers, atactic poly(a-methylstyrene) (a-PaMS) [3,4] and atactic polystyrene (a-PS) [5]. In Fig.…”

Section: Introductionmentioning

confidence: 99%

Fine characterization of oligomers and polymers in dilute solution

Science and Technology of Advanced Materials

2006

Self Cite

A fine characterization was made of atactic poly(a-methylstyrene) and atactic polystyrene on the basis of the helical wormlike chain model. It is found that there is a remarkable difference in chain stiffness and local chain conformation between the two polymers. Such a difference is shown to be reflected clearly in behavior of equilibrium, transport, and dynamical properties and also in the excludedvolume effects. r