The study of the structure factor of a wormlike chain in an orientational external field

Jiang, Ying; Zhang, Xinghua; Miao, Bin; Yan, Dadong

doi:10.1063/1.4917520

Cited by 8 publications

(10 citation statements)

References 69 publications

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“…Dashed lines in the figure indicate the initial slope to determine ⟨ S 2 ⟩ z and P ( q ). The second virial coefficient A 2 was estimated from the slope of [ c /Δ I (0)] 1/2 (filled squares) using the M w data mentioned in the former section with the same method reported in ref , in which the optical constant was estimated from [ c /Δ I (0)] c 0 1/2 and the M w value. The resultant ⟨ S 2 ⟩ z and A 2 data are listed in Table along with the M w values.…”

Section: Resultsmentioning

confidence: 99%

Chain Dimensions and Stiffness of Cellulosic and Amylosic Chains in an Ionic Liquid: Cellulose, Amylose, and an Amylose Carbamate in BmimCl

et al. 2017

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Small-angle X-ray scattering measurements were made for cellulose, amylose, and amylose tris(ethylcarbamate) (ATEC) in an ionic liquid [1-butyl-3-methylimidazolium chloride (BmimCl)] at 25 C to determine z-average mean-square radius of gyration S 2 z and the particle scattering function P(q). The obtained data were analyzed in terms of the wormlike chain model to estimate the Kuhn segment length  −1 (the stiffness parameter, equivalent to twice of the persistence length) and the helix pitch (or helix rise) per residue h. The chain stiffness ( −1 ) was determined to be 7  1 nm for cellulose, 3.5  0.5 nm for amylose, and 7.5  0.5 nm for ATEC. These values are almost the same or somewhat smaller than those of previously investigated systems, indicating these polymers have relatively high flexibility in the ionic liquid. It is reasonable to suppose that disruption of intramolecular hydrogen bonds of polysaccharide makes the main chain rather flexible in the ionic liquid.Kratky-Porod (KP) wormlike chain model 14 to determine the chain stiffness parameter  −1 (the Kuhn segment length or twice of the persistence length). 2The chain stiffness of cellulosic and amylosic chains in solution has been widely investigated in various solvents. [15][16] Cellulose is classified to as a semiflexible polymer of which  −1 was thus determined in aqueous metal complexes, [17][18][19][20] in aqueous LiOH/urea, 21 in aqueous NaOH/urea, 22 in aqueous NaOH, 23 and in LiCl/amide solvents. [24][25][26] The  −1 values vary from 8 to 50 nm depending on the solvent. Meanwhile, amylose behaves as a flexible polymer in various common organic solvents and aqueous solutions, [27][28][29] where  −1 is 2 -3 nm, (or 4 nm when analyzing the data in terms of the helical wormlike chain). 30 The exception is  −1 = 18 nm in aqueous iron-sodium tartrate. 15,18 Appreciable solvent dependent chain conformation was however found for amylose carbamate derivatives. [31][32][33][34][35] Those derivatives can form the intramolecular hydrogen bonding between carbamate groups on neighboring glucose units, depending on the solvent, which plays an important role in the chain stiffness. The chain stiffness parameters  −1 obtained in this study for cellulose, amylose, and ATEC in BmimCl are compared with the literature results in different solvents, to argue the conformational nature of the polysaccharides in the ionic liquid. Experimental SectionSamples and test solutions. Cellulose. Two cellulose samples, that is, Avicel PH-101 (Asahi Kasei) and 'Cellulose' (microcrystalline powder, Sigma) were used for this study without further purification and designated to be Cell38K and Cell37K, respectively. The weight-average molar mass Mw was estimated to be 3.8 × 10 4 g mol −1 and 3.7 × 10 4 g mol −1 for Cell38K and Cell37K, respectively, from the intrinsic viscosity [] in aqueous 6 wt % NaOH/4 wt % urea with the literature [] -Mw relationship. 22 The Mw value and the dispersity index Ð defined as the ratio of Mw to the number average molar mass were also rou...

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Section: Resultsmentioning

confidence: 99%

Chain Dimensions and Stiffness of Cellulosic and Amylosic Chains in an Ionic Liquid: Cellulose, Amylose, and an Amylose Carbamate in BmimCl

et al. 2017

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“…28−30 A good candidate for developing the general framework is the WLC model for semiflexible polymers. On the one hand, the exact solutions to the WLC model from the path integral scheme 31,32 and the green function scheme 33−38 become available recently to allow a precise counting of the conformational entropy, which remains difficult for other methods like atomic simulations. The new solutions are already applied to study polymer brush 36,38 and diblock copolymer melt.…”

Section: Resultsmentioning

confidence: 99%

Polymer-Based Accurate Positioning: An Exact Worm-like-Chain Study

et al. 2018

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Precise positioning of molecular objects from one location to another is important for nanomanipulation and is also involved in molecular motors. Here, we study single-polymer-based positioning on the basis of the exact solution to the realistic three-dimensional worm-like-chain (WLC) model. The results suggest the possibility of a surprisingly accurate flyfishing-like positioning in which tilting one end of a flexible short polymer enables positioning of the other diffusing end to a distant location within an error of ∼1 nm. This offers a new mechanism for designing molecular positioning devices. The flyfishing effect (and reverse process) likely plays a role in biological molecular motors and may be used to improve speed of artificial counterparts. To facilitate these applications, a new force–extension formula is obtained from the exact WLC solution. This formula has an improved accuracy over the widely used Marko–Siggia formula for stretched polymers and is valid for compressed polymers too. The new formula is useful in analysis of single-molecule stretching experiments and in estimating intramolecular forces of molecular motors, especially those involving both stretched and compressed polymer components.

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“…To solve the SCFT model for the isotropic-nematic transition, Spakowitz and Wang proposed an exact theoretical approach based on the Laplace-transformed partition function of a wormlike chain [67]. By examining the crossing of the isotropic and nematic branches of the free energy, Jiang et al numerically located the transition point in Nυ and the jump of the orientational order parameter S at the transition [45]. Letting L/2Lp=2.7848 yields Nυ=40.704 and S=0.353, exactly matching the transition point presented in Figure 3f.…”

Section: The Isobaric Propertiesmentioning

confidence: 99%

“…SCFT schemes based on MS-type (Maier–Saupe) models have been applied to a broad range of systems: from solutions and melts of homopolymers [42,43,44,45], to nanostructured block-copolymer melts [46,47,48,49,50,51,52,53,54]. Currently there is an increased interest in employing mean-field approaches based on MS-type models for the description of nematic mesophases of conjugated polymers (e.g., see [9,15,55,56]).…”

Section: Introductionmentioning

confidence: 99%

Thermodynamics of a Compressible Maier-Saupe Model Based on the Self-Consistent Field Theory of Wormlike Polymer

et al. 2017

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This paper presents a theoretical formalism for describing systems of semiflexible polymers, which can have density variations due to finite compressibility and exhibit an isotropic-nematic transition. The molecular architecture of the semiflexible polymers is described by a continuum wormlike-chain model. The non-bonded interactions are described through a functional of two collective variables, the local density and local segmental orientation tensor. In particular, the functional depends quadratically on local density-variations and includes a Maier-Saupe-type term to deal with the orientational ordering. The specified density-dependence stems from a free energy expansion, where the free energy of an isotropic and homogeneous homopolymer melt at some fixed density serves as a reference state. Using this framework, a self-consistent field theory is developed, which produces a Helmholtz free energy that can be used for the calculation of the thermodynamics of the system. The thermodynamic properties are analysed as functions of the compressibility of the model, for values of the compressibility realizable in mesoscopic simulations with soft interactions and in actual polymeric materials.

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The study of the structure factor of a wormlike chain in an orientational external field

Cited by 8 publications

References 69 publications

Chain Dimensions and Stiffness of Cellulosic and Amylosic Chains in an Ionic Liquid: Cellulose, Amylose, and an Amylose Carbamate in BmimCl

Chain Dimensions and Stiffness of Cellulosic and Amylosic Chains in an Ionic Liquid: Cellulose, Amylose, and an Amylose Carbamate in BmimCl

Polymer-Based Accurate Positioning: An Exact Worm-like-Chain Study

Thermodynamics of a Compressible Maier-Saupe Model Based on the Self-Consistent Field Theory of Wormlike Polymer

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