Dynamics of semiflexible regular hyperbranched polymers

Fürstenberg, Florian; Dolgushev, Maxim; Blumen, A.

doi:10.1063/1.4775584

Cited by 32 publications

(61 citation statements)

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“…Such a procedure was first introduced for fully flexible dendrimers of functionality f = 3 [43] and later extended to arbitrary functionalities [47,48]; see also recent general results [49] for flexible dendritic structures. The works in [39,40] illustrate that an extension of the procedure is also applicable to semiflexible dendrimers and semiflexible Vicsek fractals. Here, we find (G + 1) groups of eigenvectors for a T-fractal of generation G. Among them, the first G groups are based on the branches Z (1) to Z (G) , whereas the (G + 1)-th group involves the motion of all beads, including the central one (in the case of semiflexible dendrimers [39], the groups 1 to G represent the dynamics of dendrons of the generations 1 to G, and the (G + 1)-th group involves the motion of all dendrimer's beads).…”

Section: Hierarchical Eigenmodes Of T-fractalsmentioning

confidence: 99%

“…In Equation (40), the F(n − 1) × F(n − 1) matrix A n−1 describes the two terminal Z (n−1) branches, whereas the internal Z (n−1) branch is described by the (F(n) − F(n − 1)) × (F(n) − F(n − 1)) matrix L n−1 . The blocks W 12 and W 21 reflect the interaction of the two external branches with the internal branch.…”

Section: Reduced Matricesmentioning

confidence: 99%

“…This work employs the framework of semiflexible treelike polymers (STP) [35], which allows one to study arbitrary treelike architectures and to obtain many results in closed form. In particular, the STP framework allows us to determine in this work a complete set of eigenmodes of semiflexible T-fractals, following the procedure put forward by Cai and Chen for fully-flexible dendrimers [43] that has been recently extended to semiflexible structures, namely dendrimers [39] and Vicsek fractals [40]. This procedure reduces the numerical effort and gives an intuitive sense to the structure of eigenmodes and of the corresponding relaxation spectra.…”

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confidence: 99%

“…Semiflexibility was first introduced to the dynamics 37 of discrete chains by Bixon and Zwanzig [30], later it was included to the description of other 38 macromolecular architectures [31][32][33][34][35][36][37][38][39][40][41]. This work employs the framework of semiflexible treelike 39 polymers (STP) [34] which allows to study arbitrary treelike architectures and to obtain many results 40 in closed form. In particular, the STP framework allows us to determine in this work a complete 41 set of eigenmodes of semiflexible T-fractals, following the procedure put forward by Cai and Chen…”

mentioning

confidence: 99%

“…An improved description of the polymer's dynamics is achieved by introducing local semiflexibility in the GGS model, which turns out to be very important for dendritic structures [29,30]. Semiflexibility was first introduced to the dynamics of discrete chains by Bixon and Zwanzig [31]; later, it was included to the description of other macromolecular architectures [32][33][34][35][36][37][38][39][40][41][42]. This work employs the framework of semiflexible treelike polymers (STP) [35], which allows one to study arbitrary treelike architectures and to obtain many results in closed form.…”

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Relaxation Dynamics of Semiflexible Fractal Macromolecules

Mielke

Dolgushev

2016

Polymers

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Abstract:We study the dynamics of semiflexible hyperbranched macromolecules having only dendritic units and no linear spacers, while the structure of these macromolecules is modeled through T-fractals. We construct a full set of eigenmodes of the dynamical matrix, which couples the set of Langevin equations. Based on the ensuing relaxation spectra, we analyze the mechanical relaxation moduli. The fractal character of the macromolecules reveals itself in the storage and loss moduli in the intermediate region of frequencies through scaling, whereas at higher frequencies, we observe the locally-dendritic structure that is more pronounced for higher stiffness.

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Section: Hierarchical Eigenmodes Of T-fractalsmentioning

confidence: 99%

Section: Reduced Matricesmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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confidence: 99%

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Relaxation Dynamics of Semiflexible Fractal Macromolecules

Mielke

Dolgushev

2016

Polymers

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Molecular Dynamics Simulations of Hyperbranched PAMAM Vicsek Fractals

Fürstenberg

Gurtovenko

Dolgushev

et al. 2014

Macro Theory & Simulations

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Within the broad class of hyperbranched polymers, highly symmetrical objects (such as dendrimers and Vicsek fractals) are of special theoretical interest. Here we study, using the MARTINI force-field, polyamidoamine Vicsek fractals (PVF) in silico, focusing on their structure and dynamics in dilute solution. Our extensive microsecond-long simulations show that the radius of gyration of PVF scales with the molecular weight as N 0.54 , behavior rather close to that of stars and considerably distinct from that of dendrimers. The study of the radial density profiles indicates that different parts of the PVF interpenetrate significantly, fact which stresses the soft and sparse character of PVF. These results are also supported by our findings for the rotational autocorrelation functions.

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