Consequences of Grafting Density on the Linear Viscoelastic Behavior of Graft Polymers

Haugan, Ingrid N.; Maher, Michael J.; Chang, Alice B.; Lin, Tzu‐Pin; Grubbs, Robert H.; Hillmyer, Marc A.; Bates, Frank S.

doi:10.1021/acsmacrolett.8b00116

Cited by 103 publications

(148 citation statements)

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“…Several studies investigated the zero shear viscosity η 0 as a function of total molecular weight for different series of loose and dense bottlebrushes with either short chain branches (SCB) [13,18,19,24,[29][30][31]57] or long chain branches (LCB). [11,30] Within these bottlebrush series, two characteristics out of n sc , n g , and n bb are fixed and one of them is varied in the series.…”

Section: Zero Shear Viscositymentioning

confidence: 99%

“…Figure 5a presents the reduced η 0 for five bottlebrush series and a linear series at a reference temperature T ref = T g + 34 °C. [31] It was shown that η 0 versus M w has two different scaling regimes 1 and 3, which could be related to Rouse and reptation dynamics, respectively. These bottlebrushes were synthesized via ROMP of ω-norbornenyl polylactide macromonomers.…”

Section: Zero Shear Viscositymentioning

confidence: 99%

“…In both series, the DP of the backbone was below the entanglement length, n bb < n e,bb , and both series show almost a Rouse relaxation mechanism for η 0 . [31] dimethyl ester (DME) as comonomer to vary the grafting densities, [59] z ≅ 2.68/n g , PLA z -ran(DME) 1−z -NB-SCB.…”

Section: Zero Shear Viscositymentioning

confidence: 99%

“…In the current paper, we investigate the transitions from comb to bottlebrush behavior; therefore, all of these variables are used for both topologies especially in the transition from comb to bottlebrush conformations. Substantial experimental [11,[29][30][31] and coarse-grained simulation works along with scaling analysis [24,25,[32][33][34][35] have been done to classify graft polymers into comb and bottlebrush classes with distinct rheological and mechanical properties. Substantial experimental [11,[29][30][31] and coarse-grained simulation works along with scaling analysis [24,25,[32][33][34][35] have been done to classify graft polymers into comb and bottlebrush classes with distinct rheological and mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

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Comb and Bottlebrush Polymers with Superior Rheological and Mechanical Properties

2019

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combined with the grafting-to method [1,10] results in comb polystyrenes (PSs) with well-entangled monodisperse backbone and side chains; however, branch points along the backbone are randomly distributed. This random distribution of branch points has no distinct effect on the rheological properties of dense comb topologies; however, it will broaden the backbone relaxation time of loose comb topologies even though the molecular weight distribution is narrow enough. [11] A controlled branching point spacing can be achieved through the coupling of living macroanions; [12] however, this method is prone to slightly high molecular weight distribution, Ð > 1.5. Synthesis of welldefined densely grafted bottlebrushes using ROMP and grafting-through method guarantees the presence of one side chain per repeating unit on the backbone. Bottlebrushes with more than one branch per backbone repeating unit can also be synthesized using ROMP and macromonomers with more bulky groups referred as wedge polymers. [13] These bottlebrushes are similar to that of the dendronized polymer with only one layer of grafting. Loosely grafted bottlebrushes with longer distance between the branching points can be achieved using ROMP technique through copolymerization of macromonomer and a diluent molecule, e.g., racemic endo,exo-norbornenyl diesters, with different ratios. However, different reactivity of macromonomer and diluent leads to a gradient of branching point spacing along the backbone, [14] where the conformations of side chains along the backbone are affected by this gradient. [15] It should be mentioned that the bottlebrushes synthesized with ROMP technique have different repeating units in the backbone than the side chains which might cause microphase separation. However this issue could be ignorable in dense bottlebrushes where the volume fraction of backbone is less than 1 wt%. In order to avoid any microphase separation, Sheiko and co-workers [16] synthesized a series of dense combs and loose bottlebrushes homo poly(n-butyl acrylates) (PBA) with similar side chains and systematically varied grafting density through copolymerization of nonfunctional n-butyl acrylates with trimethylsilyl-protected acrylates by ATRP. However, in order to achieve high degree of polymerization (DP) of backbone (entangled system) for dense bottlebrushes, they had to use slightly different backbones, i.e., poly(n-butyl methacrylate). An organometallic coordinative insertion polymerization of α-olefins results in entangled densely grafted bottlebrushes with rod-like side chains where both backbone and side chains have alkane groups. However the dispersity index of such homopolymer bottlebrushes would Comb and bottlebrush polymers present a wide range of rheological and mechanical properties that can be controlled through their molecular characteristics, such as the backbone and side chain lengths as well as the number of branches per molecule or the grafting density. This review investigates the impact of these characteristics specifically on the zero sh...

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Section: Zero Shear Viscositymentioning

confidence: 99%

Section: Zero Shear Viscositymentioning

confidence: 99%

Section: Zero Shear Viscositymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comb and Bottlebrush Polymers with Superior Rheological and Mechanical Properties

2019

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“…The linear viscoelastic behavior of poly(norbornene)‐gr‐PLA obtained by living ROMP was studied, depending on the grafting density and total molar weight (Figure ) . It turned out that resulting polymers demonstrate Rouse and reptation dynamics with a sharp transition in zero‐shear viscosity data, demonstrating that grafting density strongly affects the entanglement molar weight.…”

Section: (Co) Polymerizationmentioning

confidence: 99%

Synthetic Methodologies for Chelating Polymer Ligands: Recent Advances and Future Development

Джардималиева

Uflyand

2018

ChemistrySelect

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This review summarizes recent progress in synthetic methodologies of chelating polymer ligands such as linear, branched, cross‐linked, grafted polymers, polymer films, liquid crystal polymers, dendrimers, star‐shaped and hyperbranched polymers. The features of methods for producing chelating polymer ligands are considered in detail: free‐radical (co)polymerization, living/controlled radical, metathesis, grafted, chemical oxidized, microwave‐assisted and asymmetric polymerization, electropolymerization, cyclopolymerization, polycondensation, post‐polymerization modification, click chemistry methods and “green” synthesis. The main directions of the development of synthetic chemistry of chelating polymeric ligands are analyzed. The bibliography includes works published in the last five years.

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Regulating the Conformational and Macroscopic Properties of Inorganic Nanowires by Polymer Grafts

Liu,

Dong,

Xia

et al. 2023

Adv Funct Materials

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Ultrathin inorganic nanowires are an emerging class of building blocks for creating functional materials and devices, but there remains challenging to fine‐tune the structure and property of the nanowires at the molecular level. Here, this work shows that ultrathin polymer‐grafted gold nanowires (PG‐AuNWs) can exhibit bottlebrush polymer‐like physical behaviors and macroscopic properties. The hybrid PG‐AuNWs in solutions show polymer‐like viscoelasticity which can be finely regulated by controlling the structural parameters (e.g., length of the AuNWs, molecular weight of grafted polymers) of the PG‐AuNWs, the environmental conditions (e.g., temperature, solvent compositions), and the aging time. Furthermore, this work unravels at the molecular level that the conformational properties (e.g., contour length, persistence length, and mean‐squared radius of gyration) of the PG‐AuNWs can be correlated to their structural parameters following similar power‐law relations as molecular bottlebrush polymers. This work bridges the fundamental gap between polymer‐like inorganic nanowires and bottlebrush polymers, thus accelerating the development of new nanowire‐based functional hybrid materials and devices.

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Consequences of Grafting Density on the Linear Viscoelastic Behavior of Graft Polymers

Cited by 103 publications

References 58 publications

Comb and Bottlebrush Polymers with Superior Rheological and Mechanical Properties

Comb and Bottlebrush Polymers with Superior Rheological and Mechanical Properties

Synthetic Methodologies for Chelating Polymer Ligands: Recent Advances and Future Development

Regulating the Conformational and Macroscopic Properties of Inorganic Nanowires by Polymer Grafts

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