The architecture of the adsorbed layer at the substrate interface determines the glass transition of supported ultrathin polystyrene films

Sun, Shuzheng; Xu, Huiwen; Han, Jun; Zhu, Yiming; Zuo, Biao; Wang, Xinping; Zhang, Wei

doi:10.1039/c6sm01500j

Cited by 50 publications

(61 citation statements)

References 75 publications

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“…Napolitano et al [11][12][13][14] demonstrated that substrate effects on the glass transition temperature (T g ) and segmental dynamics, measured in thin films upon confinement, could be directly related to the degree of chain adsorption at the substrate. Koga et al [15], Wang et al [16][17][18] revealed that suppressed dynamics of ultrathin adsorbed layers could extend tens of nanometers away from the substrate, which could be related to the thickness or architecture of the adsorbed layer.…”

Section: Main Textmentioning

confidence: 99%

Effect of Local Chain Conformation in Adsorbed Nanolayers on Confined Polymer Molecular Mobility

et al. 2019

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Interfaces play an important role in modifying the dynamics of polymers confined to the nanoscale. Here, we demonstrate that the distance over which an interface suppresses molecular mobility in poly(styrene) thin films can be systematically increased by tens of nanometers by controlling the chain conformation, i.e., height of loops in irreversibly adsorbed nanolayers. These effects arise from topological interaction between adsorbed and neighboring un-adsorbed chains, respectively, which increase their motional coupling to facilitate the propagation of suppressed dynamics originating at the interface, thus highlighting the ability to manipulate interfacial effects by local conformation of chains in adsorbed nanolayers.

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Section: Main Textmentioning

confidence: 99%

Effect of Local Chain Conformation in Adsorbed Nanolayers on Confined Polymer Molecular Mobility

et al. 2019

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“…1 The T g of ultrathin PS films could be adjusted by modifying the various aromatic groups anchored onto silicon substrate surfaces 3,5 and the loop size of the adsorbed polystyrene (PS) chains. 6,7 In other words, the local relaxation of the chains near the substrate appears to be suppressed by the various interactions between the substrate and polymer. Furthermore, the interfacial effect on the polymer properties is complex and the nature of the interfacial effect remains unclear.…”

Section: Introductionmentioning

confidence: 99%

The role of the molecular weight of the adsorbed layer on a substrate in the suppressed dynamics of supported thin polystyrene films

et al. 2022

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“…This suggests that entropic effects may also play a modifying role in understanding confinement effects. For example, changes in dynamics due to tethering and adsorption of chains to substrates have been reported, as well as variations for different chain architectures such as stars and cyclic chains that otherwise have identical chemical composition, suggesting that the presence of a boundary or interface alters the available entropic conformations and influences the local dynamics, altering the nature of the dynamical gradient. Recent studies have also reported unexpected MW dependences and chain stiffness effects to the glass transition temperature ( T g ) and surface dynamics that contradict the general understanding that had historically been formed.…”

Section: Introductionmentioning

confidence: 99%

Unexpected Molecular Weight Dependence to the Physical Aging of Thin Polystyrene Films Present at Ultra‐High Molecular Weights

Thees

Roth

2019

J Polym Sci B Polym Phys

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The physical aging behavior, time-dependent densification, of thin polystyrene (PS) films supported on silicon are investigated using ellipsometry for a large range of molecular weights (MWs) from M w = 97 to 10,100 kg mol −1 . We report an unexpected MW dependence to the physical aging rate of h < 80-nm thick films not present in bulk films, where samples made from ultra-high MWs ≥ 6500 kg mol −1 exhibit on average a 45% faster aging response at an aging temperature of 40 C compared with equivalent films made from (merely) high MWs ≤ 3500 kg mol −1 . This MW-dependent difference in physical aging response indicates that the breadth of the gradient in dynamics originating from the free surface in these thin films is diminished for films of ultra-high MW PS. In contrast, measures of the film-average glass transition temperature T g (h) and effective average film density (molecular packing) show no corresponding change for the same range of film thicknesses, suggesting physical aging may be more sensitive to differences in dynamical gradients. These results contribute to growing literature reports signaling that chain connectivity and entropy play a subtle, but important role in how glassy dynamics are propagated from interfaces.

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The architecture of the adsorbed layer at the substrate interface determines the glass transition of supported ultrathin polystyrene films

Cited by 50 publications

References 75 publications

Effect of Local Chain Conformation in Adsorbed Nanolayers on Confined Polymer Molecular Mobility

Effect of Local Chain Conformation in Adsorbed Nanolayers on Confined Polymer Molecular Mobility

The role of the molecular weight of the adsorbed layer on a substrate in the suppressed dynamics of supported thin polystyrene films

Unexpected Molecular Weight Dependence to the Physical Aging of Thin Polystyrene Films Present at Ultra‐High Molecular Weights

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