2019
DOI: 10.1021/acs.chemmater.9b02856
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Optimizing Polymer Brush Coverage To Develop Highly Coherent Sub-5 nm Oxide Films by Ion Inclusion

Abstract: Area-selective deposition is a promising technique for positional self-alignment of materials at a prepatterned surface. Critical to this is the development of molecular systems that have selective surface binding and can act as templates to material growth. This paper reports how end functionalized polymers can be used to create oxide films through a grafting method. Here, we detail a facile approach for rapid grafting (in seconds) of polymer brush films with complete coverage over large areas with high unifo… Show more

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Cited by 20 publications
(53 citation statements)
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“…Presently BCPs and polymer brushes are selected based on their ability to produce high quality patterned substrates for specific applications such as in the semiconductor industry. To enable the transition of BCPs and polymer brushes from “lab to fab” research efforts have focused on finding suitable BCPs with controllable ordination of the phase separated domains and long-range alignment and polymer brushes with high uniformity (pinhole free) complete coverage over large areas and tuneable thickness [ 18 , 69 ]. However, it is worth considering the importance of green polymer chemistry and the potential of this new technology to be environmentally friendly if toxic moieties are substituted for biocompatible materials.…”
Section: Bottom-up Versus Top-down Lithographymentioning
confidence: 99%
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“…Presently BCPs and polymer brushes are selected based on their ability to produce high quality patterned substrates for specific applications such as in the semiconductor industry. To enable the transition of BCPs and polymer brushes from “lab to fab” research efforts have focused on finding suitable BCPs with controllable ordination of the phase separated domains and long-range alignment and polymer brushes with high uniformity (pinhole free) complete coverage over large areas and tuneable thickness [ 18 , 69 ]. However, it is worth considering the importance of green polymer chemistry and the potential of this new technology to be environmentally friendly if toxic moieties are substituted for biocompatible materials.…”
Section: Bottom-up Versus Top-down Lithographymentioning
confidence: 99%
“…It is the chemical incompatibility of the BCP blocks that enables self-assembly into a variety of morphologies [ 13 , 14 , 15 ]. The molecular mechanisms of ASD and DSA technologies must be better understood before these techniques can be integrated into semiconductor manufacturing processes [ 11 , 16 , 17 , 18 ].…”
Section: Introductionmentioning
confidence: 99%
“…Samples were prepared as outlined in the work published by R. Lundy and P. Yadav et al and summarized here. 21 Native oxide silicon substrates were placed in a tetrahydrofuran (THF) bath and ultrasonicated for 20 minutes before being oxygen plasma treated for -OH group termination. The polymer powders were dissolved into a solution (THF for P2VP and P4VP, toluene for PS) of 0.2 wt.%.…”
Section: Experimental Details Materials Preparationmentioning
confidence: 99%
“…The substrate temperature was additionally kept below the polymer degradation temperature (P2VP ≈ 320 °C, P4VP ≈ 290 °C PS ≈ 260 °C). 21 All depositions (with the exception of P4VP in part of experiment 4) took place above the bulk glass transition temperature (T g ) of the polymers (P2VP ≈ 100 °C, P4VP ≈ 150 °C, PS ≈ 100 °C). 51,52 The chamber was kept pumped in such a way that the pressure was maintained at 26.7 Pa (200 mTorr) for this stage.…”
Section: In-situ Vpi Plasma Processing and Xpsmentioning
confidence: 99%
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