Suppression of Dewetting in Nanoparticle-Filled Polymer Films

Barnes, K A.; Karim, Alamgir; Douglas, Jack F.; Nakatani, Alan I.; Gruell, Holger; Amis, Eric J.

doi:10.1021/ma990614s

Cited by 179 publications

(242 citation statements)

References 26 publications

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“…While there has been no result reported on the formation of ultrathin liquid films that are stable, there have been several studies reported for the stability of thin polymer films, involving the use of grafting [20][21][22] and nanoparticles. 23 However, the film thickness is on the order of 100 nm, whereas the thickness of the stable film in this study is on the order of 1 nm.…”

Section: ͑4͒mentioning

confidence: 54%

Ultrathin liquid films under alternating intermolecular potential fields and capillary force

Suh

Lee

2002

The Journal of Chemical Physics

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A unique experimental system is devised that reveals the interplay among capillary force and alternating intermolecular forces. As a consequence of the interplay, untrathin ͑Ͻ10 nm͒ liquid films, which invariably experience dewetting, can be made stable, leading to a smooth and dropless minimum-potential surface. Theory and experiment show that the film thickness is Ͻ1 nm when the film recedes in spite of the capillarity and it is Ͻ3 nm when it rises into a cavity.

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Section: ͑4͒mentioning

confidence: 54%

Ultrathin liquid films under alternating intermolecular potential fields and capillary force

Suh

Lee

2002

The Journal of Chemical Physics

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“…Here, we show that the addition of fullerenes [15] (C 60 ) to both PECH and BSP3 inhibits dewetting of thin polymer films. In Figure 3 In Figure 3-3, fullerenes were added to the same solution of PECH as above and then spin-coated.…”

Section: Resultsmentioning

confidence: 76%

“…As a sample calculation, consider a chain with N = 20 sites of diameter σ = 6.65 Å (using N = M/m o , this corresponds to PS with molecular weight 2040, a fairly short chain but about the same length as those used by Barnes et al [20]), and nanoparticles with diameter 1.5 σ ≈ 10 Å, i.e. 1 nm.…”

Section: Equation 3-1mentioning

confidence: 99%

Resolving fundamental limits of adhesive bonding in microfabrication.

Hall¹,

Frischknecht²,

Emerson³

et al. 2004

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As electronic and optical components reach the micro-and nanoscales, efficient assembly and packaging require the use of adhesive bonds. This work focuses on resolving several fundamental issues in the transition from macro-to micro-to nanobonding. A primary issue is that, as bondline thicknesses decrease, knowledge of the stability and dewetting dynamics of thin adhesive films is important to obtain robust, void-free adhesive bonds. While researchers have studied dewetting dynamics of thin films of model, non-polar polymers, little experimental work has been done regarding dewetting dynamics of thin adhesive films, which exhibit much more complex behaviors. In this work, the areas of dispensing small volumes of viscous materials, capillary fluid flow, surface energetics, and wetting have all been investigated. By resolving these adhesive-bonding issues, we are allowing significantly smaller devices to be designed and fabricated. Simultaneously, we are increasing the manufacturability and reliability of these devices.4

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“…The syntheses of nanometersized components have extended beyond carbon [2,10,[16][17][18][19][20]. A drawback to the utilization of carbon nanotubes, based on conductivity, is the inability to control the chirality.…”

Section: Resultsmentioning

confidence: 99%

“…Poly(2-methoxy-5-ethylhexyloxy-1,4-phenylene vinylene) (MEH-PPV)/rutile-TiO 2 composite films were made by Kim [19] with various sizes from 7 to 23 nm and their electroluminescent characteristics were investigated. Barnes [20] investigated the perturbing influence of nanosize filler particles on the dewetting of spun-cast polymer films. Rotkin [21] developed a new heuristic model for the calculation of the formation energy of the carbon nanoclusters.…”

Section: Resultsmentioning

confidence: 99%

Nanostructures in Physical Materials Chemistry: An Exploratory Laboratory

et al. 2001

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Abstract:The blend of nanotechnology and material science is often beyond the scope of undergraduate laboratories. Through undergraduate research, graphite-intercalated compounds have been incorporated in the production of carbon-based nanostructures. Based on this work a series of exploratory exercises were designed for the undergraduate physical chemistry laboratory emphasizing nanostructure material science. This rapidly expanding area of science and technology can be introduced at an undergraduate level using a high temperature oven to produce nanostructure samples that are analyzed by Raman spectroscopy, scanning electron microscopy, and transmission electron microscopy at research university laboratories, infrared spectroscopy, and a bomb calorimeter. In these experiments we use samples of pure graphite, fluorinated graphite, and lanthanum oxide to induce the formation of nanostructures. An overview of fullerenes, nanotubes, boron nitride and Si nanostructures, other carbon forms, graphite-intercalated compounds, and the storage of hydrogen in nanotubes are provided in an appendix. Several extensions of the laboratory are proposed.

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Suppression of Dewetting in Nanoparticle-Filled Polymer Films

Cited by 179 publications

References 26 publications

Ultrathin liquid films under alternating intermolecular potential fields and capillary force

Ultrathin liquid films under alternating intermolecular potential fields and capillary force

Resolving fundamental limits of adhesive bonding in microfabrication.

Nanostructures in Physical Materials Chemistry: An Exploratory Laboratory

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