Experimental study and modeling of nanofoams formation from single phase acrylic copolymers

Costeux, Stéphane; Khan, Irfan; Bunker, Shana P.; Jeon, Hong G.

doi:10.1177/0021955x14531972

Cited by 47 publications

(56 citation statements)

References 31 publications

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“…The MMA‐ co ‐EMA copolymers ( T g = 96°C) were found to be more effective than PEMA ( T g = 65°C), which under similar conditions produced foams with 345 nm cells and 79% porosity . The studies concluded that homogeneous nucleation theory was consistent with the experimental trends observed, which was captured in a foaming model …”

Section: Polymer Systems For Nanofoamssupporting

confidence: 53%

“…Under the sorption conditions (30 MPa and 35°C), all polymers were in the amorphous state and readily foamed upon depressurization (1S process). Copolymers with T g between 85°C and 105°C produced nanofoams with cell size between 100 and 200 nm with porosities between 60 and 80% . Some higher T g polymers with high CO 2 solubility, such as MMA‐ co ‐PFMA, gave foams with 70 nm cell and 60% porosity and remarkably high cell nucleation densities.…”

Section: Polymer Systems For Nanofoamsmentioning

confidence: 99%

“…This is the first published validation of the Knudsen effect in nanocellular foams, which confirms the expected reduction of heat transfer due to the gaseous phase by a factor 2 to 3 compared to conventional foams. The highest porosity demonstrated for nanofoams with cells of about 100 nm or less is about 85%, which is expected to be suitable to minimize the balance between solid conduction and radiation. No overall TC data have been published to date on such foams but it seems reasonable to assume that low TC foams can indeed be made from low density nanocellular foams.…”

Section: Properties Of Nanocellular Foams and Potential Applicationsmentioning

confidence: 99%

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CO₂‐blown nanocellular foams

Costeux

2014

J of Applied Polymer Sci

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162

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Polymeric nanocellular foams are broadly defined as having cell size below one micron. However, it is only when cell size reaches 100 nm or less that unique thermal conductivity, dielectric constant, optical, or mechanical properties are expected due to gas confinement in the cells or polymer confinement in the cell walls. Producing such materials with low density by physical foaming with CO 2 requires the controlled nucleation and growth of 10 15 210 16 cells/cm 3 . This is a formidable challenge that necessitates new foaming strategies. This review provides a description of processes, conditions, and polymer systems that have been employed over the past 15 years to achieve increasingly higher cell densities and expansion ratio, culminating with the recent development of low density nanofoams and of nanostructured polymers in which nucleation can be precisely controlled. Remaining barriers to scale-up are summarized.

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Section: Polymer Systems For Nanofoamssupporting

confidence: 53%

Section: Polymer Systems For Nanofoamsmentioning

confidence: 99%

Section: Properties Of Nanocellular Foams and Potential Applicationsmentioning

confidence: 99%

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CO₂‐blown nanocellular foams

Costeux

2014

J of Applied Polymer Sci

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162

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“…The concept for these polymer blends nanofoams was similar: one phase acted as the matrix and the other dispersed phase served as a template for bubble nucleation and growth. For copolymers, nanofoams have been created mainly in PMMA‐based copolymers, such as poly(MMA‐co‐EMA) and poly(MMA‐co‐tBMA) . Polymer nanocomposites, which have some amount of nanoparticles dispersed in the polymer matrix, have been shown to generate nanofoams, such as in poly(MMA‐co‐EA) with silica nanoparticles and poly(MMA‐co‐EMA) with POSS .…”

Section: Introductionmentioning

confidence: 99%

Solid‐state microcellular and nanocellular polysulfone foams

Guo

Nicolae

Kumar

2015

J Polym Sci B Polym Phys

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In this article, we report on the process for creating microcellular and nanocellular polysulfone (PSU) foams. Microcellular foams with cell size up to 8 mm and nanocellular foams with cell size in the range of 20-30 nm were created. A range of CO 2 concentration was achieved by varying saturation temperature, from 5% at 60 C to 14.7% at 210 C. The CO 2 concentration has a strong influence on the cellular structure.There exists a critical concentration window, between 10.7% and 12.3%, within which cell nucleation densities increase rapidly and cell sizes drop from micrometer range to below 1 mm into the nanometer range. Nanofoams with cell nucleation densities exceeding 10 15 cells/cm 3 and void fraction of up to 48% are achieved. At the high CO 2 concentration region, the change from closed nanocellular structure to bicontinuous nanoporous structure is observed. Also, nanostructures on the cell wall of microcells are observed and believed to be formed via stressinduced nucleation/spinodal decomposition. The PSU nanofoams produced in this study present an opportunity to produce polymer nanofoams with a relatively high service temperature. The ability to create cells of different length scales provides an opportunity to study the effect of cell size on the foams properties.

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“…12 Scanning electron microscope QUANTA 200 FEG of Thermo Fisher Scientific (USA). 13 At least 200 cells were analysed from multiple micrographs per foamed sample. 14 −− = (2) where g V is the geometric volume of the foam, p V is the pycnometer volume and s V is a penalty volume to account for the volume of the cells at the surface of the foam.…”

Section: Open Cell Contentmentioning

confidence: 99%

The mechanics of solid-state nanofoaming

et al. 2019

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Solid-state nanofoaming experiments are conducted on two PMMA grades of markedly different molecular weight using CO2 as the blowing agent. The dependence of porosity of the nanofoams upon foaming time and foaming temperature is measured. Also, the microstructure of the PMMA nanofoams is characterized in terms of cell size and cell nucleation density. A one dimensional numerical model is developed to predict the growth of spherical, gas-filled voids during the solid-state foaming process. Diffusion of CO2 within the PMMA matrix is sufficiently rapid for the concentration of CO2 to remain almost uniform spatially. The foaming model makes use of experimentally calibrated constitutive laws for the PMMA grades, and the effect of dissolved CO2 is accounted for by a shift in the glass transition temperature of the PMMA. The observed limit of achievable porosity is interpreted in terms of cell wall tearing;it is deduced that the failure criterion is sensitive to cell wall thickness.

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Experimental study and modeling of nanofoams formation from single phase acrylic copolymers

Cited by 47 publications

References 31 publications

CO₂‐blown nanocellular foams

CO₂‐blown nanocellular foams

Solid‐state microcellular and nanocellular polysulfone foams

The mechanics of solid-state nanofoaming

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Experimental study and modeling of nanofoams formation from single phase acrylic copolymers

Cited by 47 publications

References 31 publications

CO2‐blown nanocellular foams

CO2‐blown nanocellular foams

Solid‐state microcellular and nanocellular polysulfone foams

The mechanics of solid-state nanofoaming

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Product

Resources

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CO₂‐blown nanocellular foams

CO₂‐blown nanocellular foams