Title :
Nanopore foams of high temperature polymers
Author :
Labadie, Jeff W. ; Hedrick, James L. ; Wakharkar, V. ; Hofer, Donald C. ; Russell, Thomas P.
Author_Institution :
IBM Almaden Res. Center, San Jose, CA, USA
fDate :
12/1/1992 12:00:00 AM
Abstract :
A method of generating high-temperature polymer foams with pore sizes in the nanometer regime was developed. The nanofoams were prepared by casting a block copolymer comprising a thermally stable and a thermally labile block, followed by a subsequent thermal treatment to degrade the labile material and generate the pores. The morphology of the block copolymer film was made up of a high-temperature polymer matrix, with the labile component as the dispersed phase. Thermolysis of the labile block affords pores where the size and shape of the pores are dictated by the initial copolymer morphology. Nanopore foam formation is described for triblock copolymers of poly(phenylquinoxaline) (PPQ) with poly(propylene oxide) (PO) as the labile block. Foam formation led to a 10-15% reduction in density, consistent with the PO composition, and a dielectric constant as low as 2.3. SAXS and TEM measurements indicated pore sizes of approximately 10 nm
Keywords :
X-ray diffraction examination of materials; composite insulating materials; foams; nanostructured materials; organic insulating materials; permittivity; polymer blends; polymer films; porous materials; transmission electron microscope examination of materials; 10 nm; PPQ foams; SAXS; TEM measurements; block copolymer; block copolymer film; dielectric constant; high-temperature polymer foams; high-temperature polymer matrix; interlayer dielectric; morphology; nanofoams; nanopore foam formation; nanopore foams; permittivity; polyphenylquinoxaline; polypropylene oxide; pore sizes; preparation; reduction in density; thermal treatment; thermally labile block; thermally stable block; thermolysis; triblock copolymers; Casting; Dielectric constant; Morphology; Nanoporous materials; Polymer films; Polymer foams; Shape; Temperature; Thermal degradation; Thermolysis;
Journal_Title :
Components, Hybrids, and Manufacturing Technology, IEEE Transactions on
