Polymer and inorganic-organic hybrid composites and methods...

Synthetic resins or natural rubbers -- part of the class 520 ser – Synthetic resins – At least one aryl ring which is part of a fused or bridged...

Reexamination Certificate

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C524S084000, C524S104000, C524S257000, C524S261000, C524S263000, C524S430000, C524S431000, C524S432000, C524S433000

Reexamination Certificate

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06548590

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates generally to composites and, more particularly, to polymer and inorganic-organic hybrid composites containing inorganic or organic materials disposed in the polymer matrix's free volume
BACKGROUND OF THE INVENTION
Hybrid Materials
Inorganic-organic hybrid materials have been used with varying degrees of success for a variety of applications.
In some of these materials, organic polymers are blended with inorganic fillers to improve certain properties of those polymers or to reduce the cost of the polymeric compositions by substituting cheaper inorganic materials for more expensive organic materials. Typically, inorganic fillers are either particulate or fibrous and are derived from inexpensive materials, such as naturally occurring minerals and glass. For example, U.S. Pat. No. 5,536,583 to Roberts et al. (“Roberts”) describes methods for mixing inorganic ceramic powders into polyethersulfone, polyether ketones, and polyether other ketones and methods for including metal nitrides, oxides, and carbides into fluoropolymer resins to produce corrosion inhibiting coatings as well as coatings which have improved abrasion resistance and/or enhanced bonding characteristics. U.S. Pat. No. 5,492,769 to Pryor et al. (“Pryor”) describes methods for embedding metal or ceramic materials into organic polymeric materials to increase the polymer's abrasion resistance. U.S. Pat. No. 5,478,878 to Nagaoka et al. (“Nagaoka”) describes a thermoplastic blend of an organic polymer and inorganic metallic fillers which improves the polymer's resistance to discoloration upon exposure to ambient light sources.
Each of the above inorganic-organic hybrid materials were made either (1) by melting and then mixing the inorganic and organic phases into a homogeneous mixture which was then cured, extracted, or dried or (2) by dissolving the polymer and inorganic material together in a solvent in which both materials were miscible, mixing to produce a homogeneous solution, and then evaporating the solvent to extract the hybrid material. The resulting inorganic-organic hybrid materials are essentially homogeneous macromolecular blends which have separate inorganic and organic domains which range from nanometers to tens of micrometers in size. All of the above composites are fabricated by using inorganic materials, typically naturally occurring minerals, which are in thermodynamically stable metallic forms, such as metal oxides, metal nitrides, and zero-valent metals.
These inorganic-organic hybrid materials suffer from a number of drawbacks which limit their utility. For example, the size of the domain that the inorganic materials assume within the hybrid depends on the particle size of the inorganic material particulate or fiber used in making the hybrid. In addition, the homogeneity of the inorganic-organic hybrid material largely depends on either the solubility of the inorganic material in the polymeric melt or on the solubility of the inorganic material in the solvent used to solubilize the polymeric material. Furthermore, the properties and molecular structures of these hybrids depend greatly on the methods used to extrude, cast, or dry the solid hybrid material from the melt or solubilized mixtures, which gives rise to significant, undesirable, and frequently uncontrollable batch-to-batch and regional variations.
Inorganic-organic hybrid materials have also been prepared by dispersing powdered or particulate forms of inorganic materials within various polymeric matrices.
For example, U.S. Pat. No. 5,500,759 to Coleman (“Coleman”) discloses electrochromic materials made by dispersing electrically conductive metal particles into polymeric matrices; U.S. Pat. No. 5,468,498 to Morrison et al. (“Morrison”) describes aqueous-based mixtures of colloidal vanadium oxide and dispersed sulfonated polymer which are useful for producing antistatic polymeric coatings; U.S. Pat. No. 5,334,292 to Rajeshwar et al. (“Rajeshwar”) discloses conducting polymer films containing nanodispersed inorganic catalyst particles; and U.S. Pat. No. 5,548,125 to Sandbank (“Sandbank”) discloses methods for melt- or thermo-forming flexible polymeric gloves containing particulate tungsten which makes the gloves useful for shielding x-radiation.
Although the inorganic-organic hybrid materials are homogeneously mixed, they contain separate inorganic and organic phases on a macromolecular scale. These separate phases frequently gives rise to the inorganic material's migration within and/or leaching out of the polymeric matrix. Furthermore, the inorganic phases of these inorganic-organic hybrid materials can be separated from the polymer matrix by simple mechanical processes or by solvent extraction of the polymer. Consequently, upon exposure to certain temperatures or solvents, the inorganic phases of these hybrids can migrate and dissipate out of or accumulate in various regions within the polymeric matrix, reducing its useful life.
Because of the problems associated with migration and leaching of the inorganic phase in inorganic-organic hybrids, hybrid materials containing inorganic phases having greater stability have been developed. These materials rely on physically entrapping large interpenetrating macromolecular networks of inorganic materials in the polymeric chains of the organic material.
For example, U.S. Pat. No. 5,412,016 to Sharp (“Sharp”) describes polymeric inorganic-organic interpenetrating network compositions made by mixing a hydrolyzable precursor of an inorganic gel of Si, Ti, or Zr with an organic polymer and an organic carboxylic acid to form a homogeneous solution. The solution is then hydrolyzed, and the resulting hybrid materials are used to impart added toughness to conventional organic polymers as well as to increase their thermal stabilities and abrasion resistances. U.S. Pat. No. 5,380,584 to Anderson et al. (“Anderson I”) describes an electrostatography imaging element which contains an electrically-conductive layer made of a colloidal gel of vanadium pentoxide dispersed in a polymeric binder. U.S. Pat. No. 5,190,698 to Coltrain et al. (“Coltrain I”) describes methods for making polymer/inorganic oxide composites by combining a polymer derived from a vinyl carboxylic acid with a metal oxide in a solvent solution, casting or coating the resulting solution, and curing the resulting sample to form a composite of the polymer and the metal oxide. These composites are said to be useful for forming clear coatings or films having high optical density, abrasion resistance, or antistatic properties. U.S. Pat. No. 5,115,023 to Basil et al. (“Basil”) describes siloxane-organic hybrid polymers which are made by hydrolytic condensation polymerization of organoalkyoxysilanes in the presence of organic film-forming polymers. The method is similar to that described in Sharp and, similarly, is used to improve a polymer's mechanical strength and stability while maintaining its flexibility and film forming properties. U.S. Pat. No. 5,010,128 to Coltrain et al. (“Coltrain II”) describes methods for blending metal oxides with etheric polyphosphazenes to increase abrasion resistance and antistatic properties of polyphosphazene films. These methods, like those of Coltrain I, employ inorganic metal precursors which contain hydrolyzable leaving groups.
In each of the foregoing, the polymeric inorganic-organic interpenetrating network compositions are obtained by, sequentially, (1) adding hydrolyzable metals (or hydrolyzed metal gels) into either a polymer melt or a solvent containing a dissolved polymer; (2) adding a hydrolyzing agent or adjusting the pH of the solution to effect hydrolysis; (3) mixing; and (4) curing.
The methods described, however, suffer from several limitations. For example, they are limited to incorporating interpenetrating metal oxide networks into polymers which have similar solubilities as the hydrolyzable metal precursors or the hydrolyzed metal. In addition, because the method involves first mixing the inorganic hydrolyzable metal precu

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