Abstract: An approach is presented for designing a polymeric layer for nanometer scale thermo-mechanical storage devices. Cross-linked polyimide oligomers are used as the recording layers in atomic force data storage device, giving significantly improved performance when compared to previously reported cross-linked and linear polymers. The cross-linking of the polyimide oligomers may be tuned to match thermal and force parameters required in read-write-erase cycles. Additionally, the cross-linked polyimide oligomers are suitable for use in nano-scale imaging.

Abstract: Oxycarbosilane materials make excellent matrix materials for the formation of porous low-k materials using incorporated pore generators(porogens). The elastic modulus numbers measured for porous samples prepared in this fashion are 3–6 times higher than porous organosilicates prepared using the sacrificial porogen route. The oxycarbosilane materials are used to produce integrated circuits for use in electronics devices.

Abstract: A composition of matter and a structure fabricated using the composition. The composition comprising: a resin; polymeric nano-particles dispersed in the resin, each of the polymeric nano-particle comprising a multi-arm core polymer and pendent polymers attached to the multi-arm core polymer, the multi-arm core polymer immiscible with the resin and the pendent polymers miscible with the resin; and a solvent, the solvent volatile at a first temperature, the resin cross-linkable at a second temperature, the polymeric nano-particle decomposable at a third temperature, the third temperature higher than the second temperature, the second temperature higher than the first temperature, wherein a thickness of a layer of the composition shrinks by less than about 3.5% between heating the layer from the second temperature to the third temperature.

Abstract: A nanoparticle which includes a multi-armed core and surface decoration which is attached to the core is prepared. A multi-armed core is provided by any of a number of possible routes, exemplary preferred routes being living anionic polymerization that is initiated by a reactive, functionalized anionic initiator and ?-caprolactone polymerization of a bis-MPA dendrimer. The multi-armed core is preferably functionalized on some or all arms. A coupling reaction is then employed to bond surface decoration to one or more arms of the multi-armed core. The surface decoration is a small molecule or oligomer with a degree of polymerization less than 50, a preferred decoration being a PEG oligomer with degree of polymerization between 2 and 24. The nanoparticles (particle size ?10 nm) are employed as sacrificial templating porogens to form porous dielectrics. The porogens are mixed with matrix precursors (e.g., methyl silsesquioxane resin), the matrix vitrifies, and the porogens are removed via burnout.

Abstract: Substantially or roughly spherical micellar structures useful in the formation of nanoporous materials by templating are disclosed. A roughly spherical micellar structure is formed by organization of one or more spatially unsymmetric organic amphiphilic molecules. Each of those molecules comprises a branched moiety and a second moiety. The branched moiety can form part of either the core or the surface of the spherical micellar structure, depending on the polarity of the environment. The roughly spherical micellar structures form in a thermosetting polymer matrix. They are employed in a templating process whereby the amphiphilic molecules are dispersed in the polymer matrix, the matrix is cured, and the porogens are then removed, leaving nanoscale pores.

Abstract: A nanoporous material exhibiting a lamellar structure is disclosed. The material comprises three or more substantially parallel sheets of an organosilicate material, separated by highly porous spacer regions. The distance between the centers of the sheets lies between 1 nm and 50 nm. The highly porous spacer regions may be substantially free of condensed material. For the manufacture of such materials, a process is disclosed in which matrix non-amphiphilic polymeric material and templating polymeric material are dispersed in a solvent, where the templating polymeric material includes a polymeric amphiphilic material. The solvent with the polymeric materials is distributed onto a substrate. Organization is induced in the templating polymeric material. The solvent is removed, leaving the polymeric materials in place. The matrix polymeric material is cured, forming a lamellar structure.

Abstract: Dielectric compositions comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The compositions are useful in the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric compositions are prepared by admixing a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer in a suitable solvent, heating the admixture to cure the polymer and provide a vitrified matrix, and then decomposing the porogen using heat, radiation, or a chemical reagent effective to degrade the porogen. The highly porous dielectric materials so prepared have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0. Integrated circuit devices and integrated circuit packaging devices manufactured so as to contain the dielectric material of the invention are provided as well.

Abstract: Oxycarbosilane materials make excellent matrix materials for the formation of porous low-k materials using incorporated pore generators (porogens). The elastic modulus numbers measured for porous samples prepared in this fashion are 3-6 times higher than porous organosilicates prepared using the sacrificial porogen route. The oxycarbosilane materials are used to produce integrated circuits for use in electronics devices. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader quickly to ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the appended issued claims.

Abstract: A slider assembly is provided comprising a plurality of sliders bonded by a debondable solid encapsulant comprised of different first and second polymers The solid encapsulant is comprised of a polymer prepared by polymerizing an encapsulant fluid comprising a homogeneous mixture of first and second constituents. The first constituent is comprised of a first monomer suitable for in situ polymerization to form the first polymer. The second constituent is comprised of the second polymer or a second monomer suitable for in situ polymerization to form the second polymer. The first constituent does not substantially react with the second constituent. Each slider has a surface that is free from the encapsulant. The encapsulant-free surfaces are coplanar to each other. Also provided are methods for forming the assembly and methods for patterning a slider surface using the encapsulant.

Abstract: An encapsulant fluid is provided comprising a mixture of a diene-containing compound and a dienophilic compound. At least one of the diene-containing and the dienophilic compounds is protected so that the compounds do not substantially react with each other at room temperature. The diene-containing and the dienophilic compounds undergo a reversible Diels-Alder polymerization reaction at a polymerization temperature above room temperature to form a solid debondable polymeric encapsulant. Also provided are methods for forming slider assemblies and methods for patterning a slider surface using the encapsulant.

Abstract: A slider assembly is provided comprising a plurality of sliders bonded by a debondable solid encapsulant. The solid encapsulant is comprised of a polymer prepared by polymerizing a mixture of first and second monomers in a nonstoichiometric ratio effective to render the encapsulant debondable. Each slider has a surface that is free from the encapsulant. The encapsulant-free surfaces are coplanar to each other. Also provided are methods for forming the assembly and methods for patterning a slider surface using the encapsulant.

Abstract: Defect-free dielectric coatings comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The dielectric coatings are useful in a number of contexts, including the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric coatings are prepared by admixing, in a solvent, a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer miscible therewith, coating a substrate surface with the admixture, heating the uncured coating to cure the host polymer and provide a vitrified, two-phase matrix, and then decomposing the porogen. The dielectric coatings so prepared have few if any defects, and depending on the amount and molecular weight of porogen used, can be prepared so as to have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0.

Abstract: Defect-free dielectric coatings comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The dielectric coatings are useful in a number of contexts, including the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric coatings are prepared by admixing, in a solvent, a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer miscible therewith, coating a substrate surface with the admixture, heating the uncured coating to cure the host polymer and provide a vitrified, two-phase matrix, and then decomposing the porogen. The dielectric coatings so prepared have few if any defects, and depending on the amount and molecular weight of porogen used, can be prepared so as to have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0.

Abstract: Dielectric compositions comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The compositions are useful in the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric compositions are prepared by admixing a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer in a suitable solvent, heating the admixture to cure the polymer and provide a vitrified matrix, and then decomposing the porogen using heat, radiation, or a chemical reagent effective to degrade the porogen. The highly porous dielectric materials so prepared have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0. Integrated circuit devices and integrated circuit packaging devices manufactured so as to contain the dielectric material of the invention are provided as well.

Abstract: Defect-free dielectric coatings comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The dielectric coatings are useful in a number of contexts, including the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric coatings are prepared by admixing, in a solvent, a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer miscible therewith, coating a substrate surface with the admixture, heating the uncured coating to cure the host polymer and provide a vitrified, two-phase matrix, and then decomposing the porogen. The dielectric coatings so prepared have few if any defects, and depending on the amount and molecular weight of porogen used, can be prepared so as to have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0.

Abstract: Dielectric compositions comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The compositions are useful in the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric compositions are prepared by admixing a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer in a suitable solvent, heating the admixture to cure the polymer and provide a vitrified matrix, and then decomposing the porogen using heat, radiation, or a chemical reagent effective to degrade the porogen. The highly porous dielectric materials so prepared have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0. Integrated circuit devices and integrated circuit packaging devices manufactured so as to contain the dielectric material of the invention are provided as well.

Abstract: Defect-free dielectric coatings comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The dielectric coatings are useful in a number of contexts, including the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric coatings are prepared by admixing, in a solvent, a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer miscible therewith, coating a substrate surface with the admixture, heating the uncured coating to cure the host polymer and provide a vitrified, two-phase matrix, and then decomposing the porogen. The dielectric coatings so prepared have few if any defects, and depending on the amount and molecular weight of porogen used, can be prepared so as to have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0.

Abstract: Dielectric compositions comprised of porous polymeric matrices are prepared using nitrogen-containing polymers as pore-generating agents. The compositions are useful in the manufacture of electronic devices such as integrated circuit devices and integrated circuit packaging devices. The dielectric compositions are prepared by admixing a polymeric nitrogenous porogen with a high temperature, thermosetting host polymer in a suitable solvent, heating the admixture to cure the polymer and provide a vitrified matrix, and then decomposing the porogen using heat, radiation, or a chemical reagent effective to degrade the porogen. The highly porous dielectric materials so prepared have an exceptionally low dielectric constant on the order of 2.5 or less, preferably less than about 2.0. Integrated circuit devices and integrated circuit packaging devices manufactured so as to contain the dielectric material of the invention are provided as well.