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The present invention provides apparatus and methods for growing fullerene nanotube forests, and forming nanotube films, threads and composite structures therefrom. In some embodiments, an interior-flow substrate includes a porous surface and one or more interior passages that provide reactant gas t

The present invention provides apparatus and methods for growing fullerene nanotube forests, and forming nanotube films, threads and composite structures therefrom. In some embodiments, an interior-flow substrate includes a porous surface and one or more interior passages that provide reactant gas to an interior portion of a densely packed nanotube forest as it is growing. In some embodiments, a continuous-growth furnace is provided that includes an access port for removing nanotube forests without cooling the furnace substantially. In other embodiments, a nanotube film can be pulled from the nanotube forest without removing the forest from the furnace. A nanotube film loom is described. An apparatus for building layers of nanotube films on a continuous web is described.

대표청구항 ▼

What is claimed is: 1. An apparatus comprising an interior-flow substrate having a first major face, a second major face opposite the first major face, one or more sides of the substrate, a first nanoporous surface layer on the substrate such that an exterior face of the first nanoporous layer is t

What is claimed is: 1. An apparatus comprising an interior-flow substrate having a first major face, a second major face opposite the first major face, one or more sides of the substrate, a first nanoporous surface layer on the substrate such that an exterior face of the first nanoporous layer is the first major face of the substrate, an interior flow system that includes a first plurality of elongated passageways in the substrate between the first major face and the second major face and that is operable to deliver gasses to the first nanoporous layer from the second major face or from the one or more sides of the substrate, and a nanotube-synthesis catalyst on the first nanoporous layer. 2. The apparatus of claim 1, wherein the first plurality of elongated passageways each have a length measured as a distance that extends substantially parallel to the first major face, and each have a first depth measured from one side of one of the first plurality of elongated passageways to an opposite side in a direction generally perpendicular to the first major face that is greater than their width measured from one side to an opposite side in a direction generally parallel to the first major face, and wherein their length is longer than their depth. 3. The apparatus of claim 2, wherein the substrate is a side-flow substrate wherein each one the first plurality of elongated passageways deliver gasses to the first nanoporous layer from the one or more sides of the substrate. 4. The apparatus of claim 1, further comprising: an enclosure; a furnace having a temperature control and heating unit operable to maintain an effective temperature for nanotube synthesis, wherein the enclosure includes the furnace and wherein at least a portion of the enclosure is outside the furnace; a substrate-holding mechanism that is configured to hold the interior flow substrate; a gas-flow system operable to deliver one or more reactant gasses to the interior flow system through the second major face or the one or more sides of the substrate and to exhaust spent gasses from a vicinity of the first major face; and an access port extending from inside the furnace to outside the furnace through which nanotube product can be removed from the substrate while the substrate is inside the enclosure without interrupting a substantially continuous operation of the furnace at substantially its effective temperature for nanotube synthesis. 5. The apparatus of claim 4, wherein the substrate is configured to have plurality of successive nanotube forests grown and harvested. 6. The apparatus of claim 4, wherein the furnace is entirely inside the enclosure. 7. The apparatus of claim 1, further comprising: a furnace having a reaction chamber, wherein the interior-flow substrate is held in the reaction chamber of the furnace; a temperature controller operatively coupled to the reaction chamber, and configured to maintain a temperature effective for forming carbon nanotubes; a gas-delivery system configured to deliver one or more carbon-bearing precursor gasses into the interior flow system and through the first nanoporous layer to the first major face to form carbon nanotubes thereon; and an access port configured to permit removal of the formed carbon nanotubes from the interior-flow substrate while the substrate is within the furnace. 8. The apparatus of claim 1, further comprising: means for delivering one or more nanotube-precursor gasses into the interior flow system so that the gasses pass through the first nanoporous layer to the first major face. 9. The apparatus of claim 8, the apparatus further comprising: a furnace having a reaction chamber; means for holding the interior-flow substrate in the reaction chamber of the furnace; means for heating the reaction chamber to a temperature effective for forming carbon nanotubes, wherein the means for delivering the one or more nanotube-precursor gasses includes means for delivering carbon-bearing precursor gas into the interior flow system and through the first nanoporous layer to the first major face to form carbon nanotubes thereon, wherein the substrate is a side-flow substrate, wherein the delivering of the nanotube-precursor gas is done from the one or more sides of the substrate, and wherein the forming of the first plurality of interior gas passages includes forming the first plurality of interior gas passages having a length along a direction that lies in a plane that is parallel to the first major face; means for controlling a temperature of the reaction chamber to maintain an effective temperature for nanotube synthesis; means for exhausting spent gasses from a vicinity of the first major face; and means for removing nanotube product without interrupting a substantially continuous operation of the furnace at substantially its effective temperature for nanotube synthesis. 10. The apparatus of claim 9, wherein the one or more nanotube-precursor gasses include a carbon-bearing precursor gas. 11. The apparatus of claim 1, wherein the interior flow substrate includes a first plurality of gas passages having a first depth, measured as a distance from the first major surface to a distal side of one of the first plurality of gas passages in a direction extending away from the first major face and having a length along a direction that that is generally parallel to the first major face, and a second plurality of gas passages that extend to a second depth, measured as a distance from the first major surface to a distal side of one of the second plurality of gas passages in a direction extending away from the first major face, more distal from the first major face than the first depth of the first plurality of gas passages, and wherein each of the second gas passages is in fluid communication with a plurality of the first plurality of gas passages, in order to form a flow-through substrate. 12. The apparatus of claim 1, wherein the first nanoporous surface layer and the interior flow system are configured to conduct nanotube-precursor gasses from the interior flow system through the first nanoporous surface layer to the first major face in order react there to form nanotubes using the catalyst. 13. The apparatus of claim 1, wherein the first plurality of elongated passageways are each generally parallel to the first major face of the substrate. 14. The apparatus of claim 1, wherein the first plurality of elongated passageways extend from the second major face opposite the first major face in a branching manner to deliver the gasses to an interior portion of the first nanoporous layer such that the gasses flow through the first nanoporous layer to the first major face from the interior portion. 15. The apparatus of claim 1, wherein the first plurality of elongated passageways in the substrate are exit passageways that each connect to the first nanoporous layer, the apparatus further comprising at least one elongated supply passageway that connects to each one of the first plurality of elongated exit passageways each of which conducts the gasses to the first nanoporous layer from the at least one elongated supply passageway. 16. The apparatus of claim 15, wherein the at least one elongated supply passageway has a length that extends in a direction substantially perpendicular to lengths of each one of the first plurality of elongated exit passageways. 17. The apparatus of claim 15, wherein the first plurality of exit passageways are substantially parallel to the first nanoporous layer. 18. The apparatus of claim 15, wherein the first nanoporous layer is substantially planar and the first plurality of exit passageways include at least three passageways that are substantially in one plane that is parallel to the first nanoporous layer. 19. An apparatus comprising: a substrate having a first major face, wherein the substrate includes a first porous surface layer on the substrate such that an exterior face of the first porous surface layer is the first major face of the substrate, and a nanotube-synthesis catalyst on the first porous surface layer; and a plurality of elongated hollow means within the substrate for delivering one or more nanotube-precursor gasses through the first porous surface layer to the first major face. 20. The apparatus of claim 19, wherein the means within the substrate for delivering gasses includes a first plurality of gas passages having a first depth, measured as a distance from the first major surface to a distal side of one of the first plurality of gas passages in a direction generally perpendicular to the first major face, that is greater than their width measured as a distance from one side to an opposite side of one of the first plurality of gas passages in a direction generally parallel to the first major face. 21. The apparatus of claim 19, wherein means within the substrate for delivering gasses provide fluid communication to the first porous layer from at least a side of the substrate that is adjacent the first major face. 22. The apparatus of claim 19, wherein the means within the substrate for delivering gasses includes means for delivering gas from a major face opposite the first major face, in order to form a flow-through substrate. 23. The apparatus of claim 19, further comprising: an enclosure; a furnace having a temperature control and heating unit operable to maintain an effective temperature for nanotube synthesis, wherein the enclosure includes the furnace and wherein at least a portion of the enclosure is outside the furnace; means for holding the substrate; means for delivering one or more reactant gasses to the means for delivering gas and for exhausting spent gasses from a vicinity of the first major face; and means for removing nanotube product from the substrate while the substrate is inside the enclosure without interrupting a substantially continuous operation of the furnace at substantially its effective temperature for nanotube synthesis. 24. The apparatus of claim 23, wherein the furnace is entirely inside the enclosure. 25. The apparatus of claim 23, further comprising: means for growing and harvesting a plurality of successive nanotube forests from the substrate. 26. An apparatus comprising: an interior-flow substrate having a first major face, a second major face opposite the first major face, one or more sides of the substrate, a first nanoporous surface layer on the substrate such that an exterior face of the first nanoporous layer is the first major face of the substrate, an interior flow system that includes a plurality of elongated passageways in the substrate between the first major face and the second major face and that is operable to deliver gasses to the first nanoporous layer from the second major face or from the one or more sides of the substrate, and a nanotube-synthesis catalyst on the first nanoporous layer; and means for delivering one or more nanotube-precursor gasses into the interior flow system and through the first nanoporous layer to the first major face. 27. The apparatus of claim 26, further comprising: a furnace having a reaction chamber, wherein the interior-flow substrate is placed in the reaction chamber; means for heating the reaction chamber to a temperature effective for forming carbon nanotubes, wherein the means for delivering of the nanotube-precursor gasses includes means for delivering carbon-bearing precursor gas into the interior flow system and through the first nanoporous layer to the first major face to form carbon nanotubes thereon; and means for removing the formed carbon nanotubes from the interior-flow substrate. 28. The apparatus of claim 27, wherein the substrate is a side-flow substrate, and wherein the means for delivering of the carbon-bearing precursor gas includes means for delivering of the carbon-bearing precursor gas from the one or more sides of the substrate. 29. The apparatus of claim 27, wherein the means for delivering of nanotube-precursor gasses includes means for delivering one or more reactant gasses to the second major face or the one or more sides of the substrate, the apparatus further comprising: means for controlling a temperature of the reaction chamber to maintain an effective temperature for nanotube synthesis; a substrate-holding mechanism; means for exhausting spent gasses from a vicinity of the first major face; and means for removing nanotube product without interrupting a substantially continuous operation of the furnace at substantially its effective temperature for nanotube synthesis. 30. The apparatus of claim 27, wherein the substrate is a side-flow substrate, wherein the means for delivering of the carbon-bearing precursor gas delivers the carbon-bearing precursor gas from the one or more sides of the substrate, and wherein the interior-flow system comprises a first plurality of interior gas passages in the substrate having a length along a direction that lies in a plane that is generally parallel to the first major face, and having a first depth measured generally perpendicular to the first major face, the apparatus further comprising: means for holding the interior-flow substrate in the reaction chamber of the furnace; means for heating the reaction chamber to a temperature effective for forming carbon nanotubes, wherein the means for delivering the carbon-bearing precursor gas into the interior flow system includes means for delivering the carbon-bearing precursor gas from the one or more sides of the substrate or the second major face and through the first nanoporous layer to the first major face to form carbon nanotubes thereon; means for controlling a temperature of the reaction chamber to maintain an effective temperature for nanotube synthesis; means for exhausting spent gasses from a vicinity of the first major face; and means for removing nanotube product without interrupting a substantially continuous operation of the furnace at substantially its effective temperature for nanotube synthesis. 31. The apparatus of claim 30, wherein the interior-flow system further comprises a second plurality of gas passages that extend to a second depth more distal from the first major face than the first depth of the first plurality of gas passages, and wherein each of the second gas passages is configured to be in fluid communication with a plurality of the first plurality of gas passages, in order to form a flow-through substrate. 32. The apparatus of claim 26, wherein the interior-flow substrate includes, in the substrate, a first plurality of interior gas passages having a first depth, measured as a distance from the first major surface to a distal side of one of the first plurality of gas passages greater than their width measured from one side to an opposite side in a direction generally parallel to the first major face. 33. The apparatus of claim 26, wherein the interior-flow system comprises a first plurality of interior gas passages in the substrate having a length along a direction that is parallel to the first major face, and having a maximum first depth from the first major face measured in a direction generally perpendicular to the first major face, and a second plurality of gas passages that extend to a second depth from the first major face measured in the direction generally perpendicular to the first major face more distal from the first major face than the maximum first depth of the first plurality of gas passages, and wherein each of the second plurality of gas passages is configured to be in fluid communication with a plurality of the first plurality of gas passages, in order to form a flow-through substrate.