System for bulk separation of single-walled tubular fullerenes using a channeled substrate

What is being claimed is: 1. A system for bulk separation of single-walled tubular fullerenes based on chiral angle, comprising: a container assembly for holding and dispensing a fluid bearing single-walled tubular fullerenes of a multiplicity of different chiral angles; a separation plate defined by a crystalline substrate having a lattice structure being exposed within a plurality of longitudinally directed channels formed on a surface of said crystalline substrate, each of said channels being formed to have a width selected to limit an angular tolerance of single-walled tubular fullerenes to be not greater than six degrees, said longitudinal direction being selected to be at an energetically favored angular orientation of an axis of said lattice structure of said crystalline substrate with respect to an axis of a lattice structure for single-walled tubular fullerenes of one chiral angle to be adsorbed to said crystalline substrate; a transport assembly coupled in fluid communication with said container assembly and having at least one outlet for discharging said fluid bearing said single-walled tubular fullerenes to flow across said separation plate, wherein any of said single-walled tubular fullerenes of said one chiral angle passing into a respective one of said channels being preferentially adsorbed and thereby held to said exposed portions of said upper surface of said crystalline substrate therein; and a collection assembly disposed adjacent to and downstream of said separation plate for receiving said fluid and any of said single-walled tubular fullerenes not adsorbed on said crystalline substrate. 2. The system as recited in claim 1 , wherein said crystalline substrate has a plurality of linearly directed barrier members extending thereacross and disposed in laterally spaced relationship on an upper surface of said crystalline substrate to respectively form said channels between adjacent pairs of said barrier members. 3. The system as recited in claim 1 , wherein said container assembly includes a container having at least one displaceable wall for decreasing a volume of said container to establish said flow of said fluid bearing said single-walled tubular fullerenes. 4. The system as recited in claim 1 , wherein said container assembly includes a container adapted to be pressurized to establish said flow of said fluid bearing single-walled tubular fullerenes. 5. The system as recited in claim 1 , wherein said at least one outlet discharges said fluid bearing said single-walled tubular fullerenes to flow in a direction corresponding to said longitudinal direction of said channels. 6. The system as recited in claim 1 , wherein said at least one outlet discharges said fluid bearing said single-walled tubular fullerenes to flow in a direction angularly offset with respect to said longitudinal direction of said channels. 7. The system as recited in claim 1 , wherein said at least one outlet discharges said fluid bearing said single-walled tubular fullerenes to flow in an angularly offset direction with respect to a plane defined by said surface of said crystalline substrate. 8. The system as recited in claim 1 , wherein said separation plate is disposed on a support for rotative displacement together with said discharge of said fluid bearing said single-walled tubular fullerenes. 9. A system for bulk separation of single-walled tubular fullerenes based on chiral angle, comprising: a receptacle for holding a fluid bearing single-walled tubular fullerenes of a multiplicity of different chiral angles; a separation plate defined by a crystalline substrate having a lattice structure being exposed within a plurality of longitudinally directed channels formed thereon, each of said channels being formed to have a width selected to limit an angular tolerance of single-walled tubular fullerenes to be not greater than six degrees, said longitudinal direction being selected to be at an energetically favored angular orientation of an axis of said lattice structure of said crystalline substrate with respect to an axis of a lattice structure for single-walled tubular fullerenes of one chiral angle to be adsorbed to said crystalline substrate, said separation plate being insertable into said receptacle for immersion in said fluid; and a displacement assembly for displacing said separation plate relative to said fluid, wherein any of said single-walled tubular fullerenes of said one chiral angle entering into a respective one of said channels by said relative displacement being preferentially adsorbed and thereby held to said exposed portions of said upper surface of said crystalline substrate therein. 10. The system as recited in claim 9 , wherein said displacement assembly includes an agitator coupled to said receptacle for agitating said fluid to impart a motion to said single-walled tubular fullerenes therein relative to said separation plate. 11. A system for bulk separation of single-walled tubular fullerenes based on chiral angle, comprising: a receptacle for holding a fluid bearing single-walled tubular fullerenes of a multiplicity of different chiral angles; a separation plate defined by a crystalline substrate having a lattice structure being exposed within a plurality of longitudinally directed channels formed thereon, said longitudinal direction being selected to be at an energetically favored angular orientation of an axis of said lattice structure of said crystalline substrate with respect to an axis of a lattice structure for single-walled tubular fullerenes of one chiral angle to be adsorbed to said crystalline substrate, said separation plate being insertable into said receptacle for immersion in said fluid; and a displacement assembly for displacing said separation plate relative to said fluid, wherein any of said single-walled tubular fullerenes of said one chiral angle entering into a respective one of said channels by said relative displacement being preferentially adsorbed and thereby held to said exposed portions of said upper surface of said crystalline substrate therein, said displacement assembly including a carrier for holding said separation plate and an immersion assembly coupled to said holder for immersing said separation plate in said fluid and moving said separation plate within said receptacle to thereby move said separation plate relative to said fluid. 12. The system as recited in claim 11 , wherein said displacement assembly includes an agitator coupled to said receptacle for agitating said fluid to impart a motion to said single-walled tubular fullerenes therein relative to said separation plate.