Systems and methods for separating metallic and nonmetallic particles in a mixed-particle suspension

We claim: 1. A continuous-flow method for separating metallic and nonmetallic particles from a mixed-particle suspension, comprising: providing an input flow of a mixed-particle fluid suspension in a single input channel, said single input channel being bifurcated into first and second output channels at a bifurcated junction; determining a time variation of a spatially-gradient and time-varying electric field to impose dielectrophoretic forces on metallic and nonmetallic particles in said mixed-particle suspension, wherein said determining takes into account a shape of said metallic and nonmetallic particles and a shape factor of said metallic and nonmetallic particles is determined according to L = ln ⁡ ( l r ) - 1 ( 1 2 ⁢ r ) 2 where l is a length of the metallic or nonmetallic particles and r is a radius of the metallic or nonmetallic particles; applying said spatially-gradient and time-varying electric field to said input flow of said mixed-particle fluid suspension in said single input channel to impose said dielectrophoretic forces on said metallic and nonmetallic particles in said mixed-particle fluid suspension; and collecting a metallic-particle rich fluid suspension from said first output channel and a nonmetallic-particle rich fluid suspension from said second output channel, wherein said spatially-gradient and time-varying electric field is further determined to have a time variation such that a dielectrophoretic force imposed on said metallic particles is different from a dielectrophoretic force imposed on said nonmetallic particles, and wherein said spatially-gradient and time-varying electric field is determined to have a time variation of at least 150 MHz. 2. A continuous-flow method according to claim 1 , wherein said spatially-gradient and time-varying electric field is further determined to have a time variation such that said dielectrophoretic force imposed on said metallic particles is opposite in direction to said dielectrophoretic force imposed on said nonmetallic particles. 3. A continuous-flow method according to claim 1 , wherein a fluid of said mixed-particle fluid suspension is selected based on at least one of an electrical permittivity or electrical conductivity thereof. 4. A continuous-flow method according to claim 1 , wherein a fluid of said mixed-particle fluid suspension is produced to have at least one of a selected electrical permittivity or electrical conductivity. 5. A continuous-flow method according to claim 1 , wherein said nonmetallic particles are semiconducting particles. 6. A continuous-flow method according to claim 1 , wherein said metallic particles are metallic carbon nanotubes, and wherein said nonmetallic particles are semiconducting carbon nanotubes. 7. A continuous-flow method according to claim 1 , further comprising: applying a second spatially-gradient and time-varying electric field to at least one of said metallic-particle rich fluid suspension in said first output channel or said nonmetallic-particle rich fluid suspension from said second output channel prior to said collecting as a second stage in a multistage method for separating metallic and nonmetallic particles. 8. A continuous-flow method according to claim 1 , wherein said shape factor is greater than zero. 9. A continuous-flow method according to claim 1 , wherein said determining said time variation of said spatially-gradient and time-varying electric field further comprises taking into account a frequency defined as ω = σ p ⁢ σ m + L ⁢ ⁢ σ p 2 - σ m 2 ε m 2 - ε p ⁢ ε m - L ⁢ ⁢ ε p 2 , where ∈ is a permittivity, σ is a conductivity, and L is a shape factor, and where the subscript m refers to a fluid in which said metallic and nonmetallic particles are suspended, and the subscript p refers to a metallic or nonmetallic particle. 10. A continuous-flow method according to claim 1 , wherein said spatially-gradient and time-varying electric field is further determined to have a time variation such that said difference between dielectrophoretic forces imposed on said metallic and said nonmetallic particles is maximized. 11. A continuous-flow method according to claim 1 , wherein said time variation of said spatially-gradient and time-varying electric field is further determined based on a conductivity of said nonmetallic particles. 12. A continuous-flow method according to claim 11 , wherein said conductivity of said nonmetallic particles is greater than 0. 13. A continuous-flow method according to claim 11 , wherein said conductivity of said nonmetallic particles is at least 10 4 Siemens/meter. 14. A continuous-flow method according to claim 1 , wherein said spatially-gradient and time-varying electric field is determined to have a time variation of at least 300 MHz. 15. A continuous-flow method according to claim 1 , wherein said spatially-gradient and time-v