Traveling wave tube loaded by a material having negative permittivity and positive permeability

What is claimed is: 1. A slow wave structure of a traveling wave tube comprising: a tube; an input port at a second end of the tube; an output port at a second end of the tube; a first material mounted within the tube between the input port and the output port; and a second material, wherein the second material is mounted in the first material at periodic intervals in a direction of propagation of a radio frequency signal between the input port and the output port, and the second material has a real part of permittivity that is negative and a real part of permeability that is positive at an operational frequency of the radio frequency signal. 2. The slow wave structure of claim 1 , wherein the tube is a helical coil formed by the first material and the second material, and the second material is mounted across at least a portion of the cross section of the helical coil. 3. The slow wave structure of claim 1 , wherein the first material is vacuum. 4. The slow wave structure of claim 3 , wherein the tube is a coupled cavity waveguide having a cross section perpendicular to the direction of propagation of the radio frequency signal. 5. The slow wave structure of claim 4 , wherein the second material is mounted across at least a portion of the cross section of the coupled cavity waveguide. 6. The slow wave structure of claim 3 , wherein the tube is a folded waveguide having a cross section perpendicular to the direction of propagation of the radio frequency signal. 7. The slow wave structure of claim 6 , wherein the second material is mounted across at least a portion of the cross section of the folded waveguide. 8. A traveling wave tube comprising: a slow wave structure comprising an input port at a first end of the slow wave structure; an output port at a second end of the slow wave structure; a first material mounted within the slow wave structure between the input port and the output port; and a second material, wherein the slow wave structure is configured to receive a radio frequency signal through the input port and to output an amplified radio frequency signal through the output port, wherein the radio frequency signal has an operational frequency; and an electron beam vacuum tube configured to receive an electron beam and to focus the electron beam for transmission therethrough, wherein the electron beam vacuum tube is mounted to extend lengthwise through a center of the slow wave structure defined in a plane perpendicular to a direction of propagation of the electron beam, wherein the second material is mounted in the first material at periodic intervals in a direction of propagation of the radio frequency signal between the input port and the output port, and the second material has a real part of permittivity that is negative and a real part of permeability that is positive at the operational frequency. 9. The traveling wave tube of claim 8 , wherein the slow wave structure is a helical coil formed by the first material and the second material, and the second material is mounted across at least a portion of a cross section of the helical coil. 10. The traveling wave tube of claim 8 , wherein the first material is vacuum. 11. The traveling wave tube of claim 10 , wherein the slow wave structure is a folded waveguide having a cross section perpendicular to the direction of propagation of the radio frequency signal. 12. The traveling wave tube of claim 11 , wherein the second material is mounted across at least a portion of the cross section of the folded waveguide. 13. The traveling wave tube of claim 12 , wherein the folded waveguide is a serpentine folded waveguide. 14. The traveling wave tube of claim 13 , wherein the second material forms a wedge. 15. The traveling wave tube of claim 12 , wherein the second material is mounted at a maximum distance from the center of the slow wave structure. 16. The traveling wave tube of claim 12 , wherein the second material is a metal plate that extends across the portion of the cross section of the folded waveguide. 17. The traveling wave tube of claim 16 , wherein the cross section is rectangular and the metal plate extends lengthwise between longer sides of the rectangular cross section and only partially lengthwise between shorter sides of the rectangular cross section. 18. The traveling wave tube of claim 12 , wherein the second material is a plurality of metal wires that extend lengthwise across the portion of the cross section of the folded waveguide. 19. The traveling wave tube of claim 18 , wherein the cross section is rectangular and the plurality of metal wires extend lengthwise between longer sides of the rectangular cross section. 20. The traveling wave tube of claim 8 , wherein the second material provides a shunt inductive load to the slow wave structure.