A metamaterial includes a plurality of first coiled resonators and a plurality of second coiled resonators, and an outer covering for fixing the positions of the first coiled resonators and the second coiled resonators. Each of the first coiled resonators and each of the second coiled resonators are
A metamaterial includes a plurality of first coiled resonators and a plurality of second coiled resonators, and an outer covering for fixing the positions of the first coiled resonators and the second coiled resonators. Each of the first coiled resonators and each of the second coiled resonators are disposed such that the central axes thereof differ from each other by 90 degrees. At the same time, adjacent first coiled resonators and second coiled resonators are disposed so as to be alternately linked in the shape of a chain. The first coiled resonators are disposed in a spatially continuous manner.
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1. A metamaterial comprising: a plurality of first resonators that each generate a negative dielectric constant with respect to a predetermined wavelength, each of the first resonators defining an internal space;a plurality of second resonators that each generate a negative magnetic permeability wit
1. A metamaterial comprising: a plurality of first resonators that each generate a negative dielectric constant with respect to a predetermined wavelength, each of the first resonators defining an internal space;a plurality of second resonators that each generate a negative magnetic permeability with respect to the predetermined wavelength and wherein the second resonators are multilayer capacitive resonators; anda supporting member that fixes each of the second resonators inside the plurality of first resonators, and fixes the plurality of first resonators so that the plurality of first resonators are disposed in a spatially continuous manner,wherein a length of the plurality of second resonators along a direction of electric current propagation in a signal line is less than λ/20 with respect to a wavelength λ of an electromagnetic wave at a resonant frequency, andwherein the multilayer capacitive resonators have a capacitance and an inductance, and the capacitance and the inductance comprise a closed-loop. 2. The metamaterial according to claim 1, wherein each of the first resonators comprise a metallic wire having a length of substantially half the predetermined wavelength. 3. The metamaterial according to claim 2, wherein the metallic wire comprises a first coil having a length of substantially half the predetermined wavelength and a central axis, each of the second resonators includes a second coil and a center axis orthogonal to the central axis of the first coil, andthe supporting member fixes the first coil and the second coil so that the first coil and the second coil are disposed so as to be alternately linked. 4. The metamaterial according to claim 2, wherein the metallic wire comprises a first coil having a length of substantially half the predetermined wavelength and a central axis, and the supporting member fixes each of the second resonators in a region surrounded by a corresponding first coil. 5. The metamaterial according to claim 4, wherein each of the second resonators includes a second coil and a center axis orthogonal to the central axis of the first coil. 6. The metamaterial according to claim 5, wherein each of the first resonators further comprises a conductive plate connected to an end of the first coil. 7. The metamaterial according to claim 2, wherein each of the first resonators further comprises: a first plate electrode connected to a first end of the metallic wire, anda second plate electrode connected to a second end of the metallic wire, the second end being opposite to the first end,wherein the supporting member fixes each of the second resonators in a region between the first plate electrode and the second plate electrode. 8. The metamaterial according to claim 7, wherein the metallic wire is bent. 9. The metamaterial according to claim 7, wherein each of the second resonators comprises: a first electrode plane,a second electrode plane opposed to the first electrode plane, anda conductive section that electrically connects the first electrode plane and the second electrode plane. 10. The metamaterial according to claim 9, wherein the supporting member comprises an insulating material, the first electrode plane and the second electrode plane are in the insulating material, and the conductive section electrically connects the first electrode plane and the second electrode plane through a via in the insulating material. 11. The metamaterial according to claim 10, wherein the supporting member, the first resonators, and the second resonators are multiple substrate layers. 12. A metamaterial comprising: a first resonator that generates a negative dielectric constant with respect to a predetermined wavelength, the first resonator defining an internal space;a second resonator that generates a negative magnetic permeability with respect to the predetermined wavelength, wherein the second resonator is a multilayer capacitive resonator; anda supporting member that fixes positions of the first resonator and the second resonator so that the second resonator is inside the first resonator,wherein a length of the second resonator along a direction of electric current propagation in a signal line is less than λ/20 with respect to a wavelength λ of an electromagnetic wave at a resonant frequency, andwherein the multilayer capacitive resonator has a capacitance and an inductance, and the capacitance and the inductance comprise a closed-loop. 13. A metamaterial comprising: a plurality of first resonators that each generate a negative dielectric constant with respect to a predetermined wavelength;a plurality of second resonators that each generate a negative magnetic permeability with respect to the predetermined wavelength, each of the second resonators defining an internal space, and wherein the second resonators are multilayer capacitive resonators; anda supporting member that fixes positions of the first resonator and the second resonator so that each of the first resonators is inside the plurality of second resonators, and fixes the plurality of second resonators so that the plurality of second resonators are disposed in a spatially continuous manner,wherein a length of the plurality of second resonators along a direction of electric current propagation in a signal line is less than λ/20 with respect to a wavelength λ of an electromagnetic wave at a resonant frequency, andwherein the multilayer capacitive resonators have a capacitance and an inductance, and the capacitance and the inductance comprise a closed-loop. 14. The metamaterial according to claim 13, wherein each of the first resonators comprises a metallic wire having a length of substantially half the predetermined wavelength. 15. The metamaterial according to claim 13, wherein the metallic wire is bent. 16. The metamaterial according to claim 13, wherein each of the second resonators comprises: a first electrode plane,a second electrode plane opposed to the first electrode plane, anda conductive section that electrically connects the first electrode plane and the second electrode plane. 17. The metamaterial according to claim 16, wherein the supporting member comprises an insulating material, the first electrode plane and the second electrode plane are in the insulating material, and the conductive section electrically connects the first electrode plane and the second electrode plane through a via in the insulating material. 18. The metamaterial according to claim 17, wherein the supporting member, the first resonators, and the second resonators are multiple substrate layers. 19. A metamaterial comprising: a first resonator that generates a negative dielectric constant with respect to a predetermined wavelength;a second resonator that generates a negative magnetic permeability with respect to the predetermined wavelength, the second resonator defining an internal space, and wherein the second resonator is a multilayer capacitive resonator; anda supporting member that fixes positions of the first resonator and the second resonator so that the first resonator is inside the second resonator,wherein a length of the second resonator along a direction of electric current propagation in a signal line is less than λ/20 with respect to a wavelength λ of an electromagnetic wave at a resonant frequency, andwherein the multilayer capacitive resonator has a capacitance and an inductance, and the capacitance and the inductance comprise a closed-loop.
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