Magnetic nano-transmitter plasma wave antenna

What is claimed is: 1 . A magnetic nanoparticle (MNT) antenna, comprising: a cylindrical core comprising a plurality of FeCo magnetic nanoparticles; and a wire coil wrapped around the cylindrical core. 2 . The MNT antenna of claim 1 , further comprising: an alternating current (AC) circuit coupled to the wire coil, wherein the AC circuit is matched to the wire coil, and wherein the AC circuit is configured to drive the wire coil. 3 . The MNT antenna of claim 1 , wherein the wire coil is a solenoidal wire coil. 4 . The MNT antenna of claim 1 , wherein the radiation resistance of the MNT antenna is given by R r (μ e , N, a, f)=μ 2 N 2 R r (a, f), wherein R r =(1, 1, a, f)˜(af 4 ) is the free-space radiation resistance of a single-turn loop antenna, wherein u is the permeability of the core, μe is a value of an effective permeability that includes demagnetization effects, N represents a number of loops in the wire coil, a represents a radius of the core, and f represents of frequency of the MNT antenna. 5 . The MNT antenna of claim 1 , wherein the FeCo magnetic nanoparticles are Single Domain Nanoparticles (SDN) nanoparticles. 6 . The MNT antenna of claim 1 , wherein each nanoparticle in the plurality of FeCo magnetic nanoparticles is a single domain nanoparticle (SDN). 7 . The MNT antenna of claim 6 , wherein a magnetization of each SDN is a single moment, and wherein the single moment is a sum of a plurality of magnetic moments of constituent atoms of each SDN. 8 . The MNT antenna of claim 6 , wherein a magnetic moment of each SDM has only two orientations antiparallel to each other separated by an energy barrier. 9 . The MNT antenna of claim 1 , further comprising: a polymer cap covering the FeCo magnetic nanoparticles, wherein the polymer cap maintains a separation between the FeCo magnetic nanoparticles such that the FeCo magnetic nanoparticles act independently. 10 . The MNT antenna of claim 1 , wherein the cylindrical core has a length to radius ratio of approximately 20. 11 . The MNT antenna of claim 1 , wherein the wire coil is made from copper. 12 . An antenna, comprising: a base comprising an alternating current (AC) circuit; a first magnetic nanoparticle (MNT) antenna element coupled to the base, wherein the first MNT element comprises: a cylindrical core comprising a plurality of FeCo magnetic nanoparticles, and a wire coil wrapped around the cylindrical core, wherein the wire coil is matched to the AC circuit, and wherein the AC circuit is configured to drive the wire coil; a second MNT antenna element coupled to the base, wherein the second MNT antenna element is positioned at a 90 degree angle from the first MNT element; a third MNT antenna element coupled to the base, wherein the third MNT antenna element is positioned at a 90 degree angle from the second MNT element; and a fourth MNT antenna element coupled to the base, wherein the fourth MNT antenna element is positioned at a 90 degree angle from the third MNT element and the first MNT element. 13 . The MNT antenna of claim 12 , wherein the plurality of MNT elements are oriented horizontally with respect to the base. 14 . The antenna of claim 12 , wherein the plurality of MNT elements are configured in a crossed dipole configuration. 15 . The MNT antenna of claim 12 , wherein the wire coil is a solenoidal wire coil. 16 . The MNT antenna of claim 12 , wherein the FeCo magnetic nanoparticles are Single Domain Nanoparticles (SDN) nanoparticles. 17 . The antenna of claim 12 , wherein each nanoparticle in the plurality of FeCo magnetic nanoparticles is a single domain nanoparticle (SDN). 18 . The MNT antenna of claim 12 , further comprising: a polymer cap covering the FeCo magnetic nanoparticles, wherein the polymer cap maintains a separation between the FeCo magnetic nanoparticles such that the FeCo magnetic nanoparticles act independently. 19 . The MNT antenna of claim 12 , wherein the cylindrical core has a length to radius ratio of approximately 20. 20 . A magnetic nanoparticle (MNT) antenna, comprising: a cylindrical core having a length to radius ratio of approximately 20, the cylindrical core comprising: a plurality of FeCo Single Domain Nanoparticles (SDN), wherein a magnetization of each SDN is a single moment, wherein the single moment is a sum of a plurality of magnetic moments of constituent atoms of each SDN, and wherein a magnetic moment of each SDN has only two orientations antiparallel to each other separated by an energy barrier, and a polymer cap covering the SDN, wherein the polymer cap maintains a separation between the SDN such that the SDN act independently; a solenoidal wire coil wrapped around the cylindrical core; and an alternating current (AC) circuit coupled to the wire coil, wherein the AC circuit is matched to the wire coil, and wherein the AC circuit is configured to drive the wire coil.