Magnetodielectric y-phase strontium hexagonal ferrite materials formed by sodium substitution

What is claimed is: 1 . A magnetodielectric hexagonal ferrite comprising: a y-phase strontium hexagonal ferrite material having sodium substituted for strontium and including a trivalent or tetravalent ion to form a magnetodielectric hexagonal ferrite, the composition of the magnetodielectric hexagonal ferrite being Sr 2-x Na x Co 2-x M x Fe 12 O 22 when a trivalent ion is used, where M is a trivalent ion, and the composition of the magnetodielectric hexagonal ferrite being Sr 2-2-2x Na 2x Co 2x N x Fe 12 O 22 when a tetravalent ion is used, where N is a tetravalent ion. 2 . The hexagonal ferrite of claim 1 wherein M is selected from the group consisting of Al, Ga, Sc, Cr, Mn, In, Yb, Er, Y or other lanthanide. 3 . The hexagonal ferrite of claim 1 wherein N is selected from the group consisting of Si, Ge, Ti, Zr, Sn, Ce, Pr, Hf, or Tb. 4 . The hexagonal ferrite of claim 1 wherein x is from 0 to about 1.5 in the trivalent substitution and from 0 to about 0.75 in the tetravalent substitution. 5 . The hexagonal ferrite of claim 1 wherein the magnetodielectric hexagonal ferrite has the composition Sr 1.75 Na 0.25 Co 1.75 M 0.25 Fe 12 O 22 . 6 . The hexagonal ferrite of claim 1 wherein the magnetodielectric hexagonal ferrite has the composition Sr 1.5 Na 0.5 Co 1.5 M 0.5 Fe 12 O 22 . 7 . The hexagonal ferrite of claim 1 wherein the loss factor of the magnetodielectric hexagonal ferrite remains below 4 at frequencies up to 1 GhZ. 8 . The hexagonal ferrite of claim 1 wherein the magnetodielectric hexagonal ferrite has a permeability of between around 5 and around 6 up to 1 GhZ. 9 . A method for improving magnetic properties of a hexagonal ferrite material, the method comprising: substituting sodium into a y-phase strontium hexagonal ferrite material for strontium; and charge balancing either using a trivalent or tetravalent ion to form a magnetodielectric hexagonal ferrite, the composition of the magnetodielectric hexagonal ferrite being Sr 2-x Na x Co 2-x M x Fe 12 O 22 when a trivalent ion is used, where M is a trivalent ion, and the compositions of the magnetodielectric hexagonal ferrite being Sr 2-2-2x Na 2x Co 2x N x Fe 12 O 22 when a tetravalent ion is used, where N is a tetravalent ion. 10 . The method of claim 9 wherein x is from 0 to about 1.5 in the trivalent substitution and from 0 to about 0.75 in the tetravalent substitution. 11 . The method of claim 9 wherein the magnetodielectric hexagonal ferrite has the composition Sr 1.75 Na 0.25 Co 1.75 M 0.25 Fe 12 O 22 . 12 . The method of claim 9 wherein the magnetodielectric hexagonal ferrite has the composition Sr 1.5 Na 0.5 Co 1.5 M 0.5 Fe 12 O 22 . 13 . The method of claim 9 wherein the loss factor of the magnetodielectric hexagonal ferrite remains below 4 at frequencies up to 1 GhZ. 14 . The method of claim 9 wherein the magnetodielectric hexagonal ferrite has a permeability of between around 5 and around 6 up to 1 GhZ. 15 . A magnetodielectric antenna comprising: a y-phase strontium hexagonal ferrite material having sodium substituted for strontium and including a trivalent or tetravalent ion to form a magnetodielectric hexagonal ferrite, the composition of the magnetodielectric hexagonal ferrite being Sr 2-x Na x Co 2-x M x Fe 12 O 22 when a trivalent ion is used, where M is a trivalent ion, and the composition of the magnetodielectric hexagonal ferrite being Sr 2-2-2x Na 2x Co 2x N x Fe 12 O 22 when a tetravalent ion is used, where N is a tetravalent ion. 16 . The magnetodielectric antenna of claim 15 wherein x is from 0 to about 1.5 in the trivalent substitution and from 0 to about 0.75 in the tetravalent substitution. 17 . The magnetodielectric antenna of claim 15 wherein the magnetodielectric hexagonal ferrite has the composition Sr 1.75 Na 0.25 Co 1.75 M 0.25 Fe 12 O 22 . 18 . The magnetodielectric antenna of claim 15 wherein the magnetodielectric hexagonal ferrite has the composition Sr 1.5 Na 0.5 Co 1.5 M 0.5 Fe 12 O 22 . 19 . The magnetodielectric antenna of claim 15 wherein the loss factor of the magnetodielectric hexagonal ferrite remains below 4 at frequencies up to 1 GhZ. 20 . The magnetodielectric antenna of claim 15 wherein the magnetodielectric hexagonal ferrite has a permeability of between around 5 and around 6 up to 1 GhZ.