Switched reluctance machines without permanent magnets

What is claimed is: 1. A switched reluctance machine comprising: a toroidal cylinder arranged about a longitudinal axis and comprising: an inner rotor core concentrically positioned about the longitudinal axis and comprising a plurality of flux shaping salient magnetic poles configured to concentrate flux linkage; an axial rotor core concentrically positioned about the longitudinal axis and comprising a set of flux shaping salient magnetic poles configured to concentrate flux linkage; and an axial rotor core inner edge positioned adjacent to a first end of inner rotor core; and cooperating with the inner rotor core to define a cavity within the toroidal cylinder; a coil winding assembly: comprising a set of coils arranged within the cavity defined by the inner rotor core and the axial core; and configured to rotate the inner rotor core and the axial core to minimize the reluctance of the switched reluctance machine in response to driving an alternating current across the set of coils. 2. The switched reluctance machine of claim 1 , wherein the toroidal cylinder further comprises an outer rotor core comprising a plurality of flux shaping salient magnetic poles configured to concentrate flux linkage, the outer rotor core comprising a first end positioned adjacent to an outer edge of the axial rotor core, the rotor cores forming a three-sided reluctance torque tunnel. 3. The switched reluctance machine of claim 2 , wherein the outer rotor core and the coil winding assembly are configured to minimize an air gap between the outer rotor core and the coil winding assembly. 4. The switched reluctance machine of claim 2 , wherein the outer rotor core defines, at least in part, a transverse slot, and wherein the transverse slot allows a support for the coil winding assembly to pass through the outer rotor core. 5. The switched reluctance machine of claim 2 , wherein the outer edge of the axial rotor core and the first end of the outer core define a transverse slot. 6. The switched reluctance machine of claim 2 , wherein a longitudinal length of an inner face of the inner rotor core is greater than a radial length of an inner face of the axial rotor core. 7. The switched reluctance machine of claim 1 , wherein a radial length of an inner face of the axial rotor core is greater than a longitudinal length of an inner face of the inner rotor core. 8. The switched reluctance machine of claim 1 , wherein the inner rotor core comprises flux shaping salient magnetic poles and the coil winding assembly comprises non-salient flux shaping magnetic poles. 9. The switched reluctance machine of claim 2 , wherein the inner rotor core and the outer rotor core have the same number of flux shaping salient magnetic poles. 10. The switched reluctance machine of claim 1 , wherein the rotor core comprises laminated strips of grain-oriented electrical steel coated with an oxide layer. 11. The switched reluctance machine of claim 1 , wherein the rotor core comprises an isotropic ferromagnetic material. 12. The switched reluctance machine of claim 1 , wherein the inner rotor core and the axial rotor core comprise an isotropic ferromagnetic material of a porosity between about 75% and about 95% by volume, the ferromagnetic isotropic material comprising an open cell metal foam material infused with a structural support matrix made of thermoset or a thermoplastic resin. 13. The switched reluctance machine of claim 1 , wherein the axial rotor core and the coil winding assembly are configured to minimize an airgap between the axial rotor core and the coil winding assembly. 14. The switched reluctance machine of claim 2 , wherein the outer rotor core and the coil winding assembly are configured to minimize an airgap between the outer rotor core and the coil winding assembly. 15. An electric machine comprising: a rotor core assembly comprising: an inner rotor core: arranged about a motor axis; and comprising a first a set of magnetic poles configured to induce flux linkage about the inner rotor core; an outer rotor core: arranged about the motor axis and encompassing the inner rotor core; and comprising a second set of magnetic poles configured to induce flux linkage about the outer rotor core; and an axial rotor core: arranged about the motor axis interposed between the inner rotor core and the outer rotor core; comprising a third set of magnetic poles configured to induce flux linkage about the axial rotor core; and cooperating with the axial core and the inner rotor core to form a cavity; and a set of coil assemblies: arranged within the cavity; and configured to inductively couple the inner rotor core, the axial rotor core, and the outer rotor core to rotate the rotor core assembly about the motor axis. 16. The electric machine of claim 15 : wherein an outer edge of the axial rotor core and a first end of the outer rotor core define a first set of slots; and further comprising a first set of magnetic elements: arranged within the set of slots; and interposed between the second set of magnetic poles of the outer rotor core and the third set of magnetic poles of the axial rotor core. 17. The electric machine of claim 15 : wherein the second set of magnetic poles of the outer rotor core approximates the first set of magnetic poles of the inner rotor core; and wherein the third set of magnetic poles of the axial rotor core approximates the first set of magnetic poles of the inner rotor core. 18. The electric machine of claim 15 : wherein the axial rotor core defines: an inner radial edge; and an outer radial edge; wherein the inner rotor core is arranged within the inner radial edge of the axial rotor core and coaxial with the motor axis; and wherein the outer rotor core defines a cylindrical wall encompassing the inner rotor core, the cylindrical wall comprising a first end adjacent to the outer radial edge of the axial rotor core. 19. A system comprising: a rotor core assembly comprising: an inner rotor core: arranged about a motor axis; and comprising first a set of magnetic poles configured to induce flux linkage about the inner rotor core; an axial rotor core: arranged about the inner rotor core; comprising a second set of magnetic poles configured to induce flux linkage about the axial rotor core, the second set of magnetic poles approximating the first set of magnetic poles; and cooperating with the inner rotor core to form a cavity; and a set of coil assemblies: arranged within the cavity; and configured to inductively couple the inner rotor core and the axial rotor core to rotate the rotor core assembly about the motor axis. 20. The system of claim 19 , wherein the rotor core assembly further comprises an outer rotor core: arranged about the motor axis and encompassing the inner rotor core; comprising a third set of magnetic poles configured to induce flux linkage about the outer rotor core; and cooperating with the inner rotor core and the outer rotor core to define the cavity.