Dual magnetic phase material rings for AC electric machines

What is claimed is: 1. An AC electric machine comprising: a stator assembly; and a rotor assembly positioned within the stator assembly and configured to rotate relative thereto, the rotor assembly comprising a rotor core including a stack of rotor laminations that collectively form the rotor core, the rotor core including a plurality of rotor poles separated by gaps therebetween; and a dual magnetic phase material ring positioned about the stack of rotor laminations, the dual magnetic phase material ring comprising: a first ring portion comprising a magnetic portion; and a second ring portion comprising a non-magnetic portion. 2. The AC electric machine of claim 1 wherein the first ring portion is adjacent to the rotor poles of the rotor core and the second ring portion is adjacent to the gaps between the rotor poles of the rotor core. 3. The AC electric machine of claim 1 wherein the second ring portion comprises a treated portion of the ring, with the treating of the second ring portion rendering the dual magnetic phase material of the ring non-magnetic at the locations of the second ring portion. 4. The AC electric machine of claim 3 wherein the treated portion comprises one of a heat treated portion, a portion having a nitriding treatment performed thereon, and a portion having mechanical stress applied thereto. 5. The AC electric machine of claim 2 wherein the stator assembly and the rotor core comprise laminations having a single magnetic phase, and wherein the dual magnetic phase material ring being used in combination with the stator and rotor laminations having a single magnetic phase provides a consistent power density for the AC electric machine during low and high speed operation. 6. The AC electric machine of claim 1 wherein the dual magnetic phase material ring comprises an integral, non-segmented ring formed as a single piece from a single magnetic phase material that is treated to form the first and second portions. 7. The AC electric machine of claim 1 wherein the dual magnetic phase material ring has a ring shape. 8. The AC electric machine of claim 1 wherein the dual magnetic phase material ring comprises: an outer ring; and one or more U-shaped structures that extend radially inward from the outer ring, wherein each of the one or more U-shaped structures is formed as a magnetic portion of the dual magnetic phase material ring, with connecting portions that connect the one or more U-shaped structures to the outer ring and to the rotor laminations being formed as non-magnetic portions. 9. The AC electric machine of claim 1 wherein the dual magnetic phase material ring comprises: an outer ring; and a linear protrusion that extends radially inward from the outer ring and through a majority of the rotor core, with alternating portions of the linear protrusion being magnetic and non-magnetic, with the magnetic portions being aligned with material of the rotor core and the non-magnetic portions being aligned with intermittent air gaps formed in the rotor core. 10. The AC electric machine of claim 1 wherein the AC electric machine comprises one of a synchronous reluctance machine, an induction machine and a permanent magnet machine. 11. A rotor assembly for an AC electric machine, the rotor assembly comprising: a rotor core comprising a stack of rotor laminations that collectively form the rotor core, the rotor core including a plurality of rotor poles separated by gaps therebetween; and a dual magnetic phase material sleeve positioned about the rotor core, the dual magnetic phase material sleeve comprising: a first sleeve portion comprising a magnetic portion; and a second sleeve portion comprising a non-magnetic portion; wherein the first sleeve portion is adjacent to the rotor poles of the rotor core and the second sleeve portion is adjacent to the gaps between the rotor poles of the rotor core. 12. The rotor assembly of claim 11 wherein the second sleeve portion comprises a treated portion of the sleeve, with the treating of the second sleeve portion rendering the dual magnetic phase material of the sleeve non-magnetic at the locations of the second sleeve portion. 13. The rotor assembly of claim 11 wherein the stack of rotor laminations comprises laminations having a single magnetic phase, and wherein the dual magnetic phase material sleeve used in combination with the stack of rotor laminations having a single magnetic phase provides a consistent power density for the AC electric machine during low and high speed operation. 14. The rotor assembly of claim 11 wherein the sleeve comprises an outer cylindrical sleeve. 15. The rotor assembly of claim 14 wherein the sleeve further comprises one or more U-shaped structures that extend radially inward from the outer cylindrical sleeve, wherein each of the one or more U-shaped structures is formed as a magnetic portion of the dual magnetic phase material ring, with connecting portions that connect the one or more U-shaped structures to the outer ring and to the rotor laminations being formed as non-magnetic portions. 16. The rotor assembly of claim 14 wherein the sleeve further comprises a linear protrusion that extends radially inward from the outer cylindrical sleeve and through a majority of the rotor core, with alternating portions of the linear protrusion being magnetic and non-magnetic, with the magnetic portions being aligned with material of the rotor core and the non-magnetic portions being aligned with intermittent air gaps formed in the rotor core. 17. A method for manufacturing an AC electric machine, the method comprising: providing a stator defining a stator bore; providing a rotor assembly for positioning within the stator bore that is configured to rotate relative thereto, wherein providing the rotor assembly comprises: arranging and assembling a plurality of rotor laminations to form a rotor core, the rotor core having a plurality of rotor poles separated by gaps therebetween; and positioning a dual magnetic phase material ring about the rotor core that is formed of a magnetic phase material that is magnetic in a first state and nonmagnetic in a second state, wherein portions of the dual magnetic phase material ring adjacent the plurality of rotor poles are in the first state and wherein portions of the dual magnetic phase material ring adjacent the gaps between the plurality of rotor poles are in the second state. 18. The method of claim 17 further comprising treating the dual magnetic phase material ring to put portions of the dual magnetic phase material ring in the nonmagnetic second state slot, the treating comprising one of heat treating, nitriding, and applying mechanical stress to render the portions non-magnetic. 19. The method of claim 17 wherein the ring comprises a cylindrical ring. 20. The method of claim 19 wherein the ring further comprises one or more U-shaped structures that extend radially inward from the cylindrical ring, wherein each of the one or more U-shaped structures is in the first state, with connecting portions that connect the one or more U-shaped structures to the cylindrical ring and to the rotor laminations being in the second state.