Systems and methods for conductivity coatings on wireless power resonators

What is claimed is: 1 . A resonator for use in a transcutaneous energy transfer system (TETS), the resonator comprising: a housing; a magnetic core positioned within the housing, the magnetic core comprising an annular sidewall and a central post that define an annular groove; a coil element positioned within the annular groove and surrounding the central post; and a metal object coated with a conductive material, wherein the conductive material facilitates reducing an amount of heat induced during operation of the resonator. 2 . The resonator of claim 1 , wherein the resonator is an implantable receive resonator. 3 . The resonator of claim 1 , wherein the conductive material is silver, copper, gold and/or aluminum. 4 . The resonator of claim 1 , wherein the metal object is a bulge-shaped metal header block positioned on one side of the resonator, the metal header block including an exterior surface that faces away from the rest of the resonator, the exterior surface coated with the conductive material. 5 . The resonator of claim 1 , wherein the metal object is a metal disk forming a back side of the resonator, the metal disk including an interior surface that faces the coil element, the interior surface coated with the conductive material. 6 . The resonator of claim 5 , further comprising: a metal ring circumscribing the metal disk; and a braze material coupling an outer diameter of the metal ring to the housing, wherein the braze material is made of a material that facilitates further reducing the amount of heat induced during operation of the resonator. 7 . The resonator of claim 6 , wherein the outer diameter of the metal ring is coated with the conductive material. 8 . A wireless power transfer system comprising: an external transmit resonator; and an implantable receive resonator, the implantable receive resonator comprising: a housing; a magnetic core positioned within the housing, the magnetic core comprising an annular sidewall and a central post that define an annular groove; a coil element positioned within the annular groove and surrounding the central post; and a metal object coated with a conductive material, wherein the conductive material facilitates reducing an amount of heat induced during operation of the implantable receive resonator. 9 . The wireless power transfer system of claim 8 , wherein the conductive material is silver, copper, gold and/or aluminum. 10 . The wireless power transfer system of claim 8 , wherein the metal object is a bulge-shaped metal header block positioned on one side of the implantable receive resonator, the metal header block including an exterior surface that faces away from the rest of the implantable receive resonator, the exterior surface coated with the conductive material. 11 . The wireless power transfer system of claim 8 , wherein the metal object is a metal disk forming a back side of the implantable receive resonator, the metal disk including an interior surface that faces the coil element, the interior surface coated with the conductive material. 12 . The wireless power transfer system of claim 11 , wherein the implantable receive resonator further comprises: a metal ring circumscribing the metal disk; and a braze material coupling an outer diameter of the metal ring to the housing, wherein the braze material is made of a material that facilitates further reducing the amount of heat induced during operation of the implantable receive resonator. 13 . The wireless power transfer system of claim 12 , wherein the outer diameter of the metal ring is coated with the conductive material. 14 . A method of assembling a resonator for use in a transcutaneous energy transfer system (TETS), the method comprising: positioning a magnetic core within a housing, the magnetic core including an annular sidewall and a central post that define an annular groove; positioning a coil element within the annular groove; and coating a metal object of the resonator with a conductive material, wherein the conductive material facilitates reducing an amount of heat induced during operation of the resonator. 15 . The method of claim 14 , wherein the resonator is an implantable receive resonator. 16 . The method of claim 14 , wherein coating a metal object comprises coating the metal object with silver, copper, gold and/or aluminum. 17 . The method of claim 14 , wherein coating a metal object comprises coating a surface of a bulge-shaped metal header block positioned on one side of the resonator. 18 . The method of claim 14 , wherein coating a metal object comprises coating an interior surface of a metal disk forming a back side of the resonator. 19 . The method of claim 18 , further comprising: coupling the metal disk to a metal ring circumscribing the metal disk; and coupling an outer diameter of the metal ring to the housing using a braze material, wherein the braze material is made of a material that facilitates further reducing the amount of heat induced during operation of the resonator. 20 . The resonator of claim 19 , further comprising coating the outer diameter of the metal ring with the conductive material.