Centrifugal pump assemblies having an axial flux electric motor and methods of assembly thereof

What is claimed is: 1. An electric motor assembly for pumping a fluid through a fluid cavity, said electric motor assembly comprising: a stator assembly comprising a plurality of conduction coils, wherein said conduction coils are configured to transmit heat energy to the fluid within the fluid cavity; a rotor assembly positioned adjacent said stator assembly to define an axial gap therebetween; a motor housing configured to house said stator assembly, wherein said motor housing comprises a wall configured to separate the rotor assembly from said stator assembly, wherein said motor housing prevents flow of the fluid along an axial end of said stator assembly opposite said rotor assembly; and an impeller directly coupled to said rotor assembly opposite said stator assembly such that said rotor assembly and said impeller are configured to rotate about an axis, wherein said rotor assembly and said impeller are configured to be submerged in the fluid within the fluid cavity, wherein said wall extends radially outward beyond a radially outward end of said impeller, and wherein an axially-oriented fluid flow channel is defined by and between said wall and said impeller, wherein said axially-oriented fluid flow channel is positioned radially inward of said stator assembly and wherein said wall further defines a fluid channel radially outward of said conductor coils, said fluid channel being in fluid communication with the fluid cavity. 2. The electric motor assembly in accordance with claim 1 , wherein said wall comprises an axial portion positioned immediately radially inward of said conductor coils. 3. The electric motor assembly in accordance with claim 2 , wherein said impeller comprises an axial extension, and wherein a radial gap is defined between said axial extension and said wall axial portion. 4. The electric motor assembly in accordance with claim 1 , wherein said wall comprises a radial portion extending radially within said axial gap between said stator assembly and said rotor assembly. 5. The electric motor assembly in accordance with claim 1 , wherein said conductor coils are configured to transmit the heat energy through said wall to heat the fluid within the fluid cavity. 6. The pump assembly in accordance with claim 1 , wherein an axial portion of said wall separates said stator assembly from said impeller, such that said axially-oriented fluid channel extends along said impeller opposite said conduction coils from said axial portion of the wall. 7. The electric motor assembly in accordance with claim 1 , wherein said rotor assembly comprises a rotor disk and a plurality of permanent magnets, wherein said rotor disk is coupled to said impeller. 8. The electric motor assembly in accordance with claim 7 , wherein said impeller comprises a front plate defining an inlet and an opposing rear plate, said rear plate coupled to said rotor disk. 9. A pump assembly comprising: a pump housing defining a fluid cavity; a motor housing coupled to said pump housing, wherein said motor housing comprises a wall having an axial portion and a radial portion; an electric motor assembly comprising: a stator assembly positioned within said motor housing and comprising a plurality of conduction coils, wherein said conduction coils are configured to transmit heat energy to a fluid within the fluid cavity; and a rotor assembly positioned adjacent said stator assembly and within said pump housing, wherein said wall is configured to separate said fluid cavity from said stator assembly, to limit fluid flow to within said pump housing, and to seal said stator assembly from said rotor assembly; and an impeller directly coupled to said rotor assembly opposite said stator assembly such that said rotor assembly and said impeller are configured to rotate about an axis, wherein said rotor assembly and said impeller are configured to be submerged in the fluid within the fluid cavity, wherein said wall extends radially outward beyond a radially outward end of said impeller, and wherein an axially-oriented fluid flow channel is defined by and between said wall axial portion and said impeller, wherein said axial portion separates said stator assembly from said impeller such that said axially-oriented fluid channel extends along said impeller opposite said conduction coils from said axial portion; and wherein said motor housing prevents flow of the fluid along an axial end of said stator assembly opposite said rotor assembly and said wall further defines a fluid channel radially outward of said conductor coils, said fluid channel being in fluid communication with the fluid cavity. 10. The pump assembly in accordance with claim 9 , wherein said axial portion is positioned immediately radially inward of said conductor coils and said radial portion extends radially within an axial gap between said conductor coils and said rotor assembly. 11. The pump assembly in accordance with claim 9 , wherein said impeller comprises an axial extension, and wherein a radial gap is defined between said axial extension and said wall axial portion. 12. The pump assembly in accordance with claim 9 , wherein said conductor coils are configured to transmit the heat energy through said wall to heat the fluid within the fluid cavity. 13. The pump assembly in accordance with claim 9 , wherein said axial portion and said radial portion of said wall are integrally formed. 14. The pump assembly in accordance with claim 9 , wherein said axially-oriented fluid flow channel is positioned radially inward of said stator assembly. 15. A method of assembling a pump assembly for pumping a fluid through a fluid cavity, said method comprising: providing a stator assembly including a plurality of conduction coils, wherein the conduction coils are configured to transmit heat energy to the fluid within the fluid cavity; coupling the stator assembly within a motor housing such that the conductor coils are positioned proximate a wall of the motor housing; positioning a rotor assembly adjacent the stator assembly such that an axial gap is defined therebetween, wherein the wall separates the rotor assembly from the conductor coils, wherein the motor housing prevents flow of the fluid along an axial end of the stator assembly opposite the rotor; and coupling an impeller directly to the rotor assembly opposite the stator assembly such that the rotor assembly and the impeller are configured to rotate about an axis, wherein the rotor assembly and the impeller are configured to be submerged in the fluid within the fluid cavity, wherein the wall extends radially outward beyond a radially outward end of the impeller, and wherein an axially-oriented fluid flow channel is defined by and between the wall and the impeller, wherein the axially-oriented fluid flow channel is positioned radially inward of the stator assembly and wherein said wall further defines a fluid channel radially outward of said conductor coils, said fluid channel being in fluid communication with the fluid cavity. 16. The method in accordance with claim 15 , wherein submerging the rotor assembly within the fluid comprises exposing the rotor assembly to the fluid such that the rotor assembly is cooled by the fluid. 17. The method in accordance with claim 15 , further comprising: coupling a pump housing to the motor housing, wherein the pump housing defines the fluid cavity; and positioning the rotor assembly and the impeller within the fluid cavity in the pump housing. 18. The method in accordance with claim 17 , wherein positioning the rotor assembly adjacent th