Resistance spot welding method

The invention claimed is: 1. A resistance spot welding method, comprising: placing an electrically conductive coating between a polymeric workpiece and a metallic workpiece, wherein the metallic workpiece has a textured surface facing the polymeric workpiece; piercing the polymeric workpiece with first and second electrically conductive pins of a welding electrode assembly; applying electrical energy to the first and second electrically conductive pins so that an electrical current flows through the first electrically conductive pin, the electrically conductive coating, and the second electrically conductive pin in order to at least partially melt the polymeric workpiece and the electrically conductive coating, thereby forming a weld pool; and cooling the weld pool so as to form a solid weld nugget in order to establish a mechanical interface lock between the solid weld nugget and the textured surface, wherein the mechanical interface lock interconnects the polymeric workpiece to the metallic workpiece. 2. The resistance spot welding method of claim 1 , wherein the textured surface has an arithmetic average roughness ranging between 0.001 and 2000 micrometers. 3. The resistance spot welding method of claim 1 , further comprising applying a clamping force to the polymeric and metallic workpieces in order to press the polymeric workpiece against the electrically conductive coating and the metallic workpiece. 4. The resistance spot welding method of claim 3 , further comprising advancing the first and second electrically conductive pins through the polymeric workpiece until the first and second electrically conductive pins contact the electrically conductive coating disposed between the polymeric and metallic workpieces. 5. The resistance spot welding method of claim 1 , further comprising withdrawing the first and second electrically conductive pins from the polymeric workpiece after forming the weld pool. 6. The resistance spot welding method of claim 1 , wherein the cooling is conducted by natural convection. 7. The resistance spot welding method of claim 1 , wherein placing the electrically conductive coating between the polymeric and metallic workpieces includes placing the electrically conductive coating on the textured surface. 8. The resistance spot welding method of claim 7 , wherein placing the electrically conductive coating includes placing the electrically conducting coating on a portion of the textured surface that defines a workpiece cavity so that the electrically conductive coating is at least partially disposed in the workpiece cavity. 9. The resistance spot welding method of claim 8 , wherein the polymeric workpiece has a melting point of about 270 degrees Celsius, the metallic workpiece has a melting point that is greater than 270 degrees Celsius, and applying electrical energy to the first and second electrically conductive pins includes supplying sufficient electric current to the electrically conductive coating for a sufficient amount of time in order to heat the polymeric workpiece and the electrically conductive coating at a temperature that is greater than 270 degrees Celsius in order to form the weld pool. 10. The resistance spot welding method of claim 1 , wherein applying electrical energy to the first and second electrically conductive pins includes supplying sufficient electric current to the electrically conductive coating for a sufficient amount of time in order to completely melt the electrically conductive coating. 11. A resistance spot welding method, comprising: applying a clamping force to a polymeric workpiece and a metallic workpiece in order to press the polymeric workpiece against the metallic workpiece, wherein the metallic workpiece includes a textured surface facing the polymeric workpiece, and an electrically conductive coating is disposed on the textured surface; piercing the polymeric workpiece with first and second electrically conductive pins of a welding electrode assembly; applying electrical energy to the first and second electrically conductive pins so that an electrical current flows through the first electrically conductive pin, the electrically conductive coating, and the second electrically conductive pin in order to at least partially melt the polymeric workpiece and the electrically conductive coating, thereby forming a weld pool; and cooling the weld pool so as to form a solid weld nugget in order to establish a mechanical interface lock between the solid weld nugget and the textured surface, wherein the mechanical interface lock interconnects the polymeric workpiece to the metallic workpiece. 12. The resistance spot welding method of claim 11 , wherein the textured surface has an arithmetic average roughness ranging between 0.001 and 2000 micrometers. 13. The resistance spot welding method of claim 11 , wherein applying the clamping force to the polymeric and metallic workpieces includes advancing the welding electrode assembly toward the metallic workpiece. 14. The resistance spot welding method of claim 13 , further comprising advancing the first and second electrically conductive pins through the polymeric workpiece until the first and second electrically conductive pins contact the electrically conductive coating disposed between the polymeric and metallic workpieces. 15. The resistance spot welding method of claim 11 , further comprising withdrawing the first and second electrically conductive pins from the polymeric workpiece after forming the weld pool. 16. The resistance spot welding method of claim 11 , wherein the cooling is conducted by natural convection. 17. The resistance spot welding method of claim 11 , wherein the electrically conductive coating is placed between the polymeric and metallic workpieces. 18. The resistance spot welding method of claim 17 , further comprising placing the electrically conductive coating on a portion of the textured surface that defines a workpiece cavity so that the electrically conductive coating is at least partially disposed in the workpiece cavity. 19. The resistance spot welding method of claim 11 , wherein the polymeric workpiece has a melting point of about 270 degrees Celsius, the metallic workpiece has a melting point that is greater than 270 degrees Celsius, and applying electrical energy to the first and second electrically conductive pins includes supplying sufficient electric current to the electrically conductive coating for a sufficient amount of time in order to heat the polymeric workpiece and the electrically conductive coating at a temperature that is greater than 270 degrees Celsius in order to form the weld pool. 20. The resistance spot welding method of claim 11 , wherein applying electrical energy to the first and second electrically conductive pins includes supplying sufficient electric current to the electrically conductive coating for a sufficient amount of time in order to completely melt the electrically conductive coating.