Resistance welding electrode and method of resistance welding

The invention claimed is: 1. A method of resistance spot welding a workpiece stack-up assembly that includes an aluminum workpiece and an overlapping adjacent steel workpiece, the method comprising: providing a workpiece stack-up assembly that has a first side and an opposed second side, the workpiece stack-up assembly including an aluminum workpiece and an adjacent steel workpiece that overlaps the aluminum workpiece, and further including an intermediate organic material layer disposed between confronting faying surfaces of the overlapping aluminum and steel workpieces, wherein the aluminum workpiece is proximate the first side of the stack-up assembly and the steel workpiece is proximate the second side of the stack-up assembly; pressing a weld face of a radially slotted welding electrode against the first side of the workpiece stack-up assembly, the weld face of the radially slotted welding electrode including a central upstanding plateau and a convex dome portion that surrounds the central upstanding plateau and which includes a plurality of trapezoidal weld face sections that are circumferentially spaced on a base surface of the convex dome portion around the central upstanding plateau, each of the trapezoidal weld face sections including a plurality of transverse upstanding arcuate ridges that are radially spaced apart along the base surface of the convex dome portion, and, wherein, an annular channel surrounds the central upstanding plateau and a plurality of radial slots communicate with the annular channel and extend outwardly towards an outer circumference of the base surface between the trapezoidal weld face sections; pressing a weld face of a second welding electrode against the second side of the workpiece stack-up assembly, the weld face of the second welding electrode being facially aligned with the weld face of the radially slotted welding electrode when the weld faces of the radially slotted and second welding electrodes are pressed against their respective first and second sides of the workpiece stack-up assembly; passing an electrical current between the weld face of the radially slotted welding electrode and the weld face of the second welding electrode to create a molten weld pool contained within the aluminum workpiece, the molten weld pool wetting the faying surface of the steel workpiece; and terminating passage of the electrical current between the weld face of the radially slotted welding electrode and the weld face of the second welding electrode to allow the molten weld pool to solidify into a weld joint that bonds the aluminum and steel workpieces together. 2. The method set forth in claim 1 , wherein the first side of the workpiece stack-up assembly is an outer surface of the aluminum workpiece and the second side of the workpiece stack-up assembly is an outer surface of the steel workpiece. 3. The method set forth in claim 1 , wherein the workpiece stack-up assembly includes an additional aluminum workpiece and/or an additional steel workpiece in addition to the aluminum and steel workpieces that overlap and are adjacent to one another. 4. The method set forth in claim 1 , wherein, during pressing of the weld face of the radially slotted welding electrode against the first side of the workpiece stack-up assembly, a plateau surface of the central upstanding plateau contacts the first side of the stack-up assembly before any of the transverse upstanding arcuate ridges included in the plurality of trapezoidal weld face sections contacts the first side such that a clamping load applied by the weld faces of the radially slotted and second welding electrodes is initially transferred through the central upstanding plateau. 5. The method set forth in claim 4 , wherein, prior to passage of the electrical current, only the plateau surface of the central upstanding plateau contacts the first side of the workpiece stack-up assembly, and wherein, during passage of the electrical current, the trapezoidal weld face sections of the convex dome portion that surrounds the central upstanding plateau progressively come into contact with the first side of the workpiece stack-up assembly starting with innermost upstanding arcuate ridges of the trapezoidal weld face sections and continuing radially outwards towards outermost upstanding arcuate ridges of the trapezoidal weld face sections. 6. The method set forth in claim 1 , wherein the weld face of the second welding electrode includes a convex base weld face surface and a plurality of upstanding circular ridges that project outwardly from the convex base weld face surface such that the upstanding circular ridges are separated by intervening circular portions of the convex base weld face surface. 7. The method set forth in claim 6 , wherein a diameter of an innermost upstanding circular ridge of the weld face of the second welding electrode is smaller than a diameter of the plateau surface of the central upstanding plateau of the weld face of the radially slotted welding electrode. 8. A welding electrode comprising: a body; and a weld face carried by one end of the body, the weld face comprising a central upstanding plateau, having a plateau surface, and a convex dome portion surrounding the central upstanding plateau, the convex dome portion further comprising a base surface and a plurality of trapezoidal weld face sections that are circumferentially spaced on the base surface around the central upstanding plateau, each of the trapezoidal weld face sections including a plurality of transverse upstanding arcuate ridges that are radially spaced apart along the base surface of the convex dome portion; wherein a plurality of radial slots communicates with an annular channel that surrounds the central upstanding plateau and extends outwardly towards an outer circumference of the base surface of the convex dome portion, each of the plurality of radial slots extending between two adjacent trapezoidal weld face sections. 9. The welding electrode set forth in claim 8 , wherein each of the trapezoidal weld face sections includes two to ten transverse upstanding arcuate ridges, and wherein each of the transverse upstanding arcuate ridges in each of the trapezoidal weld face sections has a ridge height that ranges from 20 μm to 400 μm and is separated from each of its adjacent ridges by a radial spacing of 50 μm to 1800 μm. 10. The welding electrode set forth in claim 8 , wherein the plateau surface of the central upstanding plateau is positively displaced above the surrounding base weld face surface of the convex dome portion such that the plateau surface is raised above an innermost transverse upstanding arcuate ridge of each of the plurality of trapezoidal weld face sections.