Current schedule for optimized reaction metallurgical joining

1 . A method of joining a first metal workpiece substrate and a second metal workpiece substrate by way of reaction metallurgical joining, the method comprising: providing a first metal workpiece substrate and a second metal workpiece substrate, the first and second metal workpiece substrates being stacked in overlapping fashion such that a faying surface of the first metal workpiece substrate confronts a faying surface of the second metal workpiece substrate, and wherein a reaction material is disposed between the faying surface of the first metal workpiece substrate and the faying surface of the second metal workpiece substrate at a joining location, the reaction material having a liquidus temperature below both a solidus temperature of the first metal workpiece substrate and a solidus temperature of the second metal workpiece substrate; passing a pulsating DC electrical current through the reaction material to resistively heat the reaction material and cause the reaction material to at least partially melt into a molten reaction material that contacts both the faying surface of the first metal workpiece substrate and the faying surface of the second metal workpiece substrate, neither the first metal workpiece substrate nor the second metal workpiece substrate being melted during passage of the pulsating DC electrical current; and pressing the first and second metal workpiece substrates together while the molten reaction material is present between the faying surfaces of the first and second metal workpiece substrates, the passing of the pulsating DC electrical current and the pressing together of the first and second metal workpiece substrates resulting in formation of a solid-state metallurgical joint between the faying surfaces of the first and second workpiece substrates. 2 . The method set forth in claim 1 , wherein the first metal workpiece substrate is composed of copper or a copper alloy, and wherein the second metal workpiece substrate is composed of copper or a copper alloy. 3 . The method set forth in claim 2 , wherein the reaction material is a self-fluxing copper-based reaction material alloy. 4 . The method set forth in claim 3 , wherein the reaction material comprises a Cu—Ag—P reaction material alloy. 5 . The method set forth in claim 1 , wherein the step of pressing the first and second metal workpiece substrates together comprises: contacting the first metal workpiece substrate with a first electrode and contacting the second metal workpiece substrate with a second electrode, the first and second electrodes being axially facially aligned with each other at the joining location; and applying a compressive force to the first and second metal workpiece substrates through the application of pressure by the first electrode and the second electrode on the first metal workpiece substrate and the second metal workpiece substrate, respectively. 6 . The method set forth in claim 1 , wherein the pulsating DC electrical current comprises a plurality of current pulses, each of which has a maximum attained current level, and wherein the plurality of electrical current pulses generally increase in applied current level such that at least 75% of the maximum attained current levels are contained within an amperage band defined by an upper amperage limit and a lower amperage limit, the upper amperage limit and the lower amperage limit having positive linear slopes and being parallel to each other so as to provide the amperage band with a bandwidth of between 2 kA and 6 kA. 7 . The method set forth in claim 6 , wherein 100% of the maximum attained current levels are contained within the amperage band. 8 . The method set forth in claim 7 , wherein each of the plurality of electrical current pulses has a starting current level and an ending current level, and wherein the starting current level and the ending current level of each electrical current pulse are below the amperage band. 9 . The method set forth in claim 6 , wherein each of the plurality of electrical current pulses has an amplitude, and wherein the amplitudes of the plurality of electrical current pulses generally increase with time. 10 . A method of joining a first metal workpiece substrate and a second metal workpiece substrate by way of reaction metallurgical joining, the method comprising: stacking a first metal workpiece substrate and a second metal workpiece substrate such that a faying surface of the first metal workpiece substrate confronts a faying surface of the second metal workpiece substrate, and wherein a reaction material having a liquidus temperature below both a solidus temperature of the first metal workpiece substrate and a solidus temperature of the second metal workpiece substrate is disposed between the faying surfaces of the first and second metal workpiece substrates; passing a pulsating DC electrical current through the reaction material to resistively heat the reaction material to a temperature above a solidus temperature of the reaction material yet below the solidus temperature of the first metal workpiece substrate and the solidus temperature of the second metal workpiece substrate, the pulsating DC electrical current comprising a plurality of electrical current pulses, each of which has a maximum attained current level, and wherein the plurality of electrical current pulses generally increase in applied current level such that at least 75% of the maximum attained current levels are contained within an amperage band defined by an upper amperage limit and a lower amperage limit, the upper amperage limit and the lower amperage limit having positive linear slopes and being parallel to each other so as to provide the amperage band with a bandwidth of between 2 kA and 6 kA; and pressing the first and second metal workpiece substrates together at least during passage of the pulsating DC electrical current to form a solid-state metallurgical joint between the faying surface of the first metal workpiece substrate and the faying surface of the second metal workpiece substrate. 11 . The method set forth in claim 10 , wherein the first metal workpiece substrate is composed of copper or a copper alloy, and wherein the second metal workpiece substrate is composed of copper or a copper alloy. 12 . The method set forth in claim 11 , wherein the reaction material comprises a Cu—Ag—P reaction material alloy. 13 . The method set forth in claim 10 , wherein the step of pressing the first and second metal workpiece substrates together comprises: contacting the first metal workpiece substrate with a first electrode and contacting the second metal workpiece substrate with a second electrode, the first and second electrodes being axially facially aligned with each other at the joining location; and applying a compressive force to the first and second metal workpiece substrates through the application of pressure by the first electrode and the second electrode on the first metal workpiece substrate and the second metal workpiece substrate, respectively. 14 . The method set forth in claim 10 , wherein 100% of the maximum attained current levels are contained within the amperage band. 15 . The method set forth in claim 10 , wherein each of the plurality of electrical current pulses has an amplitude, and wherein the amplitudes of the plurality of electrical current pulses generally increase with time. 16 . A method of joining a first metal workpiece substrate and a second metal workpiece substrate by way of reaction metallurgical joining, the method comprising: stacking a first metal workpiece substrate and a second metal w