CO2 globular transfer

What is claimed is: 1. A method of promoting droplet transfer of a welding system, comprising: transitioning a waveform between a positive polarity above zero and a negative polarity below zero within a repeated cycle, wherein the cycle includes the following: regulating an output current level of the waveform to a positive polarity background current level to sustain an electric arc between an electrode and a workpiece, producing a molten metal ball on a distal end of the electrode; dropping the output current level below the positive polarity background current level to approximately zero in response to the molten metal ball being produced, shorting to the workpiece and extinguishing the electric arc to allow the molten metal ball to wet into a puddle on the workpiece; automatically further decreasing the output current level into a negative polarity below approximately zero in response to the molten metal ball wetting into the puddle to induce the molten metal ball to pinch off from the distal end of the electrode; increasing the output current level within the negative polarity toward approximately zero as the molten ball pinches off from the distal end of the electrode onto the workpiece to re-establish an electric arc between the electrode and the workpiece; decreasing the output current level within the negative polarity below approximately zero to a negative peak current level of the waveform in response to re-establishing the electric arc; and increasing the output current level above zero to the positive polarity background current level producing a next molten metal ball on the distal end of the electrode; providing at least one heat-increasing current pulse wherein the output current level is between the positive polarity background current level and an intermediate positive current level in the positive polarity at the end of the cycle to maintain a temperature of the puddle, wherein the intermediate positive current level is greater than the positive polarity background current level and less than an absolute value of the negative peak current level re-establishing the arc and a duration of pulsing the output current level is based on a wire feed speed; the combination of steps repeated to promote the droplet transfer of the welding system. 2. The method of claim 1 , wherein the arc welding process is a gas metal arc welding (GMAW) process. 3. The method of claim 2 , wherein the GMAW process uses argon and CO 2 as shielding gases. 4. The method of claim 1 , further comprising heating the electrode more than the puddle with the output current level within the negative polarity. 5. The method of claim 1 , further comprising utilizing the negative peak current level of the waveform to produce the next molten metal ball on the distal end of the electrode. 6. A method of promoting droplet transfer of a welding system, comprising: transitioning a waveform between a positive polarity above zero and a negative polarity below zero within a repeated cycle, wherein the cycle includes the following: regulating an output current level of the waveform to a positive polarity background current level in the positive polarity to sustain an electric arc between an electrode and a workpiece, producing a molten metal ball on a distal end of the electrode; dropping the output current level within the negative polarity to a negative peak current level in response to re-establishing the electric arc; increasing the output current level into the positive polarity toward the positive polarity background current level producing a next molten metal ball on the distal end of the electrode; providing at least one heat-increasing current pulse wherein the output current level is between the positive polarity background current level and an intermediate positive current level in the positive polarity at the end of the cycle to maintain a temperature of the puddle, wherein the intermediate positive current level is greater than the positive polarity background current level and less than an absolute value of the negative peak current level re-establishing the arc and a duration of pulsing the output current level is based on a wire feed speed; the combination of steps repeated to promote the droplet transfer of the welding, system. 7. The method of claim 6 , wherein the arc welding process is a gas metal arc welding (GMAW) process. 8. The method of claim 7 , wherein the GMAW process uses argon and CO 2 as shielding gases. 9. The method of claim 6 , further comprising heating the electrode more than the puddle with the output current level within the negative polarity. 10. The method of claim 6 , further comprising utilizing the output current level within the negative polarity to mitigate depression of the puddle from the molten metal ball pinching off from the distal end of the electrode. 11. A method of promoting droplet transfer of a welding system, comprising: transitioning a waveform between a positive polarity above zero and a negative polarity below zero within a repeated cycle, wherein the cycle includes the following: regulating an output current level of the waveform to a positive polarity background current level to sustain an electric arc between an electrode and a workpiece, producing a molten metal ball on a distal end of the electrode; dropping the output current level below the positive polarity background current level to approximately zero in response to the molten metal ball being produced, shorting to the workpiece and extinguishing the electric arc to allow the molten metal ball to wet into a puddle on the workpiece; automatically further decreasing the output current level into a negative polarity below approximately zero in response to the molten metal ball wetting into the puddle to induce the molten metal ball to pinch off from the distal end of the electrode; increasing the output current level within the negative polarity toward approximately zero as the molten ball pinches off from the distal end of the electrode onto the workpiece to re-establish an electric arc between the electrode and the workpiece; decreasing the output current level within the negative polarity below approximately zero to a negative peak current level of the waveform in response to re-establishing the electric arc; and increasing the output current level above zero to the positive polarity background current level producing a next molten metal ball on the distal end of the electrode, wherein in response to the step of increasing the output current level above zero to the positive polarity background current level producing a next molten metal ball on the distal end of the electrode, a temperature of the puddle is maintained by a current pulse at the end of the cycle, the current pulse comprising at least one of: (a) a positive portion comprising pulsing the output current level between the positive polarity background current level in the positive polarity and an intermediate positive current level in the positive polarity at the end of the cycle, wherein the intermediate positive current level is greater than the positive polarity background current level and less than an absolute value of the negative peak current level and a duration of pulsing the output current level is based on a wire feed speed; (b) a negative portion comprising pulsing the output current level between the positive polarity background current level in the positive polarity and an intermediate negative current level in the negative polarity at the end of the cycle, wherein the intermediate negative current level is less than the positive polarity background current level and less than an absolute value of the ne