Plasma bipolar forceps

What is claimed is: 1. An electrosurgical bipolar forceps for use with an electrosurgical controller, said controller comprising a plurality of energy delivery modes including an ablation mode that comprises a plasma and a coagulation mode, said forceps comprising: a first leg and a second leg, each leg having a proximal and distal end portion and a respective leg length therebetween, wherein the first leg comprises an active electrode; wherein the second leg comprises a return electrode; wherein the first leg and second leg lengths are configured to move relative to each other upon application of pressure on an outer surface of each of the first and second leg lengths so as to move the first and second legs between an open first position and a closed second position; and wherein the active electrode and the return electrode are electrically connected to an electrical first lead and a second lead respectively for delivering electrosurgical energy to tissue adjacent to one of the first leg or the second leg; and wherein the forceps further comprise a fluid delivery element having a delivery aperture disposed adjacent the active and return electrode and a fluid aspiration element having an aspiration aperture disposed distal to both the active and return electrode and spaced away from the delivery aperture, the fluid delivery and aspiration elements configured so that fluid flowing from the fluid delivery aperture is drawn by suction induced from the aspiration aperture, distally along an elongate gap defined by the active and return electrodes, so as to improve plasma formation. 2. The forceps of claim 1 , wherein the elongate gap defines a first distance when the legs are in the first position, and wherein the elongate gap defines a second distance when the legs are in the second position, and the second distance is substantially less than the first distance. 3. The forceps of claim 2 , wherein the second distance ranges from 0.02 to 0.05 inches. 4. The forceps of claim 2 , further comprising a latch mechanism for retaining the first and second legs in one of the first and second positions. 5. The forceps of claim 4 , wherein the latch mechanism comprises a pin, and a detent, and wherein the pin is disposed on one of the first leg and the second leg, and the detent is disposed on the leg opposite the leg having the pin. 6. The forceps of claim 5 , wherein the detent comprises a first track and a second track, the second track having a different shaped path than the first track. 7. The forceps of claim 6 , wherein the pin comprises a first follower arm, and the first track is configured to receive and guide the first follower arm when the pin is pushed towards the detent. 8. The forceps of claim 7 , wherein the pin comprises a second follower arm, and the second track is configured to receive and guide the second follower arm when the pin is pushed towards the detent. 9. The forceps of claim 8 , wherein the pin comprises a spring-like property such that when the first follower arm and second follower arm are axially unaligned, a tension is created in the pin to urge the pin to return to a neutral configuration wherein the first follower arm and second follower arm are axially aligned. 10. The forceps of claim 1 , wherein the fluid delivery element comprises a first tubular member that extends along an inner surface of the first leg. 11. The forceps of claim 1 , wherein the fluid aspiration element is a second tubular member that defines a portion of the second leg length and the return electrode. 12. The forceps of claim 1 , wherein the fluid delivery element and the fluid aspiration element are configured to flow a fluid through their respective apertures at a defined rate, and wherein the aspiration and delivery apertures and the defined flow rate are configured so as to promote and maintain a meniscus along the elongate gap between the active electrode and return electrode. 13. The forceps of claim 12 , wherein the active electrode and the return electrode form an angle when the forceps is in the second position, and wherein the angle ranges from 0 to 30 degrees. 14. The forceps of claim 1 , wherein the active electrode has a different shape than the return electrode. 15. The forceps of claim 1 , wherein the active electrode tapers to a sharp point. 16. The forceps of claim 1 , wherein when the first leg and second leg are in the closed second position, the active electrode and the return electrode are spaced apart a distance configured to improve plasma formation without permitting arcing. 17. The forceps of claim 1 wherein the active electrode is shaped to electrosurgically dissect or ablate the tissue adjacent the first leg or the second leg when the controller is in the ablation mode and the forceps are in the closed second position; and wherein the active and return electrodes are shaped to provide hemostasis or coagulation to tissue adjacent the first leg or the second leg when the controller is in the coagulation mode and the forceps are in the first open position or an intermediate position between the closed second position and the first open position. 18. An electrosurgical bipolar forceps for use with an electrosurgical controller, comprising: a first leg and a second leg, each leg having a proximal and distal end portion and a respective leg length therebetween, wherein the first leg distal end portion comprises an active electrode; wherein the second leg distal end portion comprises a return electrode; wherein the first leg and second leg lengths are configured to move relative to each other upon application of pressure on an outer surface of each of the first and second leg lengths so as to move the first and second legs between an open first position and a closed second position; and wherein the active electrode and the return electrode are electrically connected to an electrical first lead and a second lead respectively for delivering electrosurgical energy to tissue adjacent to one of the first leg or the second leg; and wherein the forceps comprise a fluid aspiration element associated with at least one of the legs having an aspiration aperture disposed distal to both the active and return electrode, configured such that fluid is drawn distally along an elongate gap having a length defined by both the active and return electrodes before being aspirated through the aspiration aperture; wherein the fluid is drawn distally at a rate configured to improve the wetting of the active and return electrode with an electrically conductive fluid delivered adjacent the distal end portions, configured to enable more uniform ionized gas formation along the elongate gap when the forceps are in the closed position. 19. An electrosurgical bipolar forceps for use with an electrosurgical controller, comprising: a first leg and a second leg, each leg having a proximal and distal end portion and a respective leg length therebetween, wherein the first leg distal end portion comprises an active electrode; wherein the second leg distal end portion comprises a return electrode; wherein the first leg and second leg lengths are configured to move relative to each other between an open first position and a closed second position; and wherein the active electrode and the return electrode are electrically connected to an electrical first lead and a second lead respectively for delivering electrosurgical energy to tissue adjacent to one of the first leg or the second leg; and wherein the forceps comprise a fluid delivery element a