System, method and generator for generating nanobubbles or nanodroplets

The invention claimed is: 1. A method of producing nanobubbles or nanodroplets; the method comprising: providing a volume for accommodating a liquid; distributing a medium within the liquid; generating a static electric field using an electrode in the proximity of the volume, wherein the nanobubbles or nanodroplets are generated as a result of the static electric field being applied to the liquid and the medium; wherein the electrode and the liquid are not in direct electrical contact to prevent electrolysis occurring within the volume. 2. The method of claim 1 ; wherein the medium is a gas medium. 3. The method of claim 2 ; wherein the gas medium comprises: a mixture of two or more gases; or a mixture of two or more gases; wherein at least one of the gases is enriched. 4. The method of claim 1 ; wherein the medium is a liquid medium. 5. The method of claim 4 ; wherein the liquid medium comprises: a mixture of two or more liquid components; or a mixture of two or more liquid components; wherein at least one of the liquids is enriched. 6. The method of claim 1 ; wherein the liquid is an aqueous liquid. 7. The method of claim 1 ; wherein the liquid comprises deionised water. 8. The method of claim 1 ; further comprising applying a cooling means for cooling the contents of the volume. 9. The method of claim 8 ; wherein the cooling means circulates a coolant in the proximity of the volume. 10. The method of claim 1 ; further comprising evacuating the volume. 11. The method of claim 1 ; further comprising agitating the contents of the volume. 12. The method of claim 11 ; wherein the agitating is provided by a rocking motion. 13. The method of claim 1 ; further comprising sensing temperature; and/or sensing pressure. 14. The method of claim 1 ; wherein the volume of liquid is 20 cm 3 . 15. The method of claim 1 ; wherein a pressure of up to 100 bar is applied to the volume. 16. The method of claim 1 ; wherein a DC voltage of 30 V is applied to the electrode. 17. The method of claim 1 ; wherein an acoustic signal is applied for releasing the nanobubbles or nanodroplets from the liquid. 18. The method of claim 1 ; wherein a magnetic signal is applied for releasing the nanobubbles or nanodroplets from the liquid. 19. The method of claim 1 ; wherein the volume is cooled to a predetermined level for facilitating storing the nanobubbles or nanodroplets within the body of the liquid. 20. A generator for producing nanobubbles or nanodroplets; the generator comprising: a volume for accommodating a liquid; a source for supplying a medium to the volume for distributing within the liquid; an electrode for generating a static electric field in the proximity of the volume, wherein the nanobubbles or nanodroplets are generated as a result of the static electric field being applied to the liquid and the medium; wherein the electrode and the liquid are not in direct electrical contact to avoid electrolysis. 21. The generator as claimed in claim 20 ; wherein the source comprises a gas source for supplying a gas medium. 22. The generator as claimed in claim 20 ; wherein the source comprises a liquid source for supplying a liquid medium. 23. The generator as claimed in claim 20 ; wherein the generator further comprises a cooling means for cooling the contents of the volume. 24. The generator as claimed in claim 23 ; wherein the cooling means is configured for circulating a coolant in the proximity of the volume. 25. The generator as claimed in claim 24 , wherein at least a portion of the generator defines a passageway for accommodating the coolant therein. 26. The generator as claimed in claim 20 ; further comprising a vacuum means for evacuating the volume. 27. The generator as claimed in claim 20 ; further comprising an agitating means for agitating the contents of the volume. 28. The generator as claimed in claim 27 ; wherein the agitating means comprises a mechanical agitator. 29. The generator as claimed in claim 20 ; wherein the electrode comprises a cathode and an anode. 30. The generator as claimed in claim 29 ; wherein the cathode and anode are restricted from direct electrical contact with the contents of the volume to prevent electrolysis occurring within the volume. 31. The generator as claimed in claim 30 ; wherein the cathode and anode are coated with an electrically insulating coating. 32. The generator as claimed in claim 30 ; wherein the cathode and anode are arranged in a parallel configuration for providing an electric field with strength inversely proportional to a distance between the cathode and the anode. 33. The generator as claimed in claim 20 ; wherein the electrode comprises a plurality of anodes and a plurality of cathodes. 34. The generator as claimed in claim 33 ; wherein the electrode comprises a mesh configuration. 35. The generator as claimed in claim 33 ; wherein the electrode comprises a plurality of mesh elements. 36. The generator as claimed in claim 33 ; wherein the plurality of anodes and the plurality of cathodes are arranged in parallel configuration. 37. The generator as claimed in claim 35 ; wherein each mesh element comprises an aperture for receiving therein a portion of a delivery mechanism configured for facilitating the distribution of the medium within the volume. 38. The generator as claimed in claim 37 ; wherein the delivery mechanism comprises an elongated tubular member for extending through the apertures of the mesh elements. 39. The generator as claimed in claim 38 ; wherein the tubular member is operably mounted on a base member. 40. The generator as claimed in claim 37 ; wherein the delivery mechanism comprises a plurality of outlets for facilitating the distribution of the medium within the volume. 41. The generator as claimed in claim 40 ; wherein the outlets are dimensioned for accommodating the medium therethrough but preventing an ingress of the liquid from the volume. 42. The generator as claimed in claim 20 ; where the electrode is arranged to consist of a series of concentric elements. 43. The generator as claimed in claim 42 ; where said concentric elements may be configured such that each element consists of a cathode and an anode in contact. 44. The generator as claimed in claim 1 ; further comprising a storage volume for storing the nanobubbles or nanodroplets in a temperature controlled environment. 45. The generator as claimed in claim 44 ; wherein the nanobubbles or nanodroplets are frozen for facilitating storage.