Dielectric barrier discharge plasma method and apparatus for synthesizing metal particles

1 . A method for synthesizing metal particles, comprising: providing a dielectric barrier discharge (DBD) plasma apparatus, the DBD plasma apparatus comprising an electrolyte vessel, an electrode spaced-apart from the electrolyte vessel, and a dielectric barrier interposed between the electrolyte vessel and the electrode; introducing an electrolyte solution comprising metal ions inside the electrolyte vessel, the electrolyte solution having an upper surface spaced-apart from the dielectric barrier; supplying gas into a discharge area extending between the upper surface of the electrolyte solution and the dielectric barrier; and applying an alternating or pulsed direct electrical potential difference between the electrode and the electrolyte solution, an amplitude of the electrical potential difference being sufficient to produce a plasma onto the electrolyte solution so as to interact with the metal ions and thereby synthesize the metal particles. 2 . The method according to claim 1 , wherein supplying gas comprises continuously supplying the gas into the discharge area and evacuating gas therefrom. 3 . The method according to claim 1 , wherein the introducing step further comprises conveying a flow of the electrolyte solution at least one time along an electrolyte flow path from an electrolyte inlet port to an electrolyte outlet port of the electrolyte vessel. 4 - 6 . (canceled) 7 . The method according to claim 1 , further comprising cooling the electrode. 8 . The method according to claim 1 , wherein the electrode is a liquid electrode contained in an electrode cell, the method further comprising: continuously conveying a liquid of the liquid electrode in the electrode cell, and evacuating heat from the DBD plasma apparatus through the continuously conveyed liquid of the liquid electrode. 9 . (canceled) 10 . The method according to claim 8 , wherein at least a surface of the electrode cell is the dielectric barrier. 11 - 13 . (canceled) 14 . The method according to claim 1 , further comprising at least one of: monitoring and controlling a vertical gap between the upper surface of the electrolyte solution contained inside the electrolyte vessel and the dielectric barrier; monitoring a temperature of the electrolyte solution inside the electrolyte vessel and controlling the temperature of the electrolyte solution between about 0° C. and about 95° C.; and monitoring in real-time a spectral response of the synthesized metal particles. 15 - 26 . (canceled) 27 . The method according to claim 1 , wherein an electrical conduction of the electrolyte solution is sufficiently high to act as a counter-electrode, the method further comprising grounding the electrolyte solution. 28 - 30 . (canceled) 31 . The method according to claim 1 , wherein the synthesized metal particles comprise Au, Pd, Pt, Ir, Os, Re, Ru, Rh, Ag, Ni, Cu, Fe, Mn, Co, or mixtures thereof. 32 . The method according to claim 1 , wherein the metal ions comprise noble metal ions, transition metal ions, or mixtures thereof. 33 - 35 . (canceled) 36 . A dielectric barrier discharge (DBD) plasma apparatus for synthesizing metal particles, the DBD plasma apparatus comprising: an electrolyte vessel for receiving an electrolyte solution comprising metal ions; an electrode spaced-apart from the electrolyte vessel; a dielectric barrier interposed between the electrolyte vessel and the electrode such that, when the electrolyte solution is present in the electrolyte vessel in a synthesis region thereof, the dielectric barrier and an upper surface of the electrolyte solution in the synthesis region are spaced-apart from each other and define a discharge area therebetween; and at least one gas inlet port and at least one outlet port in fluid communication with the discharge area such that, when the electrolyte solution is present in the electrolyte vessel, supplying gas in the discharge area while applying an alternating or pulsed direct electrical potential difference between the electrode and the electrolyte solution cause a plasma to be produced onto the electrolyte solution so as to interact with the metal ions and thereby synthesize the metal particles. 37 . The DBD plasma apparatus according to claim 36 , wherein the upper surface of the electrolyte solution and the dielectric barrier extend parallel to and are separated from each other by a vertical gap when the electrolyte solution is contained in the electrolyte vessel, the vertical gap having a height of about 1 mm to about 10 mm. 38 - 45 . (canceled) 46 . The DBD plasma apparatus according to claim 36 , wherein the electrode is a liquid-based electrode comprising an electrically conductive liquid contained in at least one liquid containable cell. 47 . (canceled) 48 . (canceled) 49 . The DBD plasma apparatus according to claim 46 , wherein the dielectric barrier is a bottom surface of the at least one liquid-containable cell. 50 - 55 . (canceled) 56 . The DBD plasma apparatus according to claim 49 , wherein the liquid-based electrode further comprises at least one electrically-conducting element connectable to an electrical alternating power source to create the alternating or pulsed direct electrical potential difference, each one of the at least one electrically-conducting element being inserted in a respective one of the at least one liquid-containable cell. 57 - 59 . (canceled) 60 . The DBD plasma apparatus according to claim 36 , further comprising a ground for grounding the electrolyte solution contained in the electrolyte vessel. 61 . The DBD plasma apparatus according to claim 36 , comprising a housing including a base and a removable mating cover, the base defining an electrolyte vessel receiving cavity and the electrolyte vessel being removably insertable in the electrolyte vessel receiving cavity of the housing, and wherein the at least one gas inlet port and the at least one gas outlet port extend through the housing and are in gas communication with the discharge area. 62 . (canceled) 63 . (canceled) 64 . The DBD plasma apparatus according to claim 36 , further comprising a lower liquid electrode extending below the synthesis region of the electrolyte vessel. 65 . (canceled) 66 . (canceled) 67 . The DBD plasma apparatus according to claim 64 , wherein the lower liquid electrode is separated by a dielectric barrier from the synthesis region of the electrolyte vessel and the lower liquid electrode is in fluid communication with a cooling liquid supply through an electrode chamber inlet port. 68 - 82 . (canceled) 83 . The DBD plasma apparatus according to claim 36 , further comprising at least one of: a temperature control device including at least one temperature probe configured to monitor an electrolyte temperature, at least one of the temperature probe including a metal cladding in contact with the electrolyte contained in the electrolyte vessel and electrically grounding same to earth; and a spectroscopy cell in fluid communication with the electrolyte vessel, mounted downstream of the electrolyte output port. 84 . (canceled) 85 . (canceled) 86 . The DBD plasma apparat