Charge pump-based artificial lightning generator and method for manufacturing same

1 . A charge-pump-based artificial lightning generator comprising: a first electrode; a positive charging object spaced apart from the first electrode; a negative charging object spaced apart from the positive charging object in a direction opposite to the first electrode; a second electrode partially contacting the negative charging object; a grounding layer spaced apart from the positive charging object by a certain distance to intermittently contact the positive charging object. 2 . The charge-pump-based artificial lightning generator of claim 1 , wherein, when an external load is applied, negative charges in a lower part of the positive charging object induce positive charges onto a surface of the first electrode and electrons move from the second electrode to the first electrode to generate an output current. 3 - 4 . (canceled) 5 . The charge-pump-based artificial lightning generator of claim 1 , wherein the grounding layer comprises metal, ceramic, or polymer and selectively removes negative charges from the positive charging object due to grounding such that the positive charging object charged with only positive charges accumulates charges in the first electrode due to electrostatic induction. 6 . The charge-pump-based artificial lightning generator of claim 1 , wherein the negative charging object has a nanostructured surface comprising a sponge structure having a plurality of pores of 0.1 μm to 30 μm. 7 . A method of manufacturing a charge-pump-based artificial lightning generator, the method comprising: (a) forming a second electrode on a prepared substrate; (b) forming a negative charging object under the second electrode; (e) forming a positive charging object below the negative charging object at a location spaced apart from the negative charging object by a certain distance, to generate charges; (f) nanostructuring a surface of the positive charging object; (g) coating the nanostructured surface of the positive charging object with second metal particles; (h) forming a grounding layer below a side of the positive charging object while maintaining a certain distance from the positive charging object, to separate charges; and (i) forming a first electrode below the positive charging object at a location spaced apart from the positive charging object by a certain distance, to accumulate charges. 8 . The method of claim 7 , wherein the (b) comprises: (b-1) arranging spherical polymer particles mixed with a liquid; (b-2) removing the liquid by drying the liquid in the air; and (b-3) filling liquid-state negative charges between the spherical polymer particles from which the liquid is removed. 9 . The method of claim 8 , further comprising (c) removing the spherical polymer particles from the negative charging object by using a toluene solution, after (b). 10 . The method of claim 9 , further comprising (d) inserting first metal particles into the negative charging object, after (c). 11 . The method of claim 7 , wherein the (f) comprises: (f-1) forming patterns on a silicon substrate by using photolithography; (f-2) removing an oxide layer by using a buffered oxide etchant (BOE) after the patterns are formed; (f-3) producing a mold having concaved lines, cubes, or pyramids corresponding to the formed patterns, by etching the silicon substrate by using a potassium hydroxide (KOH) solution; (f-4) spin-coating a non-cured silver (Ag)-nanowires-polymer composite on the produced mold; (f-5) removing air bubbles generated due to the spin-coating, in a vacuum state and then curing the Ag-nanowires-polymer composite by exposing the Ag-nanowires-polymer composite to ultraviolet light; and (f-6) removing the cured Ag-nanowires-polymer composite from the mold. 12 . The method of claim 7 , wherein the grounding layer comprises metal, ceramic, or polymer and selectively removes negative charges from the positive charging object due to grounding such that the positive charging object charged with only positive charges accumulates charges in the first electrode due to electrostatic induction. 13 . The method of claim 7 , wherein, when an external load is applied, negative charges in a lower part of the positive charging object induce positive charges onto a surface of the first electrode and electrons move from the second electrode to the first electrode to generate an output current. 14 . The method of claim 7 , wherein first elastic supporters are provided between the first electrode and the positive charging object, and wherein second elastic supporters are provided between the positive charging object and the second electrode. 15 . The method of claim 14 , wherein the first elastic supporters and the second elastic supporters comprise springs having different spring constants k. 16 . The method of claim 7 , wherein the negative charging object has a nanostructured surface comprising a sponge structure having a plurality of pores of 0.1 μm to 30 μm. 17 . A method of manufacturing a negative charging object of a charge-pump-based artificial lightning generator, the method comprising: (A1) mixing spherical polymer particles (e.g., polystyrene, silica, or polymethylmethacrylate (PMMA) particles) with a liquid; (A2) arranging the spherical polymer particles (e.g., polystyrene, silica, or PMMA particles) mixed with the liquid; (A3) removing the liquid by drying the liquid in the air; (A4) mixing liquid-state negative charges with the spherical polymer particles; and (A5) filling the liquid-state negative charges between the spherical polymer particles. 18 . The method of claim 17 , wherein the liquid comprises first metal particles, and wherein the first metal particles are inserted into pores of the negative charging object. 19 . A method of manufacturing a positive charging object of a charge-pump-based artificial lightning generator, the method comprising: (B1) evenly dispersing silver (Ag) nanowires on a flat substrate by using spin coating; (B2) coating an elastic epoxy-based polymer on the dispersed Ag nanowires to form a composite thereof; and (B3) coating second metal particles on top surfaces of the Ag nanowires. 20 . The charge-pump-based artificial lightning generator of claim 1 , further comprising: first elastic supporters provided between the first electrode and the positive charging object; and second elastic supporters provided between the positive charging object and the second electrode. 21 . The charge-pump-based artificial lightning generator of claim 20 , wherein the first elastic supporters and the second elastic supporters comprise springs having different spring constants. 22 . A charge-pump-based artificial lightning generator comprising: a first electrode; a first charging object spaced apart from the first electrode; a second charging object spaced apart from the first charging object in a direction opposite to the first electrode; a second electrode contacting the second charging object; and a grounding layer spaced apart from the first charging object by a certain distance to intermittently contact the first charging object. 23 . The charge-pump-based artificial lightning generator of claim 22 , further comprising: first elastic supporters provided between the first electrode and the first charging object; and second elastic supporters provided between the first charging object and the second electrode. 24 . The charge-pump-based artificial lightni