Flow body for an aircraft with a selectively activatable shock bump

The invention claimed is: 1. A flow body for an aircraft, the flow body comprising an outer skin having a first flow surface, wherein the skin comprises at least one flow influencing section on the first flow surface, the flow influencing section comprising: at least one first layer comprising a first fiber composite material; at least one separator layer; at least one third layer comprising a second fiber composite material; and at least one base layer comprising a third fiber composite material, wherein the at least one first layer, the at least one separator layer and the at least one third layer are arranged upon the at least one base layer in an alternating order, wherein the at least one first layer comprises lithiated carbon fibers embedded into a matrix to form a negative electrode, wherein the at least one third layer comprises carbon fibers with an electrode active material coating to form a positive electrode, wherein the at least one separator layer comprises a non-conductive material for electrically isolating the at least one first layer and the at least one third layer from each other, and wherein the flow influencing section is configured for selectively raising at least a region of the arrangement of first layer, separator layer and third layer from the at least one base layer upon application of a voltage between the first layer and third layer to form a bump on the flow body. 2. The flow body of claim 1 , wherein the flow influencing section has a fixed position on the flow body and is configured to expand upon application of the voltage, such that the flow influencing section buckles away from the at least one base layer. 3. The flow body of claim 1 , wherein the separator layer comprises a glass fiber reinforced plastics material. 4. The flow body of claim 1 , wherein the separator layer comprises carbon fibers having an electrically isolating coating. 5. The flow body of claim 1 , wherein the electrode active material coating comprises LiFePO 4 . 6. The flow body of claim 1 , wherein at least two edges of the flow influencing section that are opposed along an extension direction are fixated to the base layer. 7. The flow body of claim 6 , wherein along the at least two edges, the first, separator and third layers are sewn or stitched to layers underneath before a curing process. 8. The flow body of claim 1 , wherein the first, separator and third layers of the respective flow influencing section are separated from material layers underneath through a friction reducing coating or layer. 9. The flow body of claim 1 , wherein the at least one flow influencing section includes at least two flow influencing sections, which at least partially overlap and which are individually and selectively actuatable to morph the bump from a neutral state to a plurality of different shapes. 10. An aircraft having at least one flow body according to claim 1 . 11. The aircraft of claim 10 , wherein the flow body is at least one of a group of flow bodies, the group comprising: a wing, a vertical tailplane, a horizontal tailplane, at least a part of a blended wing body, a fuselage, and a fairing. 12. The aircraft of claim 10 , further comprising a control system and a voltage source coupled with the control system, wherein the at least one first layer and the at least one third layer are selectively couplable with the voltage source through the control system. 13. The aircraft of claim 12 , wherein the aircraft comprises a velocity sensor, and wherein the control system is coupled with the velocity sensor to selectively apply a voltage to the at least one first layer and the at least one third layer upon reaching or exceeding at least one threshold velocity. 14. A method for producing a flow body for an aircraft, the method comprising: laying at least one base layer onto a surface of a molding tool; creating a flow influencing section on the at least one base layer by laying at least one first layer comprising a first fiber composite material onto the base layer, laying at least one separator layer onto the first layer, laying at least one third layer comprising a second fiber composite material onto the separator layer, and fixing the first layer, the separator layer and the third layer onto the base layer, impregnating the arrangement of layers with a matrix material, and curing or hardening and removing the flow body from the molding tool, wherein the at least one first layer comprises lithiated carbon fibers embedded into a matrix to form a negative electrode, wherein the at least one third layer comprises carbon fibers with an electrode active material coating to form a positive electrode, and wherein the at least one separator layer comprises a non-conductive material for electrically isolating the at least one first layer and the at least one third layer from each other. 15. The method according to claim 14 , wherein the fixing is conducted by stitching or sewing.