Molecular machine

1 . A molecular machine, comprising a movement part ( 2 ) including: a first molecular element ( 4 ), a second molecular element ( 5 ), and a linking element ( 6 ) for constraining a relative movement of the first molecular element ( 4 ) and the second molecular element ( 5 ), and a control part ( 3 ) configured to generate an electrical field around the movement part ( 2 ), wherein the first molecular element ( 4 ) is fixed relative to the control part ( 3 ), wherein the second molecular element ( 5 ) is movable relative to the first molecular element ( 4 ) in at least one degree of freedom, and wherein the second molecular element ( 5 ) is electrically charged such that the second molecular element ( 5 ) aligns to said electrical field. 2 . The molecular machine of claim 1 , wherein the control part ( 3 ) comprises a fluidic channel ( 9 , 10 ), in which the movement part ( 2 ) is provided, wherein the control part ( 3 ) has an electrical device ( 7 , 8 ) that includes electrodes (H) for creating the electrical field, and wherein the electrodes are connected to the fluidic channel ( 9 , 10 ). 3 . The molecular machine of claim 2 , wherein the control part ( 3 ) comprises at least two electrical devices ( 7 , 8 ) and fluidic channels ( 9 , 10 ) with different orientations to create at least two independent overlaying electrical fields. 4 . The molecular machine of claim 2 , wherein the first molecular element ( 4 ) is fixed to the fluidic channel ( 9 , 10 ). 5 . The molecular machine of claim 2 , wherein the electrical device ( 7 , 8 ) includes an isolating element ( 13 ) configured to isolate the electrodes ( 11 ) from the movement part ( 2 ). 6 . The molecular machine of claim 1 wherein the linking element ( 6 ) is part of the first molecular element ( 4 ) or the second molecular element ( 5 ). 7 . The molecular machine of claim L wherein at least one of the first molecular element ( 4 ), the second molecular element ( 5 ), and the linking element ( 6 ) are biomolecules. 8 . The molecular machine of claim 1 , wherein the first molecular element ( 4 ) is a platform, wherein the second molecular element ( 5 ) is a positioning arm, and wherein the linking element ( 6 ) constrains all relative movement of the first molecular element ( 4 ) and the second molecular element ( 5 ) except of a rotation of the second molecular element ( 5 ) within a plane parallel to the first molecular element ( 4 ). 9 . The molecular machine of claim 1 , wherein fluctuations of at least one of the first molecular element ( 4 ) and the second molecular element ( 5 ) due to diffusion are within a tolerance of at most 10 nm. 10 . The molecular machine of claim 1 , wherein any dimension of the first molecular element ( 4 ) and the second molecular element ( 5 ) is less than 1000 nm. 11 . The molecular machine of claim L wherein the first molecular element ( 4 ) is made from a crossed two-layer scaffold routing, in which a top layer is rotated with respect to a bottom layer by an angle between 80° and 100°. 12 . The molecular machine of claim 1 , wherein the second molecular element ( 5 ) is made from a DNA six-helix bundle. 13 . The molecular machine of claim 1 , wherein the linking element ( 6 ) is created by two adjacent scaffold crossovers with three and four unpaired bases. 14 . The molecular machine of claim 1 , wherein the second molecular element ( 5 ) is adapted to transport inorganic nanoparticles. 15 . The molecular machine of claim 3 , wherein the fluidic channels ( 9 , 10 ) are arranged to intersect at an intersection area ( 12 ), and the movement part ( 2 ) is placed at the intersection area ( 12 ). 16 . The molecular machine of claim 7 , wherein at least one of the first molecular element ( 4 ), the second molecular element ( 5 ), and the linking element ( 6 ), are made of at least one of DNA, DNA-origami, RNA, protein, and artificial charged supramolecular structures. 17 . The molecular machine of claim 9 , wherein fluctuations of at least one of the first molecular element ( 4 ) and the second molecular element ( 5 ) due to diffusion are within a tolerance of at most 1 nm. 18 . The molecular machine of claim 9 , wherein fluctuations of at least one of the first molecular element ( 4 ) and the second molecular element ( 5 ) due to diffusion are within a tolerance of at most 0.5 nm. 19 . The molecular machine of claim 11 , wherein the top layer is rotated with respect to a bottom layer by an angle of 90°.