Method and device for forming bundles of nanofilaments

1 . A method, comprising: uniformly arranging nanofilaments ( 2 ) over a surface of an electrically conductive substrate ( 1 ), wherein each of the nanofilaments ( 2 ) has a fixed end connected to the electrically conductive substrate ( 1 ) and a free end; and exposing the nanofilaments ( 2 ) to light from a first light source ( 18 ) of such an intensity that the light causes the respective free ends of a plurality of adjacent nanofilaments ( 2 ) to abut each other so as to form bundles ( 3 ) of nanofilaments ( 2 ), wherein the bundles ( 3 ) are separated from one another by spaces. 2 . The method of claim 1 , wherein the nanofilaments ( 2 ) are carbon nanotubes (CNT). 3 . The method of claim 1 , wherein a cross-sectional distance through one of the bundles ( 3 ) is between 0.5 and 5 μm. 4 . The method of claim 1 , further comprising applying an ion-absorbing coating ( 5 ) to the bundles ( 3 ), the ion-absorbing coating ( 5 ) comprising nanoparticles ( 4 ) that are connected to one another and to the bundles ( 3 ). 5 . The method of claim 4 , wherein the nanoparticles ( 4 ) comprise at least one of silicon, sulfur, titanium oxide, a phosphite, a nitrite, carbon, SiO 2 , TiO 2 , CrO 2 , LiCoO, LiTiO, LiNiO, LiMnO, LiFePO, LiCoPO, LiMnPO, V 2 O 5 , Ge, Sn, Pb or ZnO. 6 . The method of claim 1 , wherein the first light source ( 18 ) comprises a xenon lamp or a laser. 7 . The method of claim 1 , wherein the light from the first light source ( 18 ) comprises a laser beam that is generated continuously or in a pulsed manner and expanded into a strip, the method further comprising moving the laser beam over the nanofilaments ( 2 ) at a constant speed. 8 . The method of claim 4 , further comprising: applying silicon nanoparticles ( 4 ) onto the bundles ( 3 ) during the application of the ion-absorbing coating ( 5 ); and applying energy to the silicon nanoparticles ( 4 ) so as to connect the silicon nanoparticles ( 4 ) to one another and to the bundles ( 3 ). 9 . The method of claim 8 , wherein light from a second light source ( 21 ) is used for connecting the silicon nanoparticles ( 4 ) to one another and to the bundles ( 3 ), the method further comprising moving the light from the second light source ( 21 ) over the surface of the electrically conductive substrate ( 1 ) so as to melt a surface of the silicon nanoparticles ( 4 ). 10 . A device, comprising: a processing device ( 10 ) comprising: a first coating station ( 11 ) configured to form nanofilaments ( 2 ) on a substrate ( 1 ), wherein the substrate ( 1 ) is electrically conductive; and a forming station ( 12 ) arranged directly behind the first coating station ( 11 ) in a transport direction, wherein the forming station ( 12 ) comprises a first light source ( 18 ) for exposing the nanofilaments ( 2 ) on the substrate ( 1 ) to light in such a way that the nanofilaments ( 2 ) combine into bundles ( 3 ) of nanofilaments ( 2 ); an entry arrangement ( 22 ) for supplying the substrate ( 1 ) into the processing device ( 10 ); an exit arrangement ( 23 ) for removing the substrate ( 1 ) from the processing device ( 10 ); and transport means for transporting the substrate ( 1 ) through the processing device ( 10 ) in the transport direction from the entry arrangement ( 22 ) to the exit arrangement ( 23 ). 11 . The device of claim 10 , wherein the processing device ( 10 ) further comprises a second coating station ( 13 ) for applying a coating ( 5 ) on the bundles ( 3 ) formed in the forming station ( 12 ). 12 . The device of claim 10 , further comprising: a first roll ( 7 ) on which a first portion of the substrate ( 1 ) is wound; and a second roll ( 8 ) on which a second portion of the substrate ( 1 ) is wound, wherein the first roll ( 7 ) is disposed upstream from the entry arrangement ( 22 ) with respect to the transport direction, and the second roll ( 8 ) is disposed downstream of the exit arrangement ( 23 ) with respect to the transport direction. 13 . The device of claim 10 , wherein the first light source ( 18 ) comprises a laser. 14 . The device of claim 11 , wherein the second coating station ( 13 ) comprises a spraying device ( 20 ) for spraying nanoparticles ( 4 ) on the bundles ( 3 ) produced in the forming station ( 12 ). 15 . The device of claim 14 , wherein the second coating station ( 13 ) comprises a second light source ( 21 ) for shining light onto the nanoparticles ( 4 ) sprayed on the bundles ( 3 ) so as to connect the nanoparticles ( 4 ) to one another and to the bundles ( 3 ).