Surface activation in electrode stack production and electrode-preparation systems and methods

The invention claimed is: 1. A method comprising: surface treating at least one cell separator prior to attachment to at least one electrode, wherein the surface treating is configured to form binding sites on the at least one cell separator, and attaching the at least one cell separator to the at least one electrode by cold press lamination, wherein the created binding sites are configured to stabilize the cold press lamination electrostatically. 2. The method of claim 1 , further comprising applying the surface treatment to both sides of the at least one cell separator and wherein the at least one electrode comprises, for each of the at least one cell separator, an anode attached to one side of the separator and a cathode attached to another side of the separator. 3. The method of claim 2 , wherein both anode and cathode are attached to the separator simultaneously. 4. The method of claim 2 , further comprising assembling a cell stack by performing the attachment to a plurality of cell separator and a corresponding plurality of alternating anodes and cathodes. 5. A flexible battery comprising the assembled cell stack prepared by the method of claim 4 . 6. The method of claim 1 , wherein the cold press lamination is carried out below 60° C. and/or below 40 and/or at room temperatures. 7. The method of claim 1 , wherein the surface treatment is carried out by any of plasma treatment, corona treatment, ultraviolet radiation. 8. The method of claim 1 , wherein the surface treatment is carried out by depositing an ionic-conductive surface layer to form the binding sites. 9. The method of claim 1 , wherein the at least one cell separator is polymeric and the surface treatment comprises depositing a ceramic surface layer onto the polymeric at least one cell separator. 10. The method of claim 1 , wherein the at least one electrode comprises attached corresponding at least one current collector film. 11. The method of claim 10 , wherein the at least one electrode is attached to the corresponding at least one current collector film by a conductive adhesive. 12. The method of claim 1 , wherein the attaching is carried out using a sacrificial film onto which at least one of: at least one cell separator and the at least one electrode, are deposited as corresponding slurry. 13. The method of claim 1 , further comprising pressing the at least one electrode face-to-face against another electrode prior to the attaching of the at least one cell separator. 14. The method of claim 1 , wherein the attaching is carried out by at least one of: single sheet stacking, winding, Z-folding with single electrodes and Z-folding with electrode rolls. 15. The method of claim 1 , further comprising: prior to the surface treatment, depositing a cell separator slurry on a sacrificial film to form a cell separator thereupon, and following the surface treatment: attaching the formed cell separator onto the at least one electrode attached to at least one corresponding current collector film, to yield a stack, wherein a binding strength of the cell separator to the electrode is higher than a binding strength of the cell separator to the sacrificial film, and delaminating the sacrificial film from the separator while maintaining the attachments of the separator to the electrode and of the electrode to the current collector film. 16. The method of claim 15 , further comprising preparing the at least one electrode attached to the at least one corresponding current collector film by: depositing an electrode slurry on a sacrificial film to form the at least one electrode thereupon, wherein the electrode slurry comprises a first solvent, attaching a current collector film, which is produced using a second solvent, onto the formed electrode, to yield a stack, wherein a binding strength of the electrode to the current collector film is higher than a binding strength of the electrode to the sacrificial film, and delaminating the sacrificial film from the electrode while maintaining the attachment of the electrode to the current collector film. 17. The method of claim 16 , further comprising: pressing at least two double-sided coated current collector foils between external coated foils, wherein the coatings on the double-sided foils comprise the electrode slurry and face each other and the coatings of the respective external foils, and are pressed against each other, and preparing the electrodes from at least one of the pressed double-sided coated current collector foils. 18. The method of claim 16 , further comprising preparing the at least one electrode attached to the at least one corresponding current collector film by: pressing at least two double-sided coated current collector foils between external coated foils, wherein the coatings on the double-sided foils comprise electrode slurry and face each other and the coatings of the respective external foils, and are pressed against each other, and preparing electrodes from at least one of the pressed double-sided coated current collector foils. 19. A cell stack assembly system comprising: a surface treatment module configured to treat both surfaces of each of a plurality of cell separators, to form binding sites thereupon, a stacking module configured to stack a plurality of alternating anodes and cathodes between the cell separators, and a cold-press lamination module configured to cold-press the stack, wherein the formed binding sites are configured to stabilize the cold-pressed stack electrostatically. 20. The cell stack assembly system of claim 19 , further comprising at least one of: a layer transfer module configured to prepare the at least one electrode attached to at least one corresponding current collector film by depositing an electrode slurry on a sacrificial film to form the at least one electrode thereupon, wherein the electrode slurry comprises a first solvent; attaching a current collector film, which is produced using a second solvent, onto the formed electrode, wherein a binding strength of the electrode to the current collector film is higher than a binding strength of the electrode to the sacrificial film; and delaminating the sacrificial film from the electrode while maintaining the attachment of the electrode to the current collector film, and a calendaring unit comprising two pressure-applying apparatuses facing each other and configured to receive and press, against each other, at least two double-sided coated current collector foils between external coated foils, wherein the coatings on the double-sided foils face each other and the coatings of the respective external foils, and are pressed against each other, and wherein the two pressure-applying apparatuses are configured to apply pressure on the external coated foils. 21. A cell stack for lithium ion batteries, the cell stack comprising a plurality of anodes and cathodes, separated by a plurality of cell separators, wherein at least one of the anodes, the cathodes and the cell separators are surface treated to form binding sites upon surfaces thereof, and wherein the anodes, the cathodes and the cell separators are attached by cold press lamination, electrostatically stabilized by the created binding sites. 22. A method comprising: surface treating, prior to stack lamination, at least one cell separator and/or at least one electrode, wherein the surface treating is configured to form binding sites on the at least one cell separator and/or at least one electrode, respectiv