Method of manufacturing a multi-layer article

The invention claimed is: 1. A self-supported strip, comprising a fully cured surface coating and a base, wherein said fully cured surface coating in said self-supported strip is a release layer having an outer release surface, the release layer having an average roughness (Ra) of at most 250 nm on the outer release surface; and having a surface energy E 1 on the outer release surface that is greater than a surface energy E 0 on an opposite side of the release layer facing the base; wherein any defects present in the release layer have a decreasing defect density from a side of the release layer which faces the base to an opposite side of the release layer forming the outer release surface. 2. The self-supported strip of claim 1 , wherein the self-supported strip is an intermediate transfer member (ITM) suitable for use in an indirect printing system. 3. The self-supported strip of claim 1 , wherein the outer release surface of the self-supported strip is hydrophobic. 4. The self-supported strip of claim 1 , wherein the outer release surface of the self-supported strip comprises a cured vinyl-functionalized silicone polymer. 5. The self-supported strip of claim 1 , wherein the base includes two or more layers. 6. The self-supported strip of claim 1 , wherein the base includes a fiber reinforcement. 7. The self-supported strip of claim 1 , further including lateral projections to lateral edges of said self-supported strip. 8. The self-supported strip of claim 1 , wherein the base is a flexible base, and wherein said self-supported strip was produced by a method comprising: a. providing a fluid first curable material configured to be at least partially cured by a curing process; b. providing a carrier having a carrier contact surface, said carrier contact surface being wettable by said fluid first curable material, said carrier being configured to maintain structural integrity when subject to said curing process; c. forming a layer of said fluid first curable material on said carrier contact surface, with one side of said layer contacting said carrier contact surface, by applying said fluid first curable material onto said carrier, so that said fluid first curable material wets said carrier contact surface; d. at least partially curing said fluid first curable material to form an at least partially cured surface coating of the self-supported strip; e. securing a flexible base to, or forming a flexible base on, a surface of the at least partially cured surface coating opposite said carrier; and f. peeling said at least partially cured surface coating together with said flexible base from said carrier, wherein said at least partially cured surface coating is post-cured to yield the fully cured surface coating prior to or subsequent to said peeling. 9. The self-supported strip of claim 1 , wherein the outer release surface of the self-supported strip comprises a cured polyurethane polymer. 10. The self-supported strip of claim 1 , wherein the outer release surface of the self-supported strip comprises a cured silicone polymer. 11. A self-supported strip, comprising a fully cured surface coating and a base, wherein said fully cured surface coating in said self-supported strip is a release layer having an outer release surface, the release layer having an average roughness (Ra) of at most 250 nm on the outer release surface; and having a surface energy E 1 on the outer release surface that is greater than a surface energy E 0 on an opposite side of the release layer facing the base; the self-supported strip further including a peelable flexible foil carrier having a carrier contact surface contacting the outer release surface; and wherein any defects present in the release layer have a decreasing defect density from a side of the release layer which faces the base to an opposite side of the release layer forming the outer release surface. 12. The self-supported strip of claim 11 , wherein said Ra is at most 10 nm. 13. The self-supported strip of claim 11 , wherein the carrier contact surface has a surface energy between 20 and 70 mJ/m 2 . 14. The self-supported strip of claim 11 , wherein the carrier contact surface comprises a surface selected from the group consisting of a metal surface and a metal oxide surface, the metal surface or metal oxide surface being part of a metal foil or of a metalized polymer foil. 15. The self-supported strip of claim 11 , wherein the carrier contact surface includes a polymeric surface, comprising, or consisting essentially of, a polymer selected from the group consisting of polyesters, poly-fluorocarbons and polyimides. 16. The self-supported strip of claim 11 , wherein said Ra is at least 3 nm. 17. A self-supported strip, comprising a fully cured surface coating and a base, wherein said fully cured surface coating in said self-supported strip is a release layer having an outer release surface, the release layer having an average roughness (Ra) of at most 250 nm on the outer release surface; and having a surface energy E 1 on the outer release surface that is greater than a surface energy E 0 on an opposite side of the release layer facing the base; wherein said outer release surface is substantially free of defects, wherein said substantially free of defects is quantified by less than 0.01% of said outer release surface being covered by said defects; and wherein any defects present in the release layer have a decreasing defect density from a side of the release layer which faces the base to an opposite side of the release layer forming the outer release surface. 18. The self-supported strip of claim 17 , wherein said Ra is at most 25 nm. 19. The self-supported strip of claim 17 , wherein said Ra is at most 10 nm. 20. The self-supported strip of claim 19 , wherein said Ra is at least 3 nm.