A nanostructured surface for grey scale colouring

1 . A nanostructured product with a structurally coloured surface, comprising: a substrate comprising a nanostructured surface, comprising raised or depressed nanostructures, a metal layer at least partially covering the nanostructured surface and at least partially conforming to the nanostructured surface so that the metal layer generates broad band absorbance of light in a visible spectral range, wherein the thickness of the metal layer is in the range from 10-80 nm. 2 - 18 . (canceled) 19 . The nanostructured product according to claim 1 , wherein the product is configured so that the metal layer is a front layer configured to receive incident light. 20 . The nanostructured product according to claim 1 , wherein the product is configured so that the substrate is a front layer configured to receive incident light. 21 . The nanostructured product according to claim 1 , wherein the substrate is opaque to visible light. 22 . The nanostructured product according to claim 1 , wherein the substrate is an oxide layer on a metal. 23 . The nanostructured product according to claim 1 , wherein the average broad band absorption of light in a visible spectral range is greater than 20 percent in average over the visible spectral range. 24 . A nanostructured product according to claim 1 , wherein the metal layer on the nanostructured surface has a reflectance of light in a visible spectral range which is less than percent in average over the visible spectral range. 25 . The nanostructured product according to claim 1 , where the metal layer conforms to the nanostructured surface so that the metal layer comprises a nanostructured surface comprising raised or depressed structures. 26 . The nanostructured product according to claim 25 , wherein the raised or depressed nanostructures of the substrate projects from a base plane, so that the raised or depressed nanostructures of the conforming metal layer also projects from a base plane of the metal layer, and wherein the coverage of the raised or depressed structures of the metal layer relative to the base plane of the metal layer is greater than 30 percent. 27 . The nanostructured product according to claim 1 , wherein the substrate further comprises a scattering surface. 28 . The nanostructured product according to claim 27 , wherein the scattering surface comprises structures having dimensions which are large enough to scatter incoming visible light. 29 . The nanostructured product according to claim 27 , wherein the scattering surface is located adjacent to nanostructured surface. 30 . The nanostructured product according to claim 27 , wherein the substrate comprises a plurality of the scattering surfaces and a plurality the nanostructured surfaces arranged in a pattern with alternating scattering surfaces and nanostructured surfaces. 31 . The nanostructured product according to claim 27 , wherein the substrate further comprises a non-structured surface covered by the metal layer. 32 . The nanostructured product according to claim 27 , wherein the substrate is a foil, wherein the metal layer is located on a back face of the foil, and wherein the back face is configured to be connected to an object. 33 . The nanostructured product according to claim 1 , wherein the metal layer is covered with a protective transparent layer. 34 . A display comprising: the nanostructured product according to claim 1 , and a light source arranged to emit light towards the nanostructured product. 35 . A process for manufacturing the nanostructured product according to claim 1 , comprising: forming a plastic object by moulding or embossing by use of a mould or embossing tool, wherein a surface of the mould or embossing tool is provided with a nanostructured surface, so that the forming creates a nanostructured surface of the plastic object, and covering the nanostructured surface of the plastic object with a metal layer so that the metal layer at least partially covers the nanostructured surface and at least partially conforms to the nanostructured surface so that the metal layer generates broad band absorption of light in a visible spectral range, where the thickness of the metal layer is in the range from 10-80 nm.