Second-order optical nonlinear material

1 . Second-order optical nonlinear material arranged on a substrate, wherein the second-order optical nonlinear material comprises at least two different materials arranged in layers on the substrate, the layers are arranged on each other in a predetermined order based on the type of material and/or orientation of the layer, and the predetermined order is chosen so that the layers of the at least two different materials possess no macroscopic centrosymmetry with respect to their material and/or orientation. 2 . Second-order optical nonlinear material according to claim 1 , wherein the second-order optical nonlinear material does not contain quantum wells which are responsible for the nonlinearity of the second-order optical nonlinear material. 3 . Second-order optical nonlinear material according to claim 1 , wherein the layers are deposited on the substrate as mono-layers. 4 . Second-order optical nonlinear material to claim 1 , wherein the material comprises at least three different materials arranged in layers in a predetermined repeated order. 5 . Second-order optical nonlinear material according to claim 1 , wherein the different materials are deposited on the substrate in layers by atomic-layer deposition, physical vapour deposition, chemical vapour deposition and/or metal organic chemical vapour deposition. 6 . Second-order optical nonlinear material according to claim 1 , wherein the layers of different materials comprise an orientation originating from an order of use of precursors used to deposit the respective material, and wherein said orientation of the layers is causing and/or increasing the macroscopic point asymmetry of the optical nonlinear material. 7 . Second-order optical nonlinear material according to claim 1 , wherein at least one of the at least two materials is centrosymmetric in one of its bulk crystalline forms. 8 . Second-order optical nonlinear material according to claim 1 , wherein materials are arranged in layers that provide for an overall material property of the optical nonlinear material at least 15% higher than said material property of one of the at least two materials in its bulk crystalline form. 9 . Second-order optical nonlinear material according to claim 8 , wherein the material property is the temperature resistance, flexibility, electrical conductivity, and/or stability of the optical nonlinear material. 10 . Second-order optical nonlinear material according to claim 1 , wherein the nonlinear material comprises layers of inorganic materials. 11 . Second-order optical nonlinear material according to claim 1 , wherein the nonlinear material is deposited on the substrate in substacks of multiple layers, wherein each substack comprises from 6 to 30 layers of the same material, and adjacent substacks comprise different materials. 12 . Electro-optic modulator comprising an optical nonlinear material arranged on a substrate, wherein the second-order optical nonlinear material comprises at least two different materials arranged in layers on the substrate, the layers of the second-order optical nonlinear material are arranged on each other in a predetermined order based on the type of material and/or orientation of the layer, and the predetermined order is chosen so that the layers of the at least two different materials possess no macroscopic centrosymmetry with respect to their material and/or orientation. 13 . Method of depositing a second-order optical nonlinear material on a substrate, comprising the steps depositing layers of at least two different materials on the substrate; and arranging the layers on each other in a predetermined order based on the type of material and/or orientation of each layer, so that the layers of the at least two different materials possess no macroscopic centrosymmetry with respect to their material and/or orientation. 14 . Method according to claim 13 , comprising the steps: depositing the second-order optical nonlinear material on the substrate in substacks of multiple layers, wherein: each substack comprises from 6 to 30 layers of the same material, and adjacent substacks comprise different materials. 15 . Method according to claim 13 , wherein the second-order optical nonlinear material is deposited by standard CMOS processes. 16 . Method according to claim 13 , wherein the second-order optical nonlinear material is deposited by atomic layer deposition, physical vapour deposition, chemical vapour deposition, and/or metal organic chemical vapour deposition.