Perovskite compositions and uses thereof in photovoltaic devices

1 - 52 . (canceled) 53 . A perovskite film comprising spaced-apart islands of at least one functionalizable polymeric material, wherein the islands are free of a perovskite material, and having a length/height being at least a thickness of the film, wherein the film is transparent or semitransparent. 54 . The film according to claim 53 , wherein the spaced-apart islands are features of the at least one functionalizable polymeric material being substantially 3-dimensional in shape. 55 . The film according to claim 53 , wherein the film having an average visible transmittance (AVT) of at least about 12% or 20%. 56 . A device comprising or implementing a perovskite film according to claim 53 . 57 . The device according to claim 56 , being a multilayered or stacked device, wherein the perovskite film is a topmost layer or an inner layer. 58 . The device according to claim 56 , wherein islands formed in the perovskite film extend the surface of the film and penetrate into adjacent material layers. 59 . The device according to claim 56 , comprising an FTO electrode, an electron transport layer (ETL), a mesoporous oxide layer, a perovskite layer, a hole transport layer (HTL) and an electrode layer. 60 . The device according to claim 56 , the device having the structure HTL/perovskite/ETL/metal contact, wherein “HTL” is a hole transport material layer, “Perovskite” is a perovskite material, “ETL” is an electron transport material layer, and “Metal contact” is a physical contact made of a metallic material. 61 . The device according to claim 56 , wherein the device comprises a substrate, a compact metal oxide layer and a mesoporous metal oxide layer, wherein the perovskite film is provided on the mesoporous metal oxide layer. 62 . A process for fabricating a film according to claim 53 , the process comprises forming spaced-apart islands or pillar features of at least one functionalizable polymeric material on a surface region of a substrate and coating regions of the surface region not coated with the at least one functionalizable polymeric material with at least one perovskite material. 63 . The process according to claim 62 , wherein forming the spaced-apart islands or regions comprises depositing on the surface region a polymer precursor or a polymerizable material and causing said polymer precursor or polymerizable material to convert into the at least one functionalizable polymeric material. 64 . The process according to claim 63 , wherein the deposition of the polymer precursor or the polymerizable material and optionally of a photoinitiator onto a surface region to pattern the surface with spaced-apart polymeric pillars is achieved by a patterning device. 65 . A transparent or a semitransparent photovoltaic cell device comprising a perovskite film and a plurality of spaced-apart islands or pillars of at least one functionalizable polymeric material embedded within a plurality of material layers making up the device and extending the thickness of the device from a substrate of the device. 66 . The device according to claim 65 , wherein each of the pillars extends the thickness of the multilayered device from a substrate of said device. 67 . The device according to claim 65 , the device comprising an FTO electrode, an electron transport layer (ETL), a mesoporous oxide layer, a perovskite layer, a hole transport layer (HTL) and an electrode layer. 68 . The device according to claim 67 , having the structure HTL/perovskite/ETL/metal contact, wherein “HTL” is a hole transport material layer, “Perovskite” is a perovskite material, “ETL” is an electron transport material layer, and “Metal contact” is a physical contact made of a metallic material. 69 . The device according to claim 65 , wherein the perovskite film is provided as a perovskite layer of a material selected from Cs 1-x FA x Pb(I 1-y Br y ) 3 , wherein each of x and y, independently, is between 0 and 1; or, each of x an y, independently, is between 0 and 1, but is not zero; Cs 0.2 FA 0.8 Pb(I 0.6 Br 0.4 ) 3 ; Cs 0.15 FA 0.75 MA 0.10 PbI 2 Br; Cs 0.15 FA 0.85 PbI 2 Br; FA x MA x-1 Y, wherein Y is the perovskite species and wherein 0<=x<=1; FA 0.85 MA 0.15 PbI 3 ; FA 0.85 MA 0.15 PbI 2 Br; FA 0.85 MA 0.15 PbIBr 2 ; wherein FA is formamidine and MA is methylamine. 70 . The device according to claim 69 , wherein the perovskite material is Cs 0.2 FA 0.8 Pb(I 0.6 Br 0.4 ) 3 ; Cs 0.15 FA 0.75 MA 0.10 PbI 2 Br; Cs 0.15 FA 0.85 PbI 2 Br; FA 0.85 MA 0.15 PbI 3 ; FA 0.85 MA 0.15 PbI 2 Br; or FA 0.85 MA 0.15 PbIBr 2 ; wherein FA is formamidine and MA is methylamine. 71 . The device according to claim 65 having an average visible transmittance (AVT) value between 12 and 35% or between 35 and 80%. 72 . A photovoltaic cell device comprising a perovskite film of a material selected from Cs 0.2 FA 0.8 Pb(I 0.6 Br 0.4 ) 3 ; Cs 0.15 FA 0.75 MA 0.10 PbI 2 Br; Cs 0.15 FA 0.85 PbI 2 Br; FA 0.85 MA 0.15 PbI 3 ; FA 0.85 MA 0.15 PbI 2 Br; or FA 0.85 MA 0.15 PbIBr 2 ; wherein FA is formamidine and MA is methylamine; and a plurality of spaced-apart pillars of at least one functionalizable polymeric material embedded within a plurality of material layers and extending the thickness of the device from a substrate of the device, wherein the material layers comprise an electron transport layer (ETL), a mesoporous oxide layer, a perovskite layer, and a hole transport layer (HTL).