We report here the discovery of a fancy interaction between cesium iodide (CsI) and methylamine (CH3NH2) due to the presence of the hydrogen bond. The formed CsI$xCH3NH2 is a liquid phase, which facilitates the large scale fabrication of highly uniform cesium-containing perovskite films with strong (110) preferred orientation by the CH3NH2 gas healing process. With this method, at most 10% nonpolar Cs cations could fully dope into the crystal lattice and extremely enhance the interaction of the inorganic framework with a moresymmetrical PbI6 octahedron, resulting in obvious improvement in moisture stability under continuous illumination.

{An important property of hybrid layered perovskite is the possibility to reduceits dimensionality to provide wider band gap and better stability. In this work,2D perovskite of the structure (PEA)2(MA)n–1PbnBr3n+1 has been sensitized,where PEA is phenyl ethyl-ammonium, MA is methyl-ammonium, and usingonly bromide as the halide. The number of the perovskite layers has beenvaried (n) from n = 1 through n = ∞. Optical and physical characterizationverify the layered structure and the increase in the band gap. The photovoltaicperformance shows higher open circuit voltage (Voc) for the quasi 2D perovskite(i.e.

Abstract The influence of the Schottky contact is studied for hole transport material (HTM) freeCH3NH3PbI3 perovskite solar cells (PSCs), by using drift-diffusion and small signal models. The basiccurrent-voltage and capacitance-voltage characteristics are simulated in reasonable agreement with experimentaldata. The build in potential of the finite CH3NH3PbI3 layer is extracted from a Mott-Schottkycapacitance analysis. Furthermore, hole collector conductors with work-functions of more than 5.5 eV areproposed as solutions for high efficiency HTM-free CH3NH3PbI3 PSCs.

{Perovskite nanostructures, both hybrid organo-metaland fully inorganic perovskites, have gained a lot of interest in the pastfew years for their intriguing optical properties in the visible region. Wereport on inorganic cesium lead bromide (CsPbBr3) nanowires (NWs)having quantum confined dimensions corresponding to 5 unit cells. Theaddition of various hydrohalic acids (HX

We describe a general synthesis of conductive gold thin films doped with entrapped organic molecules,and demonstrate, for the first time, the immobilization of a redox couple within an electrode in a singlestep. The resulting film is of dual properties: conductivity arising from the gold, and redox behaviororiginating from the entrapped molecule. Faster electron-transfer rates are found for the entrappedcase, compared to adsorption. The conductivity of the film affects the organic molecule–metal interactions,as seen in resistivity measurements, in Raman spectroscopy of the metal-entrapped molecules and froma remarkable red shift of 30 nm in emission spectroscopy. Doping is found to affect the work functionof gold. Thin conductive doped metal films are of relevance to a variety of applications such aselectrochemical detectors, electrode materials for electrochemical impedance spectroscopy, micro andnano electronics interconnects for packaging and for printed circuit boards. The ability to fine-tune thework function opens the possibility to design the desired energy level gaps for optoelectronic applicationssuch as light emitting diodes (LEDs), solar cells and transistors.